Nucleolus

Posted by uminati fatul chusnah on Saturday, June 18, 2011


The nucleolus is contained within the cell nucleus.Schematic of typical animal cell, showing subcellular components. Organelles:
(1) nucleolus
(2) nucleus
(3) Ribosomes (little dots)
(4) vesicle
(5) rough endoplasmic reticulum (ER)
(6) Golgi apparatus
(7) Cytoskeleton
(8) smooth endoplasmic reticulum (ER)
(9) mitochondria
(10) vacuole
(11) cytosol (not cytoplasm as that includes all the organelles)
(12) lysosome
(13) centrioles within centrosome
The nucleolus (also called nucleole) is a non-membrane bound structure[1] composed of proteins and nucleic acids found within the nucleus. Ribosomal RNA (rRNA) is transcribed and assembled within the nucleolus. The nucleolus ultrastructure can be visualized through an electron microscope, while the organization and dynamics can be studied through fluorescent protein tagging and fluorescent recovery after photobleaching (FRAP). Malfunction of nucleoli can be the cause for several human diseases.
Structure
Three major components of the nucleolus are recognized: the fibrillar centers (FC), the dense fibrillar component (DFC), and granular components (GC).[2] The DFC or pars fibrosa consists of newly transcribed rRNA bound to ribosomal proteins, while the GC, called pars granulosa, contains rRNA bound to ribosomal proteins that are begining to assemble into ribosomes. However, it has been proposed that this particular organization is only observed in higher eukaryotes and that it evolved from a bipartite organization with the transition from anamniotes to amniotes. Reflecting the substantial increase in the DNA intergenic region, an original fibrillar component would have separated into the FC and the DFC.[3] Another structure identified within many nucleoli (particularly in plants) is a clear area in the center of the structure referred to as a nucleolar vacuole.[4]
Function and ribosome assembly

Nucleoli are formed around specific genetic loci called nucleolar organizing regions (NORs), first described by Barbara McClintock. Because of this non-random organization, the nucleolus is defined as a "genetically determined element."[5] A NOR is composed of tandem repeats of rRNA genes, which can be found in several different chromosomes. The human genome, for example, contains more than 200 clustered copies of the rRNA genes on five different chromosomes (13, 14, 15, 21, 22). In a typical eukaryote, a rRNA gene consists of a promoter, internal and external transcribed spacers (ITS/ETS), rRNA coding sequences (18S, 5.8S, 28S) and an external non-transcribed spacer.[6] In ribosome biogenesis, two of the three eukaryotic RNA polymerases (pol I and III) are required, and these function in a coordinated manner. In an initial stage, the rRNA genes are transcribed as a single unit within the nucleolus by RNA pol I or III. In order for this transcription to occur, several pol I-associated factors and DNA-specific transacting factors are required. In yeast, the most important are: UAF (upstream activating factor), TBP (tata-box binding protein), and CF (core factor), which bind promoter elements and form the pre-initiation complex (PIC), which is in turn recognized by RNA pol. In humans, a similar PIC is assembled with SLI, the promoter selectivity factor (composed of TBP and TBP-associated factors, or TAFs), IFs (transcription initiation factors) and UBF (upstream binding factor). RNA polymerase I transcribes most rRNA transcripts (28S, 18S, and 5.8S) but the 5S rRNA subunit (component of the 60S ribosomal subunit) is transcribed by RNA polymerase III.[7]

Transcription of the ribosomal gene yields a long precursor molecule (45S pre-rRNA) which still contains the ITS and ETS. Further processing is needed to generate the 18S RNA, 5.8S and 28S RNA molecules. In eukaryotes, the RNA-modifying enzymes are brought to their respective recognition sites by interaction with guide RNAs, which bind these specific sequences. These guide RNAs belong to the class of small nucleolar RNAs (snoRNAs) which are complexed with proteins and exist as small-nucleolar-ribonucleoproteins (snoRNPs). Once the rRNA subunits are processed, they are ready to be assembled into larger ribosomal subunits. However, an additional rRNA molecule, the 5S rRNA, is also necessary. In yeast, the 5S rDNA sequence is localized in the external non-transcribed spacer and is transcribed in the nucleolus by RNA pol. In higher eukaryotes and plants, the situation is more complex, for the 5S DNA sequence lies outside the NOR and is transcribed by RNA pol III in the nucleoplasm, after which it finds its way into the nucleolus to participate in the ribosome assembly. This assembly not only involves the rRNA, but ribosomal proteins as well. The genes encoding these r-proteins are transcribed by pol II in the nucleoplasm by a "conventional" pathway of protein synthesis (transcription, pre-mRNA processing, nuclear export of mature mRNA and translation on cytoplasmic ribosomes). The mature r-proteins are then "imported" back into the nucleus and finally the nucleolus. Association and maturation of rRNA and r-proteins result in the formation of the 40S (small) and 60S (large) subunits of the complete ribosome. These are exported through the nuclear pore complexes to the cytoplasm, where they remain free or become associated with the endoplasmic reticulum, forming rough endoplasmic reticulum.
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"BADAN GOLGI"

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Badan Golgi atau Aparatus Golgi dijumpai pada hampir semua sel tumbuhan dan hewan. Pada sel tumbuhan, Badan Golgi disebut diktiosom. Badan Golgi (ditemukan tahun 1898 oleh Camillio Golgi) tersebar dalam sitoplasma dan merupakan salah satu komponen terbesar dalam sel. Antara badan Golgi satu dengan yang lain berhubungan dan membentuk struktur kompleks seperti jala. Badan Golgi sangat penting pada sel sekresi.

Badan Golgi dan RE mempunyai hubungan erat dalam sekresi protein sel. Di depan telah dikatakan bahwa RE menampung dan menyalurkan protein ke Golgi. Golgi mereaksikan protein itu dengan glioksilat sehingga terbentuk glikoprotein untuk dibawa ke luar sel. Oleh karena hasilnya disekresikan itulah maka Golgi disebut pula sebagai organel sekretori
Fungsi Aparatus Golgi
Selain itu, badan Golgi juga mempunyai beberapa fungsi sebagai berikut.
1) Tempat sintesis polisakarida seperti mukus, selulosa, hemiselulosa, dan pektin (penyusun dinding sel tumbuhan).
2) Membentuk membran plasma.
3) Membentuk kantong sekresi untuk membungkus zat yang akan dikeluarkan sel, seperti protein, glikoprotein, karbohidrat, dan lemak.
4) Membentuk akrosom pada sperma, kuning telur pada sel telur, dan lisosom.
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"MITOKONDRIA"

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Mitokondria adalah badan energi sel yang berisi protein dan benar-benar merupakan "gardu tenaga". "Gardu tenaga" ini mengoksidasi makanan dan mengubah energi menjadi adenosin trifosfat atau ATP. ATP menjadi agen dalam berbagai reaksi termasuk sistesis enzim. Mitokondria penuh selaput dalam yang tersusun seperti akordion dan meluaskan permukaan tempat terjadinya reaksi. (Sumber: Time Life, 1984)
Wikipedia Indonesia, (ensiklopedia bebas berbahasa Indonesia; diakses pada 22 Agustus 2007) memberi pengertian mitokondria sebagai tempat di mana fungsi respirasi pada makhluk hidup berlangsung. Respirasi merupakan proses perombakan atau katabolisme untuk menghasilkan energi atau tenaga bagi berlangsungnya proses hidup. Dengan demikian, mitokondria adalah "pembangkit tenaga" bagi sel. Oleh karena itu mito kondria sering disebut sebagai “The Power House”.
Mitokondria merupakan penghasil (ATP) karena berfungsi untuk respirasi. Bentuk mitokondria beraneka ragam, ada yang bulat, oval, silindris, seperti gada, seperti raket dan ada pula yang tidak beraturan. Namun secara umum dpat dikatakan bahwa mitokondria berbentuk butiran atau benang. Mitokondria mempunyai sifat plastis, artinya bentuknya mudah berubah. Ukuran seperti bakteri dengan diameter 0,5 – 1 µm. Mitokondria baru terbentuk dari pertumbuhan serta pembelahan mitokondria yang telah ada sebelumnya (seperti pembelahan bakteri). Penyebaran dan jumlah mitokondria di dalam tiap sel tidak sama dari hanya satu hingga beberapa ribu. Pada sel sperma, mitokondria tampak berderet-deret pada bagian ekor yang digunakan untuk bergerak.
Kehidupan dan kematian merupakan dua hal yang selalu terjadi pada setiap sel. Pada kedua hal itu, mitokondria terlibat aktif dan memiliki fungsi yang penting. Untuk kehidupan sel, mitokondria berperan menghasilkan energi yang digunakan untuk melakukan berbagai fungsi sel.
Semua jaringan dan sel yang hidup dengan berbagai derajat yang berbeda menurut fungsi masing-masing memerlukan energi dalam bentuk ATP yang dihasilkan mitokondria melalui proses fosforilasi oksidatif. Disfungsi mitokondria dapat terjadi pada semua sistem organ, maka manifestasi klinik kelainan mitokondria dapat bervariasi menurut organ yang terlibat. Gangguan ini bisa berupa gangguan fungsi sampai kerusakan sistem organ. Hal itu disampaikan oleh dr David Handojo Muljono dari Lembaga Biologi Molekuler Eijkman Jakarta dalam suatu seminar tentang Mitokondria.
Dengan berkembangnya imunologi, diketahui bahwa kerusakan hati pada primary biliary cirrhosis (PBC) terjadi karena kerusakan mitokondria akibat antibodi terhadap protein mitokondria. Selanjutnya terungkap bahwa penyakit hati yang disebabkan oleh penimbunan lemak, terjadi melalui kerusakan mitokondria sel hati.
Kelainan mitokondria ini terjadi sebagai akibat peningkatan sintesis asam lemak yang diikuti mekanisme kompensasi sel berupa fat disposal melalui esterifikasi lemak menjadi trigliserida dan oksidasi di tiga organel sel yakni mitokondria, peroksisom dan mikrosom. Kelainan pada mitokondria itu juga terjadi karena pembentukan bahan-bahan yang bersifat toksik terhadap berbagai protein respirasi, fosfolipid dan DNA mitokondria.
Selain akibat penimbunan lemak, kelainan mitokondria pada penyakit hati juga diakibatkan pengaruh obat. Obat merupakan bahan kimia yang bekerja dengan berbagai cara yakni langsung pada reseptor, memodulasi enzim atau berikatan dengan protein sel untuk menimbulkan efek baru. Di lain pihak, hati merupakan organ yang bertugas menetrasisasi bahan-bahan toksik yang memasuki tubuh.
Kegagalan suatu sistem akan menyebabkan akumulasi bahan tertentu yang akan merupakan bahan toksis untuk enzim pada organel tertentu atau pada organel berikutnya.
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virus

Posted by uminati fatul chusnah

A virus is a small infectious agent that can replicate only inside the living cells of organisms. Most viruses are too small to be seen directly with a light microscope. Viruses infect all types of organisms, from animals and plants to bacteria and archaea.[1] Since the initial discovery of the tobacco mosaic virus by Martinus Beijerinck in 1898,[2] about 5,000 viruses have been described in detail,[3] although there are millions of different types.[4] Viruses are found in almost every ecosystem on Earth and are the most abundant type of biological entity.[5][6] The study of viruses is known as virology, a sub-speciality of microbiology.
Virus particles (known as virions) consist of two or three parts: the genetic material made from either DNA or RNA, long molecules that carry genetic information; a protein coat that protects these genes; and in some cases an envelope of lipids that surrounds the protein coat when they are outside a cell. The shapes of viruses range from simple helical and icosahedral forms to more complex structures. The average virus is about one one-hundredth the size of the average bacterium.
The origins of viruses in the evolutionary history of life are unclear: some may have evolved from plasmids – pieces of DNA that can move between cells – while others may have evolved from bacteria. In evolution, viruses are an important means of horizontal gene transfer, which increases genetic diversity.[7]
Viruses spread in many ways; viruses in plants are often transmitted from plant to plant by insects that feed on the sap of plants, such as aphids; viruses in animals can be carried by blood-sucking insects. These disease-bearing organisms are known as vectors. Influenza viruses are spread by coughing and sneezing. Norovirus and rotavirus, common causes of viral gastroenteritis, are transmitted by the faecal-oral route and are passed from person to person by contact, entering the body in food or water. HIV is one of several viruses transmitted through sexual contact and by exposure to infected blood. The range of host cells that a virus can infect is called its "host range". This can be narrow or, as when a virus is capable of infecting many species, broad.[8]
Viral infections in animals provoke an immune response that usually eliminates the infecting virus. Immune responses can also be produced by vaccines, which confer an artificially acquired immunity to the specific viral infection. However, some viruses including those causing AIDS and viral hepatitis evade these immune responses and result in chronic infections. Antibiotics have no effect on viruses, but several antiviral drugs have been developed.

Etymology
The word is from the Latin virus referring to poison and other noxious substances, first used in English in 1392.[9] Virulent, from Latin virulentus (poisonous), dates to 1400.[10] A meaning of "agent that causes infectious disease" is first recorded in 1728,[9] before the discovery of viruses by Dmitry Ivanovsky in 1892. The plural is viruses. The adjective viral dates to 1948.[11] The term virion is also used to refer to a single infective viral particle.
History
Main article: History of viruses
Martinus Beijerinck in his laboratory in 1921
Louis Pasteur was unable to find a causative agent for rabies and speculated about a pathogen too small to be detected using a microscope.[12] In 1884, the French microbiologist Charles Chamberland invented a filter (known today as the Chamberland filter or Chamberland-Pasteur filter) with pores smaller than bacteria. Thus, he could pass a solution containing bacteria through the filter and completely remove them from the solution.[13] In 1892, the Russian biologist Dmitry Ivanovsky used this filter to study what is now known as the tobacco mosaic virus. His experiments showed that crushed leaf extracts from infected tobacco plants remain infectious after filtration. Ivanovsky suggested the infection might be caused by a toxin produced by bacteria, but did not pursue the idea.[14] At the time it was thought that all infectious agents could be retained by filters and grown on a nutrient medium – this was part of the germ theory of disease.[2] In 1898, the Dutch microbiologist Martinus Beijerinck repeated the experiments and became convinced that the filtered solution contained a new form of infectious agent.[15] He observed that the agent multiplied only in cells that were dividing, but as his experiments did not show that it was made of particles, he called it a contagium vivum fluidum (soluble living germ) and re-introduced the word virus.[14] Beijerinck maintained that viruses were liquid in nature, a theory later discredited by Wendell Stanley, who proved they were particulate.[14] In the same year Friedrich Loeffler and Frosch passed the first animal virus – agent of foot-and-mouth disease (aphthovirus) – through a similar filter.[16]
In the early 20th century, the English bacteriologist Frederick Twort discovered a group of viruses that infect bacteria, now called bacteriophages[17] (or commonly phages), and the French-Canadian microbiologist Félix d'Herelle described viruses that, when added to bacteria on agar, would produce areas of dead bacteria. He accurately diluted a suspension of these viruses and discovered that the highest dilutions (lowest virus concentrations), rather than killing all the bacteria, formed discrete areas of dead organisms. Counting these areas and multiplying by the dilution factor allowed him to calculate the number of viruses in the original suspension.[18] Phages were heralded as a potential treatment for diseases such as typhoid and cholera, but their promise was forgotten with the development of penicillin. The study of phages provided insights into the switching on and off of genes, and a useful mechanism for introducing foreign genes into bacteria.
By the end of the 19th century, viruses were defined in terms of their infectivity, their ability to be filtered, and their requirement for living hosts. Viruses had been grown only in plants and animals. In 1906, Ross Granville Harrison invented a method for growing tissue in lymph, and, in 1913, E. Steinhardt, C. Israeli, and R. A. Lambert used this method to grow vaccinia virus in fragments of guinea pig corneal tissue.[19] In 1928, H. B. Maitland and M. C. Maitland grew vaccinia virus in suspensions of minced hens' kidneys. Their method was not widely adopted until the 1950s, when poliovirus was grown on a large scale for vaccine production.[20]
Another breakthrough came in 1931, when the American pathologist Ernest William Goodpasture grew influenza and several other viruses in fertilized chickens' eggs.[21] In 1949, John F. Enders, Thomas Weller, and Frederick Robbins grew polio virus in cultured human embryo cells, the first virus to be grown without using solid animal tissue or eggs. This work enabled Jonas Salk to make an effective polio vaccine.[22]
The first images of viruses were obtained upon the invention of electron microscopy in 1931 by the German engineers Ernst Ruska and Max Knoll.[23] In 1935, American biochemist and virologist Wendell Meredith Stanley examined the tobacco mosaic virus and found it was mostly made of protein.[24] A short time later, this virus was separated into protein and RNA parts.[25] The tobacco mosaic virus was the first to be crystallised and its structure could therefore be elucidated in detail. The first X-ray diffraction pictures of the crystallised virus were obtained by Bernal and Fankuchen in 1941. On the basis of her pictures, Rosalind Franklin discovered the full DNA structure of the virus in 1955.[26] In the same year, Heinz Fraenkel-Conrat and Robley Williams showed that purified tobacco mosaic virus RNA and its coat protein can assemble by themselves to form functional viruses, suggesting that this simple mechanism was probably the means through which viruses were created within their host cells.[27]
The second half of the 20th century was the golden age of virus discovery and most of the 2,000 recognised species of animal, plant, and bacterial viruses were discovered during these years.[28][29] In 1957, equine arterivirus and the cause of Bovine virus diarrhea (a pestivirus) were discovered. In 1963, the hepatitis B virus was discovered by Baruch Blumberg,[30] and in 1965, Howard Temin described the first retrovirus. Reverse transcriptase, the key enzyme that retroviruses use to translate their RNA into DNA, was first described in 1970, independently by Howard Martin Temin and David Baltimore.[31] In 1983 Luc Montagnier's team at the Pasteur Institute in France, first isolated the retrovirus now called HIV.[32]
Origins
Viruses are found wherever there is life and have probably existed since living cells first evolved.[33] The origin of viruses is unclear because they do not form fossils, so molecular techniques have been used to compare the DNA or RNA of viruses and are a useful means of investigating how they arose.[34] There are three main hypotheses that try to explain the origins of viruses:[35][36]
Regressive hypothesis
Viruses may have once been small cells that parasitised larger cells. Over time, genes not required by their parasitism were lost. The bacteria rickettsia and chlamydia are living cells that, like viruses, can reproduce only inside host cells. They lend support to this hypothesis, as their dependence on parasitism is likely to have caused the loss of genes that enabled them to survive outside a cell. This is also called the degeneracy hypothesis,[37][38] or reduction hypothesis.[39]
Cellular origin hypothesis
Some viruses may have evolved from bits of DNA or RNA that "escaped" from the genes of a larger organism. The escaped DNA could have come from plasmids (pieces of naked DNA that can move between cells) or transposons (molecules of DNA that replicate and move around to different positions within the genes of the cell).[40] Once called "jumping genes", transposons are examples of mobile genetic elements and could be the origin of some viruses. They were discovered in maize by Barbara McClintock in 1950.[41] This is sometimes called the vagrancy hypothesis,[37][42] or the escape hypothesis.[39]
Coevolution hypothesis
This is also called the virus-first hypothesis[39] and proposes that viruses may have evolved from complex molecules of protein and nucleic acid at the same time as cells first appeared on earth and would have been dependent on cellular life for billions of years. Viroids are molecules of RNA that are not classified as viruses because they lack a protein coat. However, they have characteristics that are common to several viruses and are often called subviral agents.[43] Viroids are important pathogens of plants.[44] They do not code for proteins but interact with the host cell and use the host machinery for their replication.[45] The hepatitis delta virus of humans has an RNA genome similar to viroids but has a protein coat derived from hepatitis B virus and cannot produce one of its own. It is, therefore, a defective virus and cannot replicate without the help of hepatitis B virus.[46] In similar manner, the virophage 'sputnik' is dependent on mimivirus, which infects the protozoan Acanthamoeba castellanii.[47] These viruses that are dependent on the presence of other virus species in the host cell are called satellites and may represent evolutionary intermediates of viroids and viruses.[48][49]
In the past, there were problems with all of these hypotheses: the regressive hypothesis did not explain why even the smallest of cellular parasites do not resemble viruses in any way. The escape hypothesis did not explain the complex capsids and other structures on virus particles. The virus-first hypothesis contravened the definition of viruses in that they require host cells.[39] Viruses are now recognised as ancient and to have origins that pre-date the divergence of life into the three domains.[50] This discovery has led modern virologists to reconsider and re-evaluate these three classical hypotheses.[50]
The evidence for an ancestral world of RNA cells[51] and computer analysis of viral and host DNA sequences are giving a better understanding of the evolutionary relationships between different viruses and may help identify the ancestors of modern viruses. To date, such analyses have not proved which of these hypotheses is correct.[51] However, it seems unlikely that all currently known viruses have a common ancestor, and viruses have probably arisen numerous times in the past by one or more mechanisms.[52]
Prions are infectious protein molecules that do not contain DNA or RNA.[53] They cause an infection in sheep called scrapie and cattle bovine spongiform encephalopathy ("mad cow" disease). In humans they cause kuru and Creutzfeldt-Jakob disease.[54] They are able to replicate because some proteins can exist in two different shapes and the prion changes the normal shape of a host protein into the prion shape. This starts a chain reaction where each prion protein converts many host proteins into more prions, and these new prions then go on to convert even more protein into prions. Although they are fundamentally different from viruses and viroids, their discovery gives credence to the idea that viruses could have evolved from self-replicating molecules.[55]
Microbiology
Life properties
Opinions differ on whether viruses are a form of life, or organic structures that interact with living organisms. They have been described as "organisms at the edge of life",[56] since they resemble organisms in that they possess genes and evolve by natural selection,[57] and reproduce by creating multiple copies of themselves through self-assembly. Although they have genes, they do not have a cellular structure, which is often seen as the basic unit of life. Viruses do not have their own metabolism, and require a host cell to make new products. They therefore cannot naturally reproduce outside a host cell[58] – although bacterial species such as rickettsia and chlamydia are considered living organisms despite the same limitation.[59][60] Accepted forms of life use cell division to reproduce, whereas viruses spontaneously assemble within cells. They differ from autonomous growth of crystals as they inherit genetic mutations while being subject to natural selection. Virus self-assembly within host cells has implications for the study of the origin of life, as it lends further credence to the hypothesis that life could have started as self-assembling organic molecules.[1]
Structure
Diagram of how a virus capsid can be constructed using multiple copies of just two protein molecules
Viruses display a wide diversity of shapes and sizes, called morphologies. Generally viruses are much smaller than bacteria. Most viruses that have been studied have a diameter between 20 and 300 nanometres. Some filoviruses have a total length of up to 1400 nm; their diameters are only about 80 nm.[61] Most viruses cannot be seen with a light microscope so scanning and transmission electron microscopes are used to visualise virions.[62] To increase the contrast between viruses and the background, electron-dense "stains" are used. These are solutions of salts of heavy metals, such as tungsten, that scatter the electrons from regions covered with the stain. When virions are coated with stain (positive staining), fine detail is obscured. Negative staining overcomes this problem by staining the background only.[63]
A complete virus particle, known as a virion, consists of nucleic acid surrounded by a protective coat of protein called a capsid. These are formed from identical protein subunits called capsomers.[64] Viruses can have a lipid "envelope" derived from the host cell membrane. The capsid is made from proteins encoded by the viral genome and its shape serves as the basis for morphological distinction.[65][66] Virally coded protein subunits will self-assemble to form a capsid, generally requiring the presence of the virus genome. Complex viruses code for proteins that assist in the construction of their capsid. Proteins associated with nucleic acid are known as nucleoproteins, and the association of viral capsid proteins with viral nucleic acid is called a nucleocapsid. The capsid and entire virus structure can be mechanically (physically) probed through atomic force microscopy.[67][68] In general, there are four main morphological virus types:
Helical
These viruses are composed of a single type of capsomer stacked around a central axis to form a helical structure, which may have a central cavity, or hollow tube. This arrangement results in rod-shaped or filamentous virions: These can be short and highly rigid, or long and very flexible. The genetic material, in general, single-stranded RNA, but ssDNA in some cases, is bound into the protein helix by interactions between the negatively charged nucleic acid and positive charges on the protein. Overall, the length of a helical capsid is related to the length of the nucleic acid contained within it and the diameter is dependent on the size and arrangement of capsomers. The well-studied tobacco mosaic virus is an example of a helical virus.[69]
Icosahedral
Most animal viruses are icosahedral or near-spherical with icosahedral symmetry. A regular icosahedron is the optimum way of forming a closed shell from identical sub-units. The minimum number of identical capsomers required is twelve, each composed of five identical sub-units. Many viruses, such as rotavirus, have more than twelve capsomers and appear spherical but they retain this symmetry. Capsomers at the apices are surrounded by five other capsomers and are called pentons. Capsomers on the triangular faces are surrounded by six others and are called hexons.[70]
Envelope
Some species of virus envelop themselves in a modified form of one of the cell membranes, either the outer membrane surrounding an infected host cell or internal membranes such as nuclear membrane or endoplasmic reticulum, thus gaining an outer lipid bilayer known as a viral envelope. This membrane is studded with proteins coded for by the viral genome and host genome; the lipid membrane itself and any carbohydrates present originate entirely from the host. The influenza virus and HIV use this strategy. Most enveloped viruses are dependent on the envelope for their infectivity.[71]
Complex
These viruses possess a capsid that is neither purely helical nor purely icosahedral, and that may possess extra structures such as protein tails or a complex outer wall. Some bacteriophages, such as Enterobacteria phage T4, have a complex structure consisting of an icosahedral head bound to a helical tail, which may have a hexagonal base plate with protruding protein tail fibres. This tail structure acts like a molecular syringe, attaching to the bacterial host and then injecting the viral genome into the cell.[72]
The poxviruses are large, complex viruses that have an unusual morphology. The viral genome is associated with proteins within a central disk structure known as a nucleoid. The nucleoid is surrounded by a membrane and two lateral bodies of unknown function. The virus has an outer envelope with a thick layer of protein studded over its surface. The whole virion is slightly pleiomorphic, ranging from ovoid to brick shape.[73] Mimivirus is the largest known virus, with a capsid diameter of 400 nm. Protein filaments measuring 100 nm project from the surface. The capsid appears hexagonal under an electron microscope, therefore the capsid is probably icosahedral.[74]
Some viruses that infect Archaea have complex structures that are unrelated to any other form of virus, with a wide variety of unusual shapes, ranging from spindle-shaped structures, to viruses that resemble hooked rods, teardrops or even bottles. Other archaeal viruses resemble the tailed bacteriophages, and can have multiple tail structures.[75]
Genome
Genomic diversity among viruses
Property Parameters
Nucleic acid • DNA
• RNA
• Both DNA and RNA (at different stages in the life cycle)
Shape • Linear
• Circular
• Segmented
Strandedness • Single-stranded
• Double-stranded
• Double-stranded with regions of single-strandedness
Sense
• Positive sense (+)
• Negative sense (−)
• Ambisense (+/−)
An enormous variety of genomic structures can be seen among viral species; as a group they contain more structural genomic diversity than plants, animals, archaea, or bacteria. There are millions of different types of viruses,[4] although only about 5,000 of them have been described in detail.[3] A virus has either DNA or RNA genes and is called a DNA virus or a RNA virus respectively. The vast majority of viruses have RNA genomes. Plant viruses tend to have single-stranded RNA genomes and bacteriophages tend to have double-stranded DNA genomes.[76]
Viral genomes are circular, as in the polyomaviruses, or linear, as in the adenoviruses. The type of nucleic acid is irrelevant to the shape of the genome. Among RNA viruses and certain DNA viruses, the genome is often divided up into separate parts, in which case it is called segmented. For RNA viruses, each segment often codes for only one protein and they are usually found together in one capsid. However, all segments are not required to be in the same virion for the virus to be infectious, as demonstrated by brome mosaic virus and several other plant viruses.[61]
A viral genome, irrespective of nucleic acid type, is almost always either single-stranded or double-stranded. Single-stranded genomes consist of an unpaired nucleic acid, analogous to one-half of a ladder split down the middle. Double-stranded genomes consist of two complementary paired nucleic acids, analogous to a ladder. The virus particles of some virus families, such as those belonging to the Hepadnaviridae, contain a genome that is partially double-stranded and partially single-stranded.[76]
For most viruses with RNA genomes and some with single-stranded DNA genomes, the single strands are said to be either positive-sense (called the plus-strand) or negative-sense (called the minus-strand), depending on whether or not they are complementary to the viral messenger RNA (mRNA). Positive-sense viral RNA is in the same sense as viral mRNA and thus at least a part of it can be immediately translated by the host cell. Negative-sense viral RNA is complementary to mRNA and thus must be converted to positive-sense RNA by an RNA-dependent RNA polymerase before translation. DNA nomenclature for viruses with single-sense genomic ssDNA is similar to RNA nomenclature, in that the coding strand for the viral mRNA is complementary to it (−), and the non-coding strand is a copy of it (+).[76] However, several types of ssDNA and ssRNA viruses have genomes that are ambisense in that transcription can occur off both strands in a double-stranded replicative intermediate. Examples include geminiviruses, which are ssDNA plant viruses and arenaviruses, which are ssRNA viruses of animals.[77]
Genome size varies greatly between species. The smallest viral genomes – the ssDNA circoviruses, family Circoviridae – code for only two proteins and have a genome size of only 2 kilobases; the largest – mimiviruses – have genome sizes of over 1.2 megabases and code for over one thousand proteins.[78] RNA viruses generally have smaller genome sizes than DNA viruses because of a higher error-rate when replicating, and have a maximum upper size limit.[34] Beyond this limit, errors in the genome when replicating render the virus useless or uncompetitive. To compensate for this, RNA viruses often have segmented genomes – the genome is split into smaller molecules – thus reducing the chance that an error in a single-component genome will incapacitate the entire genome. In contrast, DNA viruses generally have larger genomes because of the high fidelity of their replication enzymes.[79] Single-strand DNA viruses are an exception to this rule, however, as mutation rates for these genomes can approach the extreme of the ssRNA virus case.[80]
How antigenic shift, or reassortment, can result in novel and highly pathogenic strains of human influenza
Viruses undergo genetic change by several mechanisms. These include a process called genetic drift where individual bases in the DNA or RNA mutate to other bases. Most of these point mutations are "silent" – they do not change the protein that the gene encodes – but others can confer evolutionary advantages such as resistance to antiviral drugs.[81] Antigenic shift occurs when there is a major change in the genome of the virus. This can be a result of recombination or reassortment. When this happens with influenza viruses, pandemics might result.[82] RNA viruses often exist as quasispecies or swarms of viruses of the same species but with slightly different genome nucleoside sequences. Such quasispecies are a prime target for natural selection.[83]
Segmented genomes confer evolutionary advantages; different strains of a virus with a segmented genome can shuffle and combine genes and produce progeny viruses or (offspring) that have unique characteristics. This is called reassortment or viral sex.[84]
Genetic recombination is the process by which a strand of DNA is broken and then joined to the end of a different DNA molecule. This can occur when viruses infect cells simultaneously and studies of viral evolution have shown that recombination has been rampant in the species studied.[85] Recombination is common to both RNA and DNA viruses.[86][87]
Replication cycle
Viral populations do not grow through cell division, because they are acellular. Instead, they use the machinery and metabolism of a host cell to produce multiple copies of themselves, and they assemble in the cell.
A typical virus replication cycle
Some bacteriophages inject their genomes into bacterial cells
The life cycle of viruses differs greatly between species but there are six basic stages in the life cycle of viruses:[88]
• Attachment is a specific binding between viral capsid proteins and specific receptors on the host cellular surface. This specificity determines the host range of a virus. For example, HIV infects a limited range of human leucocytes. This is because its surface protein, gp120, specifically interacts with the CD4 molecule – a chemokine receptor – which is most commonly found on the surface of CD4+ T-Cells. This mechanism has evolved to favour those viruses that infect only cells in which they are capable of replication. Attachment to the receptor can induce the viral envelope protein to undergo changes that results in the fusion of viral and cellular membranes, or changes of non-enveloped virus surface proteins that allow the virus to enter.
• Penetration follows attachment: Virions enter the host cell through receptor-mediated endocytosis or membrane fusion. This is often called viral entry. The infection of plant and, it is presumed, fungal cells is different from that of animal cells. Plants have a rigid cell wall made of cellulose, and fungi one of chitin, so most viruses can get inside these cells only after trauma to the cell wall.[89] However, nearly all plant viruses (such as tobacco mosaic virus) can also move directly from cell to cell, in the form of single-stranded nucleoprotein complexes, through pores called plasmodesmata. This process requires movement proteins, which are virus-encoded proteins probably originally derived from plant proteins, which interact with the plasmodesmatal transport machinery [90] Bacteria, like plants, have strong cell walls that a virus must breach to infect the cell. However, given that bacterial cell walls are much less thick than plant cell walls due to their much smaller size, some viruses have evolved mechanisms that inject their genome into the bacterial cell across the cell wall, while the viral capsid remains outside.[91]
• Uncoating is a process in which the viral capsid is removed: This may be by degradation by viral enzymes or host enzymes or by simple dissociation; the end-result is the releasing of the viral genomic nucleic acid.
• Replication of viruses primarily involves multiplication of the genome. Replication involves synthesis of viral messenger RNA (mRNA) from "early" genes (with exceptions for positive sense RNA viruses), viral protein synthesis, possible assembly of viral proteins, then viral genome replication mediated by early or regulatory protein expression. This may be followed, for complex viruses with larger genomes, by one or more further rounds of mRNA synthesis: "late" gene expression is, in general, of structural or virion proteins.
• Following the structure-mediated self-assembly of the virus particles, some modification of the proteins often occurs. In viruses such as HIV, this modification (sometimes called maturation) occurs after the virus has been released from the host cell.[92]
• Viruses can be released from the host cell by lysis, a process that kills the cell by bursting its membrane and cell wall if present: This is a feature of many bacterial and some animal viruses. Some viruses undergo a lysogenic cycle where the viral genome is incorporated by genetic recombination into a specific place in the host's chromosome. The viral genome is then known as a "provirus" or, in the case of bacteriophages a "prophage".[93] Whenever the host divides, the viral genome is also replicated. The viral genome is mostly silent within the host; however, at some point, the provirus or prophage may give rise to active virus, which may lyse the host cells.[94] Enveloped viruses (e.g., HIV) typically are released from the host cell by budding. During this process the virus acquires its envelope, which is a modified piece of the host's plasma or other, internal membrane.[95]
The genetic material within virus particles, and the method by which the material is replicated, varies considerably between different types of viruses.
DNA viruses
The genome replication of most DNA viruses takes place in the cell's nucleus. If the cell has the appropriate receptor on its surface, these viruses enter the cell sometimes by direct fusion with the cell membrane (e.g. herpesviruses) or – more usually – by receptor-mediated endocytosis. Most DNA viruses are entirely dependent on the host cell's DNA and RNA synthesising machinery, and RNA processing machinery; however, viruses with larger genomes may encode much of this machinery themselves. In eukaryotes the viral genome must cross the cell's nuclear membrane to access this machinery, while in bacteria it need only enter the cell.[96]
RNA viruses
Replication usually takes place in the cytoplasm. RNA viruses can be placed into four different groups depending on their modes of replication. The polarity (whether or not it can be used directly by ribosomes to make proteins) of single-stranded RNA viruses largely determines the replicative mechanism; the other major criterion is whether the genetic material is single-stranded or double-stranded. All RNA viruses use their own RNA replicase enzymes to create copies of their genomes.[97]
Reverse transcribing viruses
These have ssRNA (Retroviridae, Metaviridae, Pseudoviridae) or dsDNA (Caulimoviridae, and Hepadnaviridae) in their particles. Reverse transcribing viruses with RNA genomes (retroviruses), use a DNA intermediate to replicate, whereas those with DNA genomes (pararetroviruses) use an RNA intermediate during genome replication. Both types use a reverse transcriptase, or RNA-dependent DNA polymerase enzyme, to carry out the nucleic acid conversion. Retroviruses integrate the DNA produced by reverse transcription into the host genome as a provirus as a part of the replication process; pararetroviruses do not, although integrated genome copies of especially plant pararetroviruses can give rise to infectious virus.[98] They are susceptible to antiviral drugs that inhibit the reverse transcriptase enzyme, e.g. zidovudine and lamivudine. An example of the first type is HIV, which is a retrovirus. Examples of the second type are the Hepadnaviridae, which includes Hepatitis B virus.[99]
Effects on the host cell
The range of structural and biochemical effects that viruses have on the host cell is extensive.[100] These are called cytopathic effects.[101] Most virus infections eventually result in the death of the host cell. The causes of death include cell lysis, alterations to the cell's surface membrane and apoptosis.[102] Often cell death is caused by cessation of its normal activities because of suppression by virus-specific proteins, not all of which are components of the virus particle.[103]
Some viruses cause no apparent changes to the infected cell. Cells in which the virus is latent and inactive show few signs of infection and often function normally.[104] This causes persistent infections and the virus is often dormant for many months or years. This is often the case with herpes viruses.[105][106] Some viruses, such as Epstein-Barr virus, can cause cells to proliferate without causing malignancy,[107] while others, such as papillomaviruses, are established causes of cancer.[108]
Host range
Viruses are by far the most abundant parasites on earth, and they have been found to infect all types of cellular life including animals, plants, and bacteria.[3] However, different types of viruses can infect only a limited range of hosts and many are species-specific. Some, such as smallpox virus for example, can infect only one species – in this case humans,[109] and are said to have a narrow host range. Other viruses, such as rabies virus, can infect different species of mammals and are said to have a broad range.[110] The viruses that infect plants are harmless to animals, and most viruses that infect other animals are harmless to humans.[111] The host range of some bacteriophages is limited to a single strain of bacteria and they can be used to trace the source of outbreaks of infections by a method called phage typing.[112]
Classification
Main article: Virus classification
Classification seeks to describe the diversity of viruses by naming and grouping them on the basis of similarities. In 1962, André Lwoff, Robert Horne, and Paul Tournier were the first to develop a means of virus classification, based on the Linnaean hierarchical system.[113] This system bases classification on phylum, class, order, family, genus, and species. Viruses were grouped according to their shared properties (not those of their hosts) and the type of nucleic acid forming their genomes.[114] Later the International Committee on Taxonomy of Viruses was formed. However, viruses are not classified on the basis of phylum or class, as their small genome size and high rate of mutation makes it difficult to determine their ancestry beyond Order. As such, the Baltimore Classification is used to supplement the more traditional hierarchy.
ICTV classification
The International Committee on Taxonomy of Viruses (ICTV) developed the current classification system and wrote guidelines that put a greater weight on certain virus properties to maintain family uniformity. A unified taxonomy (a universal system for classifying viruses) has been established. The 7th lCTV Report formalised for the first time the concept of the virus species as the lowest taxon (group) in a branching hierarchy of viral taxa.[115] However, at present only a small part of the total diversity of viruses has been studied, with analyses of samples from humans finding that about 20% of the virus sequences recovered have not been seen before, and samples from the environment, such as from seawater and ocean sediments, finding that the large majority of sequences are completely novel.[116]
The general taxonomic structure is as follows:
Order (-virales)
Family (-viridae)
Subfamily (-virinae)
Genus (-virus)
Species (-virus)
In the current (2008) ICTV taxonomy, five orders have been established, the Caudovirales, Herpesvirales, Mononegavirales, Nidovirales, and Picornavirales. The committee does not formally distinguish between subspecies, strains, and isolates. In total there are 5 orders, 82 families, 11 subfamilies, 307 genera, 2,083 species and about 3,000 types yet unclassified.[117][118]
Baltimore classification
Main article: Baltimore classification
The Baltimore Classification of viruses is based on the method of viral mRNA synthesis.
The Nobel Prize-winning biologist David Baltimore devised the Baltimore classification system.[31][119] The ICTV classification system is used in conjunction with the Baltimore classification system in modern virus classification.[120][121][122]
The Baltimore classification of viruses is based on the mechanism of mRNA production. Viruses must generate mRNAs from their genomes to produce proteins and replicate themselves, but different mechanisms are used to achieve this in each virus family. Viral genomes may be single-stranded (ss) or double-stranded (ds), RNA or DNA, and may or may not use reverse transcriptase (RT). Additionally, ssRNA viruses may be either sense (+) or antisense (−). This classification places viruses into seven groups:
• I: dsDNA viruses (e.g. Adenoviruses, Herpesviruses, Poxviruses)
• II: ssDNA viruses (+)sense DNA (e.g. Parvoviruses)
• III: dsRNA viruses (e.g. Reoviruses)
• IV: (+)ssRNA viruses (+)sense RNA (e.g. Picornaviruses, Togaviruses)
• V: (−)ssRNA viruses (−)sense RNA (e.g. Orthomyxoviruses, Rhabdoviruses)
• VI: ssRNA-RT viruses (+)sense RNA with DNA intermediate in life-cycle (e.g. Retroviruses)
• VII: dsDNA-RT viruses (e.g. Hepadnaviruses)
As an example of viral classification, the chicken pox virus, varicella zoster (VZV), belongs to the order Herpesvirales, family Herpesviridae, subfamily Alphaherpesvirinae, and genus Varicellovirus. VZV is in Group I of the Baltimore Classification because it is a dsDNA virus that does not use reverse transcriptase.
Role in human disease
See also: Table of clinically important viruses
Overview of the main types of viral infection and the most notable species involved[123][124]
Examples of common human diseases caused by viruses include the common cold, influenza, chickenpox and cold sores. Many serious diseases such as ebola, AIDS, avian influenza and SARS are caused by viruses. The relative ability of viruses to cause disease is described in terms of virulence. Other diseases are under investigation as to whether they too have a virus as the causative agent, such as the possible connection between human herpes virus six (HHV6) and neurological diseases such as multiple sclerosis and chronic fatigue syndrome.[125] There is controversy over whether the borna virus, previously thought to cause neurological diseases in horses, could be responsible for psychiatric illnesses in humans.[126]
Viruses have different mechanisms by which they produce disease in an organism, which largely depends on the viral species. Mechanisms at the cellular level primarily include cell lysis, the breaking open and subsequent death of the cell. In multicellular organisms, if enough cells die, the whole organism will start to suffer the effects. Although viruses cause disruption of healthy homeostasis, resulting in disease, they may exist relatively harmlessly within an organism. An example would include the ability of the herpes simplex virus, which causes cold sores, to remain in a dormant state within the human body. This is called latency[127] and is a characteristic of the herpes viruses including Epstein-Barr virus, which causes glandular fever, and varicella zoster virus, which causes chickenpox and shingles. Most people have been infected with at least one of these types of herpes virus.[128] However, these latent viruses might sometimes be beneficial, as the presence of the virus can increase immunity against bacterial pathogens, such as Yersinia pestis.[129]
Some viruses can cause life-long or chronic infections, where the viruses continue to replicate in the body despite the host's defence mechanisms.[130] This is common in hepatitis B virus and hepatitis C virus infections. People chronically infected are known as carriers, as they serve as reservoirs of infectious virus.[131] In populations with a high proportion of carriers, the disease is said to be endemic.[132]
Epidemiology
Viral epidemiology is the branch of medical science that deals with the transmission and control of virus infections in humans. Transmission of viruses can be vertical, that is from mother to child, or horizontal, which means from person to person. Examples of vertical transmission include hepatitis B virus and HIV where the baby is born already infected with the virus.[133] Another, more rare, example is the varicella zoster virus, which, although causing relatively mild infections in humans, can be fatal to the foetus and new-born baby.[134]
Horizontal transmission is the most common mechanism of spread of viruses in populations. Transmission can occur when: body fluids are exchanged during sexual activity, e.g., HIV; blood is exchanged by contaminated transfusion or needle sharing, e.g., hepatitis C; a child is born to an infected mother, e.g., hepatitis B; exchange of saliva by mouth, e.g., Epstein-Barr virus; contaminated food or water is ingested, e.g., norovirus; aerosols containing virions are inhaled, e.g., influenza virus; and insect vectors such as mosquitoes penetrate the skin of a host, e.g., dengue. The rate or speed of transmission of viral infections depends on factors that include population density, the number of susceptible individuals, (i.e., those not immune),[135] the quality of healthcare and the weather.[136]
Epidemiology is used to break the chain of infection in populations during outbreaks of viral diseases.[137] Control measures are used that are based on knowledge of how the virus is transmitted. It is important to find the source, or sources, of the outbreak and to identify the virus. Once the virus has been identified, the chain of transmission can sometimes be broken by vaccines. When vaccines are not available sanitation and disinfection can be effective. Often infected people are isolated from the rest of the community and those that have been exposed to the virus placed in quarantine.[138] To control the outbreak of foot and mouth disease in cattle in Britain in 2001, thousands of cattle were slaughtered.[139] Most viral infections of humans and other animals have incubation periods during which the infection causes no signs or symptoms.[140] Incubation periods for viral diseases range from a few days to weeks but are known for most infections.[141] Somewhat overlapping, but mainly following the incubation period, there is a period of communicability; a time when an infected individual or animal is contagious and can infect another person or animal.[142] This too is known for many viral infections and knowledge the length of both periods is important in the control of outbreaks.[143] When outbreaks cause an unusually high proportion of cases in a population, community or region they are called epidemics. If outbreaks spread worldwide they are called pandemics.[144]
Epidemics and pandemics
See also: Spanish flu, AIDS, and Ebola
For more details on this topic, see List of epidemics.
Transmission electron microscope image of a recreated 1918 influenza virus
Native American populations were devastated by contagious diseases, in particular, smallpox, brought to the Americas by European colonists. It is unclear how many Native Americans were killed by foreign diseases after the arrival of Columbus in the Americas, but the numbers have been estimated to be close to 70% of the indigenous population. The damage done by this disease significantly aided European attempts to displace and conquer the native population.[145]
A pandemic is a worldwide epidemic. The 1918 flu pandemic, commonly referred to as the Spanish flu, was a category 5 influenza pandemic caused by an unusually severe and deadly influenza A virus. The victims were often healthy young adults, in contrast to most influenza outbreaks, which predominantly affect juvenile, elderly, or otherwise-weakened patients.[146]
The Spanish flu pandemic lasted from 1918 to 1919. Older estimates say it killed 40–50 million people,[147] while more recent research suggests that it may have killed as many as 100 million people, or 5% of the world's population in 1918.[148] Most researchers believe that HIV originated in sub-Saharan Africa during the 20th century;[149] it is now a pandemic, with an estimated 38.6 million people now living with the disease worldwide.[150] The Joint United Nations Programme on HIV/AIDS (UNAIDS) and the World Health Organization (WHO) estimate that AIDS has killed more than 25 million people since it was first recognised on June 5, 1981, making it one of the most destructive epidemics in recorded history.[151] In 2007 there were 2.7 million new HIV infections and 2 million HIV-related deaths.[152]

Marburg virus
Several highly lethal viral pathogens are members of the Filoviridae. Filoviruses are filament-like viruses that cause viral hemorrhagic fever, and include the ebola and marburg viruses. The Marburg virus attracted widespread press attention in April 2005 for an outbreak in Angola. Beginning in October 2004 and continuing into 2005, the outbreak was the world's worst epidemic of any kind of viral hemorrhagic fever.[153]
Cancer
For more details on this topic, see Oncovirus.
Viruses are an established cause of cancer in humans and other species. Viral cancers occur only in a minority of infected persons (or animals). Cancer viruses come from a range of virus families, including both RNA and DNA viruses, and so there is no single type of "oncovirus" (an obsolete term originally used for acutely transforming retroviruses). The development of cancer is determined by a variety of factors such as host immunity[154] and mutations in the host.[155] Viruses accepted to cause human cancers include some genotypes of human papillomavirus, hepatitis B virus, hepatitis C virus, Epstein-Barr virus, Kaposi's sarcoma-associated herpesvirus and human T-lymphotropic virus. The most recently discovered human cancer virus is a polyomavirus (Merkel cell polyomavirus) that causes most cases of a rare form of skin cancer called Merkel cell carcinoma.[156] Hepatitis viruses can develop into a chronic viral infection that leads to liver cancer.[157][158] Infection by human T-lymphotropic virus can lead to tropical spastic paraparesis and adult T-cell leukemia.[159] Human papillomaviruses are an established cause of cancers of cervix, skin, anus, and penis.[160] Within the Herpesviridae, Kaposi's sarcoma-associated herpesvirus causes Kaposi's sarcoma and body cavity lymphoma, and Epstein–Barr virus causes Burkitt's lymphoma, Hodgkin’s lymphoma, B lymphoproliferative disorder, and nasopharyngeal carcinoma.[161] Merkel cell polyomavirus closely related to SV40 and mouse polyomaviruses that have been used as animal models for cancer viruses for over 50 years.[162]
Host defence mechanisms
See also: Immune system
The body's first line of defence against viruses is the innate immune system. This comprises cells and other mechanisms that defend the host from infection in a non-specific manner. This means that the cells of the innate system recognise, and respond to, pathogens in a generic way, but, unlike the adaptive immune system, it does not confer long-lasting or protective immunity to the host.[163]
RNA interference is an important innate defence against viruses.[164] Many viruses have a replication strategy that involves double-stranded RNA (dsRNA). When such a virus infects a cell, it releases its RNA molecule or molecules, which immediately bind to a protein complex called dicer that cuts the RNA into smaller pieces. A biochemical pathway called the RISC complex is activated, which degrades the viral mRNA and the cell survives the infection. Rotaviruses avoid this mechanism by not uncoating fully inside the cell and by releasing newly produced mRNA through pores in the particle's inner capsid. The genomic dsRNA remains protected inside the core of the virion.[165][166]
When the adaptive immune system of a vertebrate encounters a virus, it produces specific antibodies that bind to the virus and render it non-infectious. This is called humoral immunity. Two types of antibodies are important. The first, called IgM, is highly effective at neutralizing viruses but is produced by the cells of the immune system only for a few weeks. The second, called IgG, is produced indefinitely. The presence of IgM in the blood of the host is used to test for acute infection, whereas IgG indicates an infection sometime in the past.[167] IgG antibody is measured when tests for immunity are carried out.[168]
Two rotaviruses: the one on the right is coated with antibodies that stop its attaching to cells and infecting them
A second defence of vertebrates against viruses is called cell-mediated immunity and involves immune cells known as T cells. The body's cells constantly display short fragments of their proteins on the cell's surface, and, if a T cell recognises a suspicious viral fragment there, the host cell is destroyed by killer T cells and the virus-specific T-cells proliferate. Cells such as the macrophage are specialists at this antigen presentation.[169] The production of interferon is an important host defence mechanism. This is a hormone produced by the body when viruses are present. Its role in immunity is complex; it eventually stops the viruses from reproducing by killing the infected cell and its close neighbours.[170]
Not all virus infections produce a protective immune response in this way. HIV evades the immune system by constantly changing the amino acid sequence of the proteins on the surface of the virion. These persistent viruses evade immune control by sequestration, blockade of antigen presentation, cytokine resistance, evasion of natural killer cell activities, escape from apoptosis, and antigenic shift.[171] Other viruses, called neurotropic viruses, are disseminated by neural spread where the immune system may be unable to reach them.
Prevention and treatment
Because viruses use vital metabolic pathways within host cells to replicate, they are difficult to eliminate without using drugs that cause toxic effects to host cells in general. The most effective medical approaches to viral diseases are vaccinations to provide immunity to infection, and antiviral drugs that selectively interfere with viral replication.
Vaccines
For more details on this topic, see Vaccination.
Vaccination is a cheap and effective way of preventing infections by viruses. Vaccines were used to prevent viral infections long before the discovery of the actual viruses. Their use has resulted in a dramatic decline in morbidity (illness) and mortality (death) associated with viral infections such as polio, measles, mumps and rubella.[172] Smallpox infections have been eradicated.[173] Vaccines are available to prevent over thirteen viral infections of humans,[174] and more are used to prevent viral infections of animals.[175] Vaccines can consist of live-attenuated or killed viruses, or viral proteins (antigens).[176] Live vaccines contain weakened forms of the virus, which do not cause the disease but, nonetheless, confer immunity. Such viruses are called attenuated. Live vaccines can be dangerous when given to people with a weak immunity, (who are described as immunocompromised), because in these people, the weakened virus can cause the original disease.[177] Biotechnology and genetic engineering techniques are used to produce subunit vaccines. These vaccines use only the capsid proteins of the virus. Hepatitis B vaccine is an example of this type of vaccine.[178] Subunit vaccines are safe for immunocompromised patients because they cannot cause the disease.[179] The yellow fever virus vaccine, a live-attenuated strain called 17D, is probably the safest and most effective vaccine ever generated.[180]
Antiviral drugs
For more details on this topic, see Antiviral drug.

Guanosine

The guanosine analogue Aciclovir
Antiviral drugs are often nucleoside analogues, (fake DNA building-blocks), which viruses mistakenly incorporate into their genomes during replication. The life-cycle of the virus is then halted because the newly synthesised DNA is inactive. This is because these analogues lack the hydroxyl groups, which, along with phosphorus atoms, link together to form the strong "backbone" of the DNA molecule. This is called DNA chain termination.[181] Examples of nucleoside analogues are aciclovir for Herpes simplex virus infections and lamivudine for HIV and Hepatitis B virus infections. Aciclovir is one of the oldest and most frequently prescribed antiviral drugs.[182] Other antiviral drugs in use target different stages of the viral life cycle. HIV is dependent on a proteolytic enzyme called the HIV-1 protease for it to become fully infectious. There is a large class of drugs called protease inhibitors that inactivate this enzyme.
Hepatitis C is caused by an RNA virus. In 80% of people infected, the disease is chronic, and without treatment, they are infected for the remainder of their lives. However, there is now an effective treatment that uses the nucleoside analogue drug ribavirin combined with interferon.[183] The treatment of chronic carriers of the hepatitis B virus by using a similar strategy using lamivudine has been developed.[184]
Infection in other species
Main article: Animal virology
Viruses infect all cellular life and, although viruses occur universally, each cellular species has its own specific range that often infect only that species.[185] Some viruses, called satellites, can only replicate within cells that have already been infected by another virus.[186] Viruses are important pathogens of livestock. Diseases such as Foot and Mouth Disease and bluetongue are caused by viruses.[187] Companion animals such as cats, dogs, and horses, if not vaccinated, are susceptible to serious viral infections. Canine parvovirus is caused by a small DNA virus and infections are often fatal in pups.[188] Like all invertebrates, the honey bee is susceptible to many viral infections.[189] Fortunately, most viruses co-exist harmlessly in their host and cause no signs or symptoms of disease.[2]
Plants
Main article: Plant pathology

There are many types of plant virus, but often they cause only a loss of yield, and it is not economically viable to try to control them. Plant viruses are often spread from plant to plant by organisms, known as vectors. These are normally insects, but some fungi, nematode worms, and single-celled organisms have been shown to be vectors. When control of plant virus infections is considered economical, for perennial fruits, for example, efforts are concentrated on killing the vectors and removing alternate hosts such as weeds.[190] Plant viruses are harmless to humans and other animals because they can reproduce only in living plant cells.[191]
Plants have elaborate and effective defence mechanisms against viruses. One of the most effective is the presence of so-called resistance (R) genes. Each R gene confers resistance to a particular virus by triggering localised areas of cell death around the infected cell, which can often be seen with the unaided eye as large spots. This stops the infection from spreading.[192] RNA interference is also an effective defence in plants.[193] When they are infected, plants often produce natural disinfectants that kill viruses, such as salicylic acid, nitric oxide, and reactive oxygen molecules.[194]
Plant virus particles or virus-like particles (VLPs) have applications in both biotechnology and nanotechnology. The capsids of most plant viruses are simple and robust structures and can be produced in large quantities either by the infection of plants or by expression in a variety of heterologous systems. Plant virus particles can be modified genetically and chemically to encapsulate foreign material and can be incorporated into supramolecular structures for use in biotechnology.[195]
Bacteria
Main article: Bacteriophage

Transmission electron micrograph of multiple bacteriophages attached to a bacterial cell wall
Bacteriophages are a common and diverse group of viruses and are the most abundant form of biological entity in aquatic environments – there are up to ten times more of these viruses in the oceans than there are bacteria,[196] reaching levels of 250,000,000 bacteriophages per millilitre of seawater.[197] These viruses infect specific bacteria by binding to surface receptor molecules and then entering the cell. Within a short amount of time, in some cases just minutes, bacterial polymerase starts translating viral mRNA into protein. These proteins go on to become either new virions within the cell, helper proteins, which help assembly of new virions, or proteins involved in cell lysis. Viral enzymes aid in the breakdown of the cell membrane, and, in the case of the T4 phage, in just over twenty minutes after injection over three hundred phages could be released.[198]
The major way bacteria defend themselves from bacteriophages is by producing enzymes that destroy foreign DNA. These enzymes, called restriction endonucleases, cut up the viral DNA that bacteriophages inject into bacterial cells.[199] Bacteria also contain a system that uses CRISPR sequences to retain fragments of the genomes of viruses that the bacteria have come into contact with in the past, which allows them to block the virus's replication through a form of RNA interference.[200][201] This genetic system provides bacteria with acquired immunity to infection.
Archaea
Some viruses replicate within archaea: these are double-stranded DNA viruses with unusual and sometimes unique shapes.[5][75] These viruses have been studied in most detail in the thermophilic archaea, particularly the orders Sulfolobales and Thermoproteales.[202] Defences against these viruses may involve RNA interference from repetitive DNA sequences within archaean genomes that are related to the genes of the viruses.[203][204]
Role in aquatic ecosystems
Main article: Marine bacteriophage
Viruses are the most abundant biological entity in aquatic environments:[1] a teaspoon of seawater contains about one million of them.[205] They are essential to the regulation of saltwater and freshwater ecosystems.[206] Most of these viruses are bacteriophages, which are harmless to plants and animals. They infect and destroy the bacteria in aquatic microbial communities, comprising the most important mechanism of recycling carbon in the marine environment. The organic molecules released from the bacterial cells by the viruses stimulates fresh bacterial and algal growth.[207]
Microorganisms constitute more than 90% of the biomass in the sea. It is estimated that viruses kill approximately 20% of this biomass each day and that there are 15 times as many viruses in the oceans as there are bacteria and archaea. Viruses are the main agents responsible for the rapid destruction of harmful algal blooms,[208] which often kill other marine life.[209] The number of viruses in the oceans decreases further offshore and deeper into the water, where there are fewer host organisms.[210]
The effects of marine viruses are far-reaching; by increasing the amount of photosynthesis in the oceans, viruses are indirectly responsible for reducing the amount of carbon dioxide in the atmosphere by approximately 3 gigatonnes of carbon per year.[210]
Like any organism, marine mammals are susceptible to viral infections. In 1988 and 2002, thousands of harbour seals were killed in Europe by phocine distemper virus.[211] Many other viruses, including caliciviruses, herpesviruses, adenoviruses and parvoviruses, circulate in marine mammal populations.[210]
Role in evolution
Main article: Horizontal gene transfer
Viruses are an important natural means of transferring genes between different species, which increases genetic diversity and drives evolution.[7] It is thought that viruses played a central role in the early evolution, before the diversification of bacteria, archaea and eukaryotes and at the time of the last universal common ancestor of life on Earth.[212] Viruses are still one of the largest reservoirs of unexplored genetic diversity on Earth.[210]
Applications
Life sciences and medicine
Scientist studying the H5N1 influenza virus.
Viruses are important to the study of molecular and cellular biology as they provide simple systems that can be used to manipulate and investigate the functions of cells.[213] The study and use of viruses have provided valuable information about aspects of cell biology.[214] For example, viruses have been useful in the study of genetics and helped our understanding of the basic mechanisms of molecular genetics, such as DNA replication, transcription, RNA processing, translation, protein transport, and immunology.
Geneticists often use viruses as vectors to introduce genes into cells that they are studying. This is useful for making the cell produce a foreign substance, or to study the effect of introducing a new gene into the genome. In similar fashion, virotherapy uses viruses as vectors to treat various diseases, as they can specifically target cells and DNA. It shows promising use in the treatment of cancer and in gene therapy. Eastern European scientists have used phage therapy as an alternative to antibiotics for some time, and interest in this approach is increasing, because of the high level of antibiotic resistance now found in some pathogenic bacteria.[215]
Expression of heterologous proteins by viruses is the basis of several manufacturing processes that are currently being used for the production of various proteins such as vaccine antigens and antibodies. Industrial processes have been recently developed using viral vectors and a number of pharmaceutical proteins are currently in pre-clinical and clinical trials.[216]
Materials science and nanotechnology
Current trends in nanotechnology promise to make much more versatile use of viruses. From the viewpoint of a materials scientist, viruses can be regarded as organic nanoparticles. Their surface carries specific tools designed to cross the barriers of their host cells. The size and shape of viruses, and the number and nature of the functional groups on their surface, is precisely defined. As such, viruses are commonly used in materials science as scaffolds for covalently linked surface modifications. A particular quality of viruses is that they can be tailored by directed evolution. The powerful techniques developed by life sciences are becoming the basis of engineering approaches towards nanomaterials, opening a wide range of applications far beyond biology and medicine.[217]
Because of their size, shape, and well-defined chemical structures, viruses have been used as templates for organizing materials on the nanoscale. Recent examples include work at the Naval Research Laboratory in Washington, DC, using Cowpea Mosaic Virus (CPMV) particles to amplify signals in DNA microarray based sensors. In this application, the virus particles separate the fluorescent dyes used for signalling to prevent the formation of non-fluorescent dimers that act as quenchers.[218] Another example is the use of CPMV as a nanoscale breadboard for molecular electronics.[219]
Synthetic viruses
Many viruses can be synthesized de novo (“from scratch”) and the first synthetic virus was created in 2002.[220] Although somewhat of a misconception, it is not the actual virus that is synthesized, but rather its DNA genome (in case of a DNA virus), or a cDNA copy of its genome (in case of RNA viruses). For many virus families the naked synthetic DNA or RNA (once enzymatically converted back from the synthetic cDNA) is infectious when introduced into a cell. That is, they contain all the necessary information to produce new viruses. This technology is now being used to investigate novel vaccine strategies.[221] The ability to synthesize viruses has far-reaching consequences, since viruses can no longer be regarded as extinct, as long as the information of their genome sequence is known and permissive cells are available. Currently, the full-length genome sequences of 2408 different viruses (including smallpox) are publicly available at an online database, maintained by the National Institute of Health.[222]
Weapons
For more details on this topic, see Biological warfare.
The ability of viruses to cause devastating epidemics in human societies has led to the concern that viruses could be weaponised for biological warfare. Further concern was raised by the successful recreation of the infamous 1918 influenza virus in a laboratory.[223] The smallpox virus devastated numerous societies throughout history before its eradication. There are officially only two centers in the world that keep stocks of smallpox virus – the Russian Vector laboratory, and the United States Centers for Disease Control.[224] But fears that it may be used as a weapon are not totally unfounded; the vaccine for smallpox has sometimes severe side-effects – during the last years before the eradication of smallpox disease more people became seriously ill as a result of vaccination than did people from smallpox and smallpox vaccination is no longer universally practiced.Thus, much of the modern human population has almost no established resistance to smallpox.
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Kanguru Indonesia Di Papua

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Kanguru ternyata tidak hanya terdapat di Autralia saja. Ternyata di Indonesia, tepatnya di Papua, juga memiliki Kangguru, spisies yang mempunyai ciri khas kantung di perutnya (Marsupialia). Kanguru Papua ini memiliki ukuran yang lebih kecil dibandingkan dengan Kanguru Australia. Sayang Kanguru yang terdiri atas Kanguru tanah dan Kanguru pohon ini mulai langka sehingga termasuk binatang (satwa) Indonesia yang dilindungi dari kepunahan.

Kangguru Papua terdiri atas dua genus yaitu dendrolagus (Kanguru Pohon) dan thylogale (Kanguru Tanah). Kanguru pohon sebagian besar masa hidupnya ada di pohon. Sekalipun begitu satwa tersebut juga sering turun ke tanah, misalnya bila sedang mencari air minum. Moncong kanguru pohon bentuknya lebih runcing jika dibandingkan dengan moncong kanguru darat. Ekornya agak panjang dan bulat, berbulu lebat dari pangkal sampai ekornya. Sedangkan pada kanguru darat kedua kaki depannya lebih pendek dari pada kaki belakangnya, Cakarnya pun lebih kecil. Moncongnya agak tumpul dan tidak berbulu. Ekornya makin meruncing ke ujung, bulunya tidak begitu lebat.

Kangguru Tanah (lau-lau atau paunaro):

Thylogale bruniiThylogale brunii (Dusky Pademelon) merupakan jenis kangguru terkecil yang ada di dunia. Beratnya antara 3-6 kilogram, tetapi ada juga yang 10 kilogram. Panjang tubuhnya sekitar 90 sentimeter dengan lebar sekitar 50 sentimeter. Satwa langka yang dilindungi ini adalah hewan endemik Papua, dan hanya terdapat di Papua di kawasan dataran rendah di hutan-hutan di wilayah Selatan Papua, dan Papua Niugini. Di Indonesia Thylogale brunii terdapat antara lain di Taman Nasional Wasur (Kabupaten

Thylogale stigmata,

Merauke) dan Taman Nasional Gunung Lorentz (Mimika).

Thylogale stigmata (red-legged pademelon) merupakan jenis yang hidup di daerah pantai selatan Papua. Thylogale stigmata mempunyai warna kulit tubuh lebih cerah yaitu kuning kecokelatan.

Thylogale browniThylogale brownii (Brown’s pademelon). Selain di Papua, binatang ini juga terdapat di Papua New Guinea.

Kangguru pohon (lau-lau):

Dendrolagus pulcherrimus (Kanguru Pohon Mantel Emas) merupakan sejenis kanguru pohon yang hanya ditemukan di hutan pegunungan pulau Irian. Spesies ini memiliki rambut-rambut halus pendek berwarna coklat muda. Leher, pipi dan kakinya berwarna kekuningan. Sisi bawah perut berwarna lebih pucat dengan dua garis keemasan Dendrolagus pulcherrimusdipunggungnya. Ekor panjang dan tidak prehensil dengan lingkaran-lingkaran terang.

Penampilan Kanguru-pohon Mantel-emas serupa dengan Kanguru pohon Hias. Perbedaannya adalah Kanguru-pohon Mantel-emas memiliki warna muka lebih terang atau merah-muda, pundak keemasan, telinga putih dan berukuran lebih kecil dari Kanguru-pohon Hias. Beberapa ahli menempatkan Kanguru-pohon Mantel-emas sebagai subspesies dari Kanguru-pohon Hias.

Kanguru-pohon Mantel-emas merupakan salah satu jenis kanguru-pohon yang paling terancam kepunahan diantara semua kanguru pohon. Spesies ini telah punah di sebagian besar daerah habitat aslinya

Dendrolagus goodfellowi (disebut Kanguru Pohon Goodfellow atau kanguru pohon hias atau Goodfellow’s Tree-kangaroo) merupakan jenis kanguru pohon yang paling sering ditemui. Kulit tubuhnya berwarna

Dendrolagus mbaiso

cokelat sawo matang dan banyak terdapat di hutan hujan di pulau Papua

Dendrolagus mbaiso (disebut sebagai Kanguru Pohon Mbaiso atau Dingiso) kanguru ini ditemukan di hutan montane yang tinggi dan subalpine semak belukar di Puncak Sudirman. Kanguru pohon ini mempunyai bulu hitam dengan kombinasi putih di bagian dadanya.

Dengrolagus dorianus atau disebut sebagai Kangguru Pohon Ndomea atau Doria’s Tree-kangaroo.

Dendrolagus ursinus (disebut Vogelkop Tree-kangaroo atau Kanguru Pohon Nemena) merupakan kanguru pohon yang paling awal terklasifikasikan. Mempunyai telinga panjang dan ekor panjang dan hitam.

Dendrolagus dorianus, Dendrolagus ursinus, Dendrolagus inustus

Dendrolagus inustus disebut juga sebagai Kanguru Pohon Wakera atau Grizzled Tree-kangaroo.

Dendrolagus stellarum disebut juga sebagai Seri’s Tree-kangaroo. Kanguru pohon ini terdapat di Tembagapura.

Klasifikasi: Kerajaan: Animalia; Filum: Chordata; Kelas: Mammalia; Infrakelas: Marsupialia; Ordo: Diprotodontia; Famili: Macropodidae Genus: Dendrolagus dan Thylogale
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Cell (biology)

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The cell is the functional basic unit of life. It was discovered by Robert Hooke and is the functional unit of all known living organisms. It is the smallest unit of life that is classified as a living thing, and is often called the building block of life.[1] Some organisms, such as most bacteria, are unicellular (consist of a single cell). Other organisms, such as humans, are multicellular. Humans have about 100 trillion or 1014 cells; a typical cell size is 10 µm and a typical cell mass is 1 nanogram. The largest cells are about 135 µm in the anterior horn in the spinal cord while granule cells in the cerebellum, the smallest, can be some 4 µm and the longest cell can reach from the toe to the lower brain stem (Pseudounipolar cells).[2] The largest known cells are unfertilised ostrich egg cells, which weigh 3.3 pounds.[3][4]

In 1835, before the final cell theory was developed, Jan Evangelista Purkyně observed small "granules" while looking at the plant tissue through a microscope. The cell theory, first developed in 1839 by Matthias Jakob Schleiden and Theodor Schwann, states that all organisms are composed of one or more cells, that all cells come from preexisting cells, that vital functions of an organism occur within cells, and that all cells contain the hereditary information necessary for regulating cell functions and for transmitting information to the next generation of cells.[5]

The word cell comes from the Latin cellula, meaning, a small room. The descriptive term for the smallest living biological structure was coined by Robert Hooke in a book he published in 1665 when he compared the cork cells he saw through his microscope to the small rooms monks lived in.[6]
Anatomy

There are two types of cells: eukaryotic and prokaryotic. Prokaryotic cells are usually independent, while eukaryotic cells are often found in multicellular organisms.
Prokaryotic cells
Main article: Prokaryote
Diagram of a typical prokaryotic cell

The prokaryote cell is simpler, and therefore smaller, than a eukaryote cell, lacking a nucleus and most of the other organelles of eukaryotes. There are two kinds of prokaryotes: bacteria and archaea; these share a similar structure.

Nuclear material of prokaryotic cell consist of a single chromosome that is in direct contact with cytoplasm. Here, the undefined nuclear region in the cytoplasm is called nucleoid.

A prokaryotic cell has three architectural regions:

* On the outside, flagella and pili project from the cell's surface. These are structures (not present in all prokaryotes) made of proteins that facilitate movement and communication between cells;
* Enclosing the cell is the cell envelope – generally consisting of a cell wall covering a plasma membrane though some bacteria also have a further covering layer called a capsule. The envelope gives rigidity to the cell and separates the interior of the cell from its environment, serving as a protective filter. Though most prokaryotes have a cell wall, there are exceptions such as Mycoplasma (bacteria) and Thermoplasma (archaea). The cell wall consists of peptidoglycan in bacteria, and acts as an additional barrier against exterior forces. It also prevents the cell from expanding and finally bursting (cytolysis) from osmotic pressure against a hypotonic environment. Some eukaryote cells (plant cells and fungi cells) also have a cell wall;
* Inside the cell is the cytoplasmic region that contains the cell genome (DNA) and ribosomes and various sorts of inclusions. A prokaryotic chromosome is usually a circular molecule (an exception is that of the bacterium Borrelia burgdorferi, which causes Lyme disease). Though not forming a nucleus, the DNA is condensed in a nucleoid. Prokaryotes can carry extrachromosomal DNA elements called plasmids, which are usually circular. Plasmids enable additional.
* functions, such as antibiotic resistance.

Eukaryotic cells
Main article: Eukaryote
Diagram of a typical animal (eukaryotic) cell, showing subcellular components. Organelles:
(1) nucleolus
(2) nucleus
(3) ribosome
(4) vesicle
(5) rough endoplasmic reticulum (ER)
(6) Golgi apparatus
(7) Cytoskeleton
(8) smooth endoplasmic reticulum
(9) mitochondria
(10) vacuole
(11) cytoplasm
(12) lysosome
(13) centrioles within centrosome

Eukaryotic cells are about 15 times wider than a typical prokaryote and can be as much as 1000 times greater in volume. The major difference between prokaryotes and eukaryotes is that eukaryotic cells contain membrane-bound compartments in which specific metabolic activities take place. Most important among these is a cell nucleus, a membrane-delineated compartment that houses the eukaryotic cell's DNA. This nucleus gives the eukaryote its name, which means "true nucleus." Other differences include:

* The plasma membrane resembles that of prokaryotes in function, with minor differences in the setup. Cell walls may or may not be present.
* The eukaryotic DNA is organized in one or more linear molecules, called chromosomes, which are associated with histone proteins. All chromosomal DNA is stored in the cell nucleus, separated from the cytoplasm by a membrane. Some eukaryotic organelles such as mitochondria also contain some DNA.
* Many eukaryotic cells are ciliated with primary cilia. Primary cilia play important roles in chemosensation, mechanosensation, and thermosensation. Cilia may thus be "viewed as sensory cellular antennae that coordinate a large number of cellular signaling pathways, sometimes coupling the signaling to ciliary motility or alternatively to cell division and differentiation."[7]
* Eukaryotes can move using motile cilia or flagella. The flagella are more complex than those of prokaryotes.
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Melatih bicara pada burung beo

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Burung beo terkenal pandai bicara. Tapi jangan salah tafsir, tidak ada jaminan sama sekali bahwa apabila kita membeli burung maka burung tersebut akan menjadi bagian dari keluarga dan kelak dapat bicara. Melatih burung kakatua bicara memerlukan rasa kasih sayang, kesabaran, dan konsisten. Burung yang masih kecil pada umumnya jauh lebih mudah dilatih dari pada burung yang sudah besar.


Kasih sayang

Hampir semua binatang peliharaan memerlukan perhatian dan kasih sayang dari majikannya. Perhatian dan kasih sayang ini akan dibalas olehnya misalnya ditunjukkan pada saat si majikan akan pergi dari atau pulang ke rumah. Sebaliknya apabila si majikan tidak memperhatikan atau menunjukkan kasih sayangnya maka merekapun tidak akan peduli terhadap apa yang diinginkan oleh majikannya. Dengan demikian diperlukan kesungguhan tanpa syarat untuk menerima mereka apapun hasilnya apakah nantinya mereka akan bicara atau tidak. Burung kakatua disamping pintar juga terkenal sangat sensitif. Konon mereka dapat mempengaruhi Anda apabila mereka telah mengenal Anda.


Kesabaran

Seperti halnya melatih anak kecil untuk belajar berbicara, maka diperlukan kesabaran. Latihan sebaiknya dilakukan secara bertahap dan janganlah membuat target waktu yang pada akhirnya hanya akan menjadi beban berupa kekecewaan apabila harapan ternyata tidak terwujud. Perasaan kecewa juga dapat menimpa si burung kecil yang punya perasaan sensitif. Siapa tahu ketidaktaatan pada perintah adalah sebagai reaksi karena kecewa pada sikap Anda. Hendaknya selalu diingat bahwa bagaimanapun seekor burung tidak mungkin dapat disamakan dengan anak kecil yang dalam suatu periode waktu tertentu sudah dapat berbicara.


Konsisten

Methode pelatihan harus dilakukan secara konsisten dan disertai dengan ketulusan. Setiap perkataan atau phrase yang diajarkan harus ditunjang oleh arti atau tanda yang membedakannya dari perkataan yang lain. Sebagai contoh, pada waktu matahari terbit secara rutin dan berulang-ulang ucapkanlah "Selamat pagi" dan pada waktu matahari terbenam ucapkanlah "Selamat malam". Dari perbedaan waktu pagi dan malam si burung akan menyadari perbedaan arti dari ke dua perkataan tersebut.
Janganlah dicampur adukkan yang akan membuat dia menjadi bingung.

Contoh-contoh yang lain adalah:
• Katakan "Mandi dulu!" pada saat dia akan dimandikan dan jangan mengatakan kata itu apabila tidak akan dimandikan.
• Katakan "Ada tamu" pada saat menerima tamu, atau katakan "Sepi sekali" apabila tidak ada orang.
• Katakan "Mau brokoli?" saat dia dikasi makan brokoli. Apabila dia tidak mau makan dan makanan tersebut dikeluarkan lagi katakan "Tidak mau?", atau apabila terus disimpan didekatnya katakan "Buat nanti ya!"
• Katakan "Selamat tinggal" pada waktu mau pergi lama misalnya pergi bekerja dan apabila akan segera kembali katakan "Sebentar nanti kembali".

Sebelum mahir benar janganlah diajak dulu bercanda, misalnya menawarkan makanan tapi tidak jadi diberikan. Sebaiknya dihindarkan hal-hal yang menjurus atau akan menyebabkan dia mengeluarkan kata-kata jorok seperti menempatkannya di dekat kamar mandi
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sifat air

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Di samping sifat-sifat fisiknya, sifat-sifat kimia air juga sangat sesuai untuk kehidupan. Di antara sifat-sifat kimia air, yang terutama adalah bahwa air merupakan pelarut yang baik: Hampir semua zat kimia bisa dilarutkan dalam air.
Konsekuensi yang sangat penting dari sifat kimia ini adalah mineral-mineral dan zat-zat yang berguna yang terkandung tanah terlarut dalam air dan dibawa ke laut oleh sungai. Diperkirakan lima milyar ton zat dibawa ke sungai setiap tahun. Zat-zat tersebut penting bagi kehidupan laut.
Air juga mempercepat (mengkatalisis) hampir semua reaksi kimia yang diketahui. Sifat kimia air yang penting lainnya adalah reaktivitas kimianya ada pada tingkat yang ideal. Air tidak terlalu reaktif yang membuatnya berpotensi merusak (seperti asam sulfat) dan tidak juga terlalu lamban (seperti argon yang tidak bereaksi kimia). Mengutip Michael Denton: “Tampaknya, seperti semua sifatnya yang lain, reaktivitas air ideal baik bagi peran biologis maupun geologisnya.”
Detail lain tentang kesesuaian sifat-sifat kimia air untuk kehidupan selalu terungkap ketika para peneliti menyelidiki zat tersebut lebih jauh. Harold Morowitz, seorang profesor biofisika dari Universitas Yale, menyatakan:
Beberapa tahun ke belakang telah menyaksikan studi yang berkembang tentang sebuah sifat air yang baru dipahami (yaitu, konduktansi proton) yang ternyata hampir unik bagi zat tersebut, merupakan unsur kunci transfer energi biologis, dan tentu saja penting bagi asal usul kehidupan. Semakin dalam dipelajari, semakin terkesan sebagian dari kami dengan kesesuaian alam dalam bentuk yang begitu tepat.
Viskositas Ideal Air
Setiap kali kita memikirkan zat cair, bayangan yang terbentuk dalam pikiran kita adalah zat yang sangat cair. Kenyataannya, zat cair yang berbeda memiliki tingkat viskositas (kekentalan) yang berbeda: Kekentalan ter/aspal, gliserin, minyak zaitun, dan asam sulfat, misalnya, sangat bervariasi. Dan jika kita bandingkan zat-zat cair tersebut dengan air, perbedaannya menjadi lebih jelas. Air 10 juta kali lebih cair daripada aspal, 1.000 kali lebih cair daripada gliserin, 100 kali lebih cair daripada minyak zaitun, dan 25 kali lebih cair daripada asam sulfat.
Seperti yang ditunjukkan oleh perbandingan singkat itu, air memiliki tingkat viskositas yang sangat rendah. Bahkan, jika kita mengabaikan beberapa zat seperti eter dan hidrogen cair, air ternyata berviskositas lebih kecil dari apa pun kecuali gas.
Apakah kekentalan air yang rendah menguntungkan bagi kita? Akan berbedakah keadaan jika zat cair vital ini memiliki kekentalan lebih besar atau lebih kecil? Michael Denton menjawabnya untuk kita:
Kesesuaian air akan berkurang jika kekentalan air lebih rendah. Struktur sistem kehidupan akan bergerak jauh lebih acak di bawah pengaruh gaya-gaya deformasi jika kekentalan air sama rendahnya dengan hidrogen cair…. Jika kekentalan air sangat lebih rendah, struktur yang rawan akan mudah dikacaukan… dan air tidak akan mungkin mendukung struktur mikroskopik rumit yang permanen. Arsitektur molekular sel yang rawan mungkin tidak akan bertahan.
Jika kekentalan lebih tinggi, gerak terkontrol makromolekul yang besar dan terutama struktur seperti mitokondria dan organel-organel kecil tidak akan mungkin, demikian pula proses-proses seperti pembelahan sel. Semua aktivitas penting sel akan membeku dengan efektif, dan jenis-jenis kehidupan seluler yang jauh menyerupai yang biasa kita kenal akan tidak mungkin ada. Perkembangan organisme yang lebih tinggi, yang secara kritis bergantung pada kemampuan sel untuk bergerak dan merangkak dalam fase embriogenesis, pasti tidak mungkin terjadi jika kekentalan air sedikit saja lebih tinggi dari kekentalan normal. Kekentalan air yang rendah tidak hanya penting untuk gerak seluler, namun juga untuk sistem sirkulasi.
Semua makhluk hidup dengan ukuran tubuh lebih dari seperempat milimeter memiliki sistem sirkulasi pusat. Hal ini karena pada ukuran lebih dari itu, tidak mungkin makanan dan oksigen didifusikan ke seluruh tubuh organisme. Artinya, makanan dan oksigen tidak bisa lagi masuk secara langsung ke dalam sel, dan produk sampingannya pun tidak bisa dibuang begitu saja. Ada banyak sel dalam tubuh sebuah organisme, karenanya oksigen dan energi yang diambil tubuh perlu didistribusikan (dipompa) ke tubuh melalui “saluran”; dan saluran lain diperlukan pula untuk mengangkut buangan. “Saluran” ini adalah pembuluh vena dan arteri dalam sistem sirkulasi. Jantung adalah pompa yang menjaga sistem ini agar terus bekerja, sementara zat yang dibawa melalui “saluran” itu adalah cairan yang kita sebut “darah”, yang sebagian besar merupakan air, (95 % dari plasma darah-materi yang tersisa setelah sel darah, protein, dan hormon telah dikeluarkan-adalah air.)
Itulah sebabnya kekentalan air sangat penting agar sistem sirkulasi berfungsi efisien. Jika air memiliki kekentalan seperti aspal misalnya, pasti tidak ada jantung organisme yang dapat memompanya. Jika air memiliki kekentalan minyak zaitun, yang lebih kecil seratus juta kali daripada aspal, jantung mungkin bisa memompanya, namun akan sangat sulit dan darah tidak akan pernah bisa mencapai miliaran kapiler di seluruh pelosok tubuh kita.
Mari kita cermati kapiler-kapiler tersebut. Tujuannya adalah membawa oksigen, makanan, hormon, dan lain-lain yang penting bagi kehidupan ke setiap sel di seluruh tubuh. Jika sebuah sel berjarak lebih dari 50 mikron (satu mikron adalah satu milimeter dibagi seribu) dari kapiler, maka sel tersebut tidak bisa memanfaatkan “layanan” kapiler. Sel dengan jarak 50 mikron dari kapiler akan mati kelaparan.
Itulah sebabnya tubuh manusia diciptakan sedemikian rupa sehingga kapilernya membentuk jejaring yang menjangkau semua sel. Tubuh manusia normal memiliki sekitar 5 miliar kapiler yang panjangnya, jika dibentangkan, sekitar 950 kilometer. Pada sebagian mamalia, ada sebanyak 3.000 kapiler dalam setiap satu sentimeter persegi jaringan otot. Jika Anda menyatukan sepuluh ribu kapiler terkecil dalam tubuh manusia, hasil jalinannya mungkin setebal isi pensil. Diameter kapiler bervariasi dari 3-5 mikron: sama dengan tiga sampai lima milimeter dibagi seribu.
Jika darah akan menembus jalan sesempit itu tanpa terhambat atau melambat, maka darah harus cair, dan berkat kekentalan air yang rendah, demikian adanya. Menurut Michael Denton, jika kekentalan air sedikit saja lebih besar dari seharusnya, sistem sirkuasi darah sama sekali tidak bermanfaat:
Sistem kapiler akan bekerja hanya jika zat cair yang dipompa melalui seluruh tabungnya memiliki kekentalan yang sangat rendah. Kekentalan rendah sangat penting karena aliran berbanding terbalik dengan kekentalan… Dari sini mudah dilihat bahwa jika kekentalan air memiliki nilai hanya beberapa kali lebih besar dari seharusnya, memompa darah melalui kapiler akan memerlukan tekanan besar, dan hampir semua jenis sistem sirkulasi pasti tidak akan bekerja…Jika kekentalan air sedikit lebih besar, dan kapiler terkecil berdiameter 10 mikron alih-alih 3 mikron, maka kapiler harus memenuhi hampir semua jaringan otot agar dapat menyediakan oksigen dan glukosa dengan efektif. Jelas sekali rancangan bentuk kehidupan makroskopik tidak akan mungkin dan sangat terbatasi…. Maka tampaknya kekentalan air harus demikian adanya agar menjadi perantara yang sesuai bagi kehidupan.
Dengan kata lain, seperti semua sifat lainnya, kekentalan air juga “dirancang khusus” untuk kehidupan. Mencermati kekentalan zat-zat cair berbeda, kita lihat antara satu zat dengan yang lain ada selisih hingga miliaran kali. Di antara miliaran itu hanya ada satu zat cair dengan kekentalan yang diciptakan tepat seperti yang diperlukan: air.
Kesimpulan
Segala sesuatu yang sudah kita ketahui dalam bab ini sejak awal menunjukkan bahwa sifat termal, fisik, kimia, dan kekentalan air tepat seperti seharusnya demi keberadaan kehidupan. Air dirancang begitu sempurna untuk kehidupan, sehingga dalam beberapa kasus, hukum-hukum alam dilanggar demi tujuan tersebut. Contoh terbaik dari hal ini adalah pengembangan yang tidak terduga dan tidak dapat dipahami pada volume air ketika suhunya turun di bawah 4oC: Jika pengembangan tidak terjadi, es tidak akan mengambang, lautan akan membeku menjadi padatan total, dan kehidupan tidak mungkin ada.
Air “begitu tepat” untuk kehidupan, sampai-sampai tidak dapat dibandingkan dengan zat cair lain. Sebagian besar planet ini, dunia dengan atribut lain (suhu, cahaya, spektrum elektromagnetik, atmosfer, permukaan, dan lain-lain) yang semuanya sesuai untuk kehidupan, telah diisi air dengan jumlah tepat untuk kehidupan. Jelaslah bahwa semua itu bukan kebetulan, dan sebaliknya pasti merupakan rancangan yang disengaja.
Untuk menguraikannya dengan cara lain, semua sifat fisik dan kimia air menunjukkan bahwa dia diciptakan khusus untuk kehidupan. Bumi, yang sengaja diciptakan untuk tempat hidup umat manusia, dihidupkan dengan air yang khusus diciptakan untuk membentuk dasar kehidupan manusia. Dalam air, Allah telah memberi kita kehidupan dan dengannya Dia menumbuhkan makanan yang kita makan dari tanah.
Akan tetapi, aspek terpenting dari semua ini adalah bahwa kebenaran ini, yang telah ditemukan oleh ilmu pengetahuan modern, diungkapkan dalam Al Quran, yang diturunkan kepada umat manusia sebagai petunjuk empat belas abad yang lalu. Mengenai air dan umat manusia, dikemukakan firman Allah dalam Al Quran:
“Dialah, Yang telah menurunkan air hujan dari langit untuk kamu, sebagiannya menjadi minuman dan sebagiannya (menyuburkan) tumbuh-tumbuhan, yang pada (tempat tumbuhnya) kamu menggembalakan ternakmu. Dia menumbuhkan bagi kamu dengan air hujan itu tanam-tanaman; zaitun, kurma, anggur, dan segala macam buah-buahan…”
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