define ribosomes ..........................
Answers
Ribosomes are the cell organelles found inside the cell and composed of RNA and Proteins
Explanation:
A ribosome is a complex cellular mechanism used to translate genetic code into chains of amino acids. Long chains of amino acids fold and function as proteins in cells.
Function of a Ribosome
The function of a ribosome in any cell is to produce proteins. Proteins are used in almost all cellular functions; as catalysts they speed the time of reactions, as fibers they provide support, and many proteins function in specific tasks, like contracting muscle cells. All proteins start as deoxyribonucleic acid, or DNA. A special protein, RNA polymerase, is an enzyme that recognizes sequences in the DNA, binds to them with the help of other proteins, and creates a new information molecule which can travel from the nucleus to the cytosol of the cell. The strand of ribonucleic acid (RNA) produced by RNA polymerase is processed on its way out of the nucleus, and areas of the RNA that do not code for proteins are removed. The molecule is now known as a messenger RNA or mRNA.
Every mRNA is made of 4 different nucleic bases, known as nucleic acids. The base pairs are “read” in series of threes, making up codons. Each codon specifies a specific amino acid. All life on Earth uses the same 20 amino acids, and the codons used to call for those amino acids are nearly universal. The codon that starts all proteins is “AUG”. This stands for the sequence of nucleic bases: adenine, uracil, and guanine, respectively. A special RNA molecule that can bind to amino acids, known as a transfer RNA or tRNA, recognizes this sequence and binds to it. This particular tRNA carries a methionine amino acid. Depending on the protein being built, the next amino acid could be any one of the twenty.
This is where the ribosome comes in. Recognizing the structure of the mRNA bound to a tRNA, the two subunits of the ribosome (discussed below) can combine to start synthesizing protein from the mRNA strand. The ribosome acts as a large catalyst, forming peptide bonds between amino acids. The used tRNA is released back into the cytosol so it can bind to another amino acid. Eventually, the mRNA will present a codon to the ribosome that means “stop”. Special proteins will detach the string of amino acids from the last tRNA, and the protein will be released. This process of synthesizing new protein is pictured in the image below:
TRNA ribosomes diagram
Different proteins require different modifications and transport to various areas of the cell before they can function. A ribosome attached to the endoplasmic reticulum, for example, will deposit the newly formed protein inside, where it can be further modified and folded properly. Other proteins are formed directly in the cytosol where they can start acting as catalysts for various reactions. Ribosomes create all of these proteins that cells need, which is a lot. Per cell weigh, proteins account for about 20 percent. An average cell can have 10,000 different proteins, with on average a million copies of each. That is a lot of protein that must be synthesized, which is why the ribosome has evolved to be an efficient and speedy machine. On average, ribosomes can add 3-5 amino acids per second to a protein chain. Given that the largest known protein, titin, is around 30,000 amino acids, it only takes a ribosome 2-3 hours to synthesize. Short proteins, of only a few hundred amino acids, can be synthesized in minutes.
Once made, ribosomes cannot shut off. As soon as a tRNA has bound to an mRNA, they attach with the help of various other proteins, and the process of protein synthesis is initiated. Viruses have taken advantage of this fact. A virus is a small strand of DNA or RNA that replicates by hijacking a cell’s normal machinery, including ribosomes. The ribosomes of a cell are used by the virus to create proteins needed for it to replicate its genome and encapsulate itself so it can leave the cell. When a virus injects its genome into a cell, the molecule is treated the same as if the cell had created it. If the virus is DNA-based, the DNA makes its way into the nucleus, where the cell’s proteins translate it into RNA, which is translated by ribosomes into proteins. If the virus is RNA-based the viral RNA stays in the cytoplasm, where it can interact with ribosomes directly, creating new proteins. Either way, the virus will be able to create all the proteins required to replicate its genome and package the copies in new protein capsules, able to travel to a new host cell and spread the disease.