A sequence of three nucleotides on mRNA specifying an amino acid or other information is called a codon or genetic code. For example Triplet code AAA in DNA codes for phenylalanine amino acid in the protein. Triplet code AAA in DNA during transcription is changed into UUU code of RNA. Thus, AAA and UUU are DNA and RNA codon for amino acid phenylalanine.
Gene is actually a segment of the chromosome, composed of DNA thread of particular length controlling particular protein formation.
Gene is a DNA segment composed of a set of nucleotide. Nucleotides sequence within gene controls amino acid sequence within a protein. Four different types of DNA nucleotides within a DNA molecule direct the position of twenty different amino acids in the growing polypeptide chain of protein during the translation process. Actually, nucleotides within DNA chain make a code which directs the position of the specific amino acid within the protein chain. This code is called the Genetic code.
Is it possible for one nucleotide to control the position of one amino acid? Absolutely not, because four types of nucleotides could control only four different amino acids out of 20. If we consider a code in which two bases (e.g. AG ) make a set to control one amino acid, only 16 possible codons could be formed which are not enough to control 20 amino acid. But if there is a set of three bases (e.g. AGC) to control one amino acid, then 64 possible codons combinations of genetic code could be formed which are more than enough to control the position of 20 different amino acids.
“SO, we conclude that the genetic code is triplet code and each codon consists of 3 nucleotides bases”
Triplet genetic code confirmation
Triplet nature of genetic code was confirmed by different groups of scientists. In 1961 J. Heinrich Matthaei and Marshall Nierenberg were able to construct a synthetic RNA composed of Uracil base only. They used this RNA to form a protein. The protein was composed of phenylalanine amino acid only. It was concluded that phenylalanine amino acid is controlled by triplet codon UUU.
Later Nierenberg and Philip Leder developed a cell-free system, a test tube in which cytoplasmic contents of a cell were present, and assigned amino acid to each of the RNA codons.
These are genetic codes by which thousands of different types of genes within an organism are controlling the formation of thousands of different types of proteins, which control almost every aspect of organism i.e. growth, development, Physiology, etc.
Out of 64 RNA codons 61 code for some amino acid and rest three codons are stop codons, which terminate the translation process and stop protein synthesis.
Most amino acids have more than one codon, for example in the case of arginine, leucine, and serine amino acids each one of them has 6 different codons. In the case of leucine amino acid, these codons are CUA, CUC, CUG, CUU, UUA, and UUG. This helps in codes against the harmful effect of the mutation.
Each code has only one meaning i.e it codes only one amino acid. For example, AUG codes only one amino acid which is methionine. It can never code any other amino acid.
There is only one start codon (AUG, initiation codon) which starts the translation process, but to stop this process three stop codons are present i.e.UAA, UGA and UAG.
A specific tRNA molecule contains a set of three consecutive nucleotides that can base pair with the codon of mRNA. This set of nucleotide that can base pair with codon is called Anticodon. For example for codon of UGC on mRNA, tRNA will have anticodon ACG.
These will code same amino acids in all organisms, even it may be plant-animal of fungi, etc.
Francis Crick and his coworkers in 1961 predicted the triplet nature of the genetic and concluded that the code is not overlapping and degenerate in nature. They said that triplet codes follow each other in a linear order without interrupting commas or noncoding regions in bacterial DNA i.e. Introns. So, Genetic code was called commaless, without Introns. But after the discovery of Introns in 1977 within DNA, showed that all genes are not commaless or degenerate and overlap with each other and this is very common in eukaryotes.
The genetic code is a set of three nucleotides. Each nucleotide is named on the basis of one of the four nitrogenous bases found in each of them. Nucleotide having nitrogenous bases Adenine is assigned the “A” letter, and nucleotide containing Guanine base is assigned letter “G”. Similarly Cytosine and Thymine containing nucleotides are assigned letter “C” and “T” respectively. So. A, G, C, and T are letters of Genetic code.
University in genetic code means that with few exceptions in viruses rest all organisms use the same set of codes for directing their amino acid sequence. A single code found in all organisms will always code for the single specific amino acid.
The genetic code is composed by codons, which are the three-letter sequence of nucleotides. Each codon makes a link with specific anticodons of tRNA and in this way, it codes for one specific amino acid.
The genetic code is set of three nucleotides which specifies one amino acid of the protein chain. Consecutive triplet code exactly define location and type of amino acid to form a specific amino acid chain. The organism uses its specific codon sequence in forming peculiar protein and hence these codes regulate and control organism at the cellular level.
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