Question

The dna segments which are formed from rna under the influence of rna dependent dna polymerase enzyme are teed as

Answer 1



Nuclear fraction of Bacillus subtilis as a template for ribonucleic acid synthesis

S Mizuno, HR Whiteley

Journal of bacteriology 95 (4), 1221-1237, 1968

A “nuclear fraction” prepared from Bacillus subtilis was a more efficient template than purified deoxyribonucleic acid for the synthesis of ribonucleic acid by exogenously added ribonucleic acid polymerase isolated from B. subtilis. The initial rate of synthesis with the nuclear fraction was higher and synthesis continued for several hours, yielding an amount of ribonucleic acid greater than the amount of deoxyribonucleic acid used as the template. The product was heterogenous in size, with a large portion exceeding 23S. When purified deoxyribonucleic acid was the template, a more limited synthesis was observed with a predominantly 7S product. However, the ribonucleic acids produced in vitro from these templates were very similar to each other and to in vivo synthesized ribonucleic acid as determined by the competition of ribonucleic acid from whole cells in the annealing of in vitro synthesized ribonucleic acids to deoxyribonucleic acid. Treatment of the nuclear fraction with heat (60 C for 15 min) or trypsin reduced the capacity of the nuclear fraction to synthesize ribonucleic acid to the level observed with purified deoxyribonucleic acid.

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Asymmetrical DNA replication promotes evolution: disparity theory of evolution

Mitsuru Furusawa, Hirofumi Doi

Genetica 102, 333-347, 1998

Heredity is guaranteed by faithful DNA replication whereas evolution depends upon errors accompanying DNA replication. This contradiction existing between heredity and evolution cannot be resolved in an individual organism, but only in terms of a population, in that a delicate balance exists between wild type and variants in a population which is necessary for the survival of the species. Namely, there seems to be a key in the mechanism of DNA replication to solve some problems of evolution. DNA is replicated semiconservatively using the leading and discontinuous lagging strands. According to our ‘disparity theory of evolution’, the existence of a sufficient fidelity difference between the leading and lagging strands is advantageous in terms of evolution, because the diversity of genotypes is enlarged but genotypes that have occurred in the past are guaranteed. In theory, by artificially increasing the fidelity difference between the leading and lagging strand (‘disparity mutator’), evolution is accelerated while avoiding the extinction of the population. Using a disparity mutator, we should be able to improve living things, including multicellular organisms, within constrained conditions. A double-stranded genetic algorithm, which mimics the structure and replication manner of DNA, is promising for solving optimization problems.