Genetic code mRNA codons

The Genetic Code mRNA Codons and the Amino Acid Each Codon Directs... 

The genetic code (Table 28 3) is the message earned by mRNA It is made up of triplets of adjacent nucleotide bases called codons Because mRNA has only four dif ferent bases and 20 ammo acids must be coded for codes using either one or two nucleotides per ammo acid are inadequate If nucleotides are read m sets of three how ever the four mRNA bases generate 64 possible words more than sufficent to code for 20 ammo acids... 

Section 28 11 Three RNAs are involved m gene expression In the transcription phase a strand of messenger RNA (mRNA) is synthesized from a DNA tern plate The four bases A G C and U taken three at a time generate 64 possible combinations called codons These 64 codons comprise the genetic code and code for the 20 ammo acids found m proteins plus start and stop signals The mRNA sequence is translated into a prescribed protein sequence at the ribosomes There small polynucleotides called... 

Translation of the Foreign Gene. The translation of a mRNA into a protein is governed by the presence of appropriate initiation sequences that specify binding of the mRNA to the ribosome. In addition, not all the codons of the genetic code are used equally frequently by all organisms. 

Twenty different amino acids are required for the synthesis of the cellular complement of proteins thus, there must be at least 20 distinct codons that make up the genetic code. Since there are only four different nucleotides in mRNA, each codon must consist of more than a single purine or pyrimidine nucleotide. Codons consisting of two nucleotides each could provide for only 16 (4 ) specific codons, whereas codons of three nucleotides could provide 64 4 ) specific codons. 

The anticodon region consists of seven nucleotides, and it recognizes the three-letter codon in mRNA (Figure 38-2). The sequence read from the 3 to 5 direction in that anticodon loop consists of a variable base-modified purine-XYZ-pyrimidine-pyrimidine-5h Note that this direction of reading the anticodon is 3 " to 5 whereas the genetic code in Table 38—1 is read 5 to 3 since the codon and the anticodon loop of the mRNA and tRNA molecules, respectively, are antipar-allel in their complementarity just like all other inter-molecular interactions between nucleic acid strands. 

The information contained in the DNA (i.e., the order of the nucleotides) is first transcribed into RNA. The messenger RNA thus formed interacts with the amino-acid-charged tRNA molecules at specific cell organelles, the ribosomes. The loading of the tRNA with the necessary amino acids is carried out with the help of aminoacyl-tRNA synthetases (see Sect. 5.3.2). Each separate amino acid has its own tRNA species, i.e., there must be at least 20 different tRNA molecules in the cells. The tRNAs contain a nucleotide triplet (the anticodon), which interacts with the codon of the mRNA in a Watson-Crick manner. It is clear from the genetic code that the different amino acids have different numbers of codons thus, serine, leucine and arginine each have 6 codewords, while methionine and tryptophan are defined by only one single nucleotide triplet. 

Genetic code Sequence of nucleotides along the DNA and coded in triplets (codons) along the mRNA that determines the sequence of amino acids in protein synthesis. The DNA sequence of a gene can be used to predict the mRNA sequence, and subsequently to predict the amino acid sequence. 

The triplet codon genetic codes of mRNA are translated into amino acids as shown below. 

Most genetic code tables designate the codons for amino adds as mRNA sequences (Figure 1-4-1). Important features of the genetic code include ... 

Translation of the information encoded in DNA, expressed as a particular nucleotide sequence, into a protein, expressed as an amino acid sequence, depends on the genetic code. In this code, sequences of three nucleotides (termed a codon) represent one of the 20 amino acids that compose the protein molecule. Because there are 64 codons which can be constructed for the four different bases, and only 20 different amino acids that are coded for, several amino acids may be coded for by more than one codon. There are also three codons, called stop codons, that terminate the transfer of information. Furthermore, although all cells contain the same complement of genes, certain cells (for example, the neurons) have specialized genes that encode specific proteins for the synthesis of specific transmitters. The expression of such genes is under the control of regulatory proteins called transcription factors which control the transcription of mRNAs from the genes they control. 

The genetic code is a set of words or codons that are read as the nucleotide sequence of the mRNA and translated into the protein sequence it specifies. 

On each of the tRNA molecules, one of the single-stranded loops contains a trinucleotide sequence that is complementary to the triplet codon sequence used in the genetic code to specify a particular amino acid. This loop on the tRNA is known as the anticodon loop, and it is used to match the tRNA with a complementary codon on the mRNA. In this way the amino acids carried by the tRNA molecules can be aligned in the proper sequence for polymerization into a functional protein. 

The last stage of peptide chain synthesis is termination. The genetic code specifies three stop codons, indicating the termination of a coding sequence. When the ribosome encounters one of these stop codons on the mRNA, certain release factors... 

In the next step, translation, the sequence of nucleotides in the newly synthesized mRNA strand is used to determine the sequence of amino acids in the protein to be synthesized. This is done by way of a genetic code, which was fully deciphered by 1966 and is shown in Figure 13.34. According to the genetic code, it takes three mRNA nucleotides—each three-nucleotide unit is called a codon—to code for a single amino acid. The mRNA nucleotide sequence AGU, for example, codes for the amino acid serine, and AAG codes for lysine. (Note from Figure 13.34 that more than one codon can call for the same amino acid.) A few codons, such as AUG and UGA, are the signals for protein synthesis to either start or stop. 

It is immediately obvious that there are three ways of reading the genetic code in mRNA depending upon which nucleotide is used to start each codon. For... 

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