Genetic material, nucleic acids

Viruses essentially consist of genetic material (nucleic acids, green strands in (A) and a capsular envelope made up of proteins (blue hexagons), often with a coat (gray ring) of a phospholipid (PL) bilayer with embedded proteins (small blue bars). They lack a metabolic system but depend on the infected cell for their growth and replication. Targeted therapeutic suppression of viral replication requires selective inhibition of those metabolic processes that specifically serve viral replication in infected cells. 

Nitrogen is a component of amino acids that make up proteins chlorophyll (the molecule that captures the sun s energy) enzymes and the genetic material, nucleic acids. Therefore, this nutrient is required in large amounts by all plants and forms one of three primary nutrients. Although nitrogen is available in abundance... 

VVThen a beam of ionizing radiation hits living cells, important cell functions may be altered or destroyed. In particular, the replication mechanisms of the cell which are associated with their genetic material, deoxyribonucleic acid (DNA), are particularly radiosensitive. In order to appreciate fully the biological implications of this damage, further understanding at the chemical level is needed. For these reasons, we are undertaking a detailed study of the reactions of the primary reactive species in water (e aq,-OH) with nucleic acid derivatives. 

Vimses are one of the smallest biological entities (except viroids and prions) that carry all the iaformation necessary for thek own reproduction. They are unique, differing from procaryotes and eucaryotes ia that they carry only one type of nucleic acid as genetic material, which can be transported by the vims from one cell to another. Vimses are composed of a shell of proteki enclosing a core of nucleic acid, either ribonucleic acid (RNA) or deoxyribonucleic acid (DNA), that codes for vkal reproduction. The outer shell serves as a protective coat to keep the nucleic acid kitact and safe from enzymatic destmction. In addition to thek proteki coat, some vimses contain an outer covering known as an outer envelope. This outer envelope consists of a Hpid or polysaccharide material. 

Nucleic acids are the molecules of the genetic apparatus. They direct protein biosynthesis in the body and are the raw materials of genetic technology (see Genetic engineering). Most often polynucleotides are synthesized microbiologicaHy, or at least enzymatically, but chemical synthesis is possible. 

FIGURE 1.25 The virus life cycle. Viruses are mobile bits of genetic iuformatiou encapsulated in a protein coat. The genetic material can be either DNA or RNA. Once this genetic material gains entry to its host cell, it takes over the host machinery for macromolecular synthesis and subverts it to the synthesis of viral-specific nucleic acids and proteins. These virus components are then assembled into mature virus particles that are released from the cell. Often, this parasitic cycle of virus infection leads to cell death and disease. 

The hypothesis that our biological world built on the DNA-RNA-protein central dogma was preceded by an RNA world in which RNA molecules carried both the genetic information and executed the gene functions (through ribozyme activity) is now widely accepted [130]. However, it is also well recognized that RNA due to its vulnerability to hydrolysis - especially as a result of catalysis by divalent metal ions - would not have been able to evolve in a harsh pre-biotic environment Also the formation of RNA under presumed pre-biotic conditions is extremely inefficient It is not so far-fetched to propose that a peptide nucleic acid-like molecule may have been able to function as a form of pre-biotic genetic material since it... 

Nielsen P.E. Peptide nucleic acid (PNA) A model stmcture for the primordial genetic material. Orig. Life Evolut. Biosphere 1993 23 323-327. 

The nucleic acids were recognized as chemical substances more than 70 years before DNA was found to be responsible for the transmission of inherited characteristics. Later it was suspected that DNA might be the genetic material because of its high concentration in chromosomes and in some viruses. The premise was complicated, however, because the concentration of protein in these structures was... 

Ironically, in the first half of the Twentieth century, molecular biologists rejected nucleic acids as a genetic material, since they seemed entirely too simple, compared to proteins, to play roles in both heredity and development. 

The shift towards viewing nucleic acids as the genetic material begins with the critical paper by Avery et at. (1944). 

Until the 1980s, yields of nucleobases obtained in prebiotic syntheses were very small. Thus, some scientists assumed that in earlier phases of molecular evolution, the nucleic acids used other bases in their information-transmitting substances. Piccirilli et al. (1990) suggested isocytosine and diaminopyridine, while Wachtershauser (1988) suggested that the first genetic material possibly consisted only of purines. However, pyrimidine (about a fifth of the total amount of purines present) had been detected in the Murchison meteorite, so that an effective pyrimidine synthesis should have been possible. 

Replication of Viral Nucleic Acid. In addition to producing molecules for the formation of new capsids, the virus must replicate its nucleic acid to provide genetic material for packaging into the capsids. The way in which this is done might vary. In positive-sense, single-strand RNA viruses, a polymerase translated from viral mRNA produces negative-sense RNA from the positive-sense template which is then repeatedly transcribed into more positive strands. 

The role of DNA in storing and transferring genetic material is dependent on the properties of the four bases. These bases are complementary in that guanine is always associated with cytosine, and adenosine with thymine. Watson and Crick, some 40 years ago, showed that the stability of DNA is due to the double helix structure of the molecule that protects it from major perturbations. Information is ultimately transferred by separating these strands which then act as templates for the synthesis of new nucleic acid molecules. 

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