Genetic code Genetics

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... 

GENESEQ GENESIS Gene therapy Genetic code Genetic colonization Genetic engineering... 

A potentially general method of identifying a probe is, first, to purify a protein of interest by chromatography (qv) or electrophoresis. Then a partial amino acid sequence of the protein is deterrnined chemically (see Amino acids). The amino acid sequence is used to predict likely short DNA sequences which direct the synthesis of the protein sequence. Because the genetic code uses redundant codons to direct the synthesis of some amino acids, the predicted probe is unlikely to be unique. The least redundant sequence of 25—30 nucleotides is synthesized chemically as a mixture. The mixed probe is used to screen the Hbrary and the identified clones further screened, either with another probe reverse-translated from the known amino acid sequence or by directly sequencing the clones. Whereas not all recombinant clones encode the protein of interest, reiterative screening allows identification of the correct DNA recombinant. 

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. 

RNA structures, compared to the helical motifs that dominate DNA, are quite diverse, assuming various loop conformations in addition to helical structures. This diversity allows RNA molecules to assume a wide variety of tertiary structures with many biological functions beyond the storage and propagation of the genetic code. Examples include transfer RNA, which is involved in the translation of mRNA into proteins, the RNA components of ribosomes, the translation machinery, and catalytic RNA molecules. In addition, it is now known that secondary and tertiary elements of mRNA can act to regulate the translation of its own primary sequence. Such diversity makes RNA a prime area for the study of structure-function relationships to which computational approaches can make a significant contribution. 

All of the 20 amino acids have in common a central carbon atom (Co) to which are attached a hydrogen atom, an amino group (NH2), and a carboxyl group (COOH) (Figure 1.2a). What distinguishes one amino acid from another is the side chain attached to the Ca through its fourth valence. There are 20 different side chains specified by the genetic code others occur, in rare cases, as" the products of enzymatic modifications after translation. 

The genetic code specifies 20 different amino acid side chains... 

If enzymes responsible for DNA repair are unable to remove the DNA adduct, or if an error takes place in the repair, then the error in the genetic code remains when the cell divides. Thus, cellular proliferation is also required, in addition to a mutation, for there to be a permanent effect of a chemical compound. Accumulation of genetic errors, i.e., mutations, has been suspected to be an important factor in chemical carcinogenesis. ... 

In one of the early experiments designed to elucidate the genetic code, Marshall Nirenberg of the U.S. National Institutes of Health (Nobel Prize in physiology or medicine, 1968) prepared a synthetic mRNA in which all the bases were uracil. He added this poly(U) to a cell-free system containing all the necessary materials for protein biosynthesis. A polymer of a single amino acid was obtained. What amino acid was polymerized ... 

What is the amino acid sequence of the fusion protein Where is the junction between /3-galactosidase and the sequence encoded by the insert (Consult the genetic code table on the inside front cover to decipher the amino acid sequence.)... 

The two strands which make up DNA are held together by hydrogen bonds between complementary pairs of bases adenine paired with thymine and guanine paired with cytosine. The integrity of the genetic code (and of life as we know it) depends on error-free transmission of base-pairing information. 

Atomic determinants for aminoacy lation of RNA minihelices and their relationship to genetic code 99ACR368. 

H. Gobind Khorana (medicine) interpretations of the genetic code and its function in protein synthesis... 

The following molecules are bases that are part of the nucleic acids involved in the genetic code. Identify (a) the hybridization of each C and N atom, (b) the number of a- and ir-bonds, and (c) the number of lone pairs of electrons in the molecule. 

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