Nucleic acids characteristics

In 1985, Lyamichev et al. [15] called H-DNA to the intramolecular triplex of sequence PyPuPy in order to indicate the high H+ concentration of the media where this triplex exists. This requires protonation of one cytosine in each base-triplet and the two pyrimidine strands must run antiparallel. These form has undergone much research recently [16, 17], as it is very important to understand what is the role of triplex DNA in the nucleic acid characteristics and biotechnological applications may be of great relevance. 

H. gestii and H. fasciculum have many features in common with the two earlier described heliobacteria (3,4). Absorption spectra, membrane structure, growth requirements and, where known, nucleic acid characteristics, are all very similar. The main differences appear to be morphological. A strong case can therefore be made for classifying all of the known heliobacteria in a single genus. 

Transfer RNA (tRNA) Transfer RNAs are relatively small nucleic acids containing only about 70 nucleotides They get their name because they transfer ammo acids to the ribosome for incorporation into a polypeptide Although 20 ammo acids need to be transferred there are 50-60 tRNAs some of which transfer the same ammo acids Figure 28 11 shows the structure of phenylalanine tRNA (tRNA ) Like all tRNAs it IS composed of a single strand with a characteristic shape that results from the presence of paired bases m some regions and their absence m others... 

The circumstances under which water becomes contaminated are as varied as the ways water is taken internally. It is then conceivable that almost any virus could be transmitted through the water route. The increased use of water for recreational purposes increases the incidence of human contact with bodies of water and, consequently, with waterborne viruses and bacteria. The major waterborne viruses among pathogens, and the most likely candidates for water transmission, are the picornaviruses (from pico, meaning very small, and RNA, referring to the presence of nucleic acid). The characteristics of picornaviruses are shown in Table 1. Among the picornaviruses are the enteroviruses (polioviruses, coxsackieviruses. 

Another property of pyrimidines and purines is their strong absorbance of ultraviolet (UV) light, which is also a consequence of the aromaticity of their heterocyclic ring structures. Figure 11.8 shows characteristic absorption spectra of several of the common bases of nucleic acids—adenine, uracil, cytosine, and guanine—in their nucleotide forms AMP, UMP, CMP, and GMP (see Section 11.4). This property is particularly useful in quantitative and qualitative analysis of nucleotides and nucleic acids. 

Prions—protein particles that lack nucleic acid— cause fatal transmissible spongiform encephalopathies such as Creutzfeldt-Jakob disease, scrapie, and bovine spongiform encephalopathy. Prion diseases involve an altered secondary-tertiary strucmre of a namrally occurring protein, PrPc. When PrPc interacts with its pathologic isoform PrPSc, its conformation is transformed from a predominantly a-helical strucmre to the P-sheet strucmre characteristic of PrPSc. 

PAMAM dendrimers have the following characteristics which are important for their use as transfection reagents. They bind and form complexes with nucleic acids, allow transfer of the DNA-dendrimer complex into the cytoplasm of the... 

We might also note another important difference between animal and bacterial cells. Bacterial cells have rigid cell walls containing peptidoglycan and associated substances. Animal cells, on the other hand, lack cell walls. This difference is important for the way by which the virus genome enters and exits the cell. In bacteria, the protein coat of the virus remains on the outside of the cell and only the nucleic acid enters. In animal viruses, on the other hand, uptake of the virus often occurs by endocytosis (pinocytosis or phagocytosis), processes which are characteristic of animal cells, so that the whole virus particle enters the cell. The separation of animal virus genomes from their protein coats then occurs inside the cell. 

Conventionally, central and special metabolic pathways are distinguished. Central pathways are common to the decomposition and synthesis of major macromolecules. Actually, they are much alike in all representatives of the living world. Special cycles are characteristic of the synthesis and decomposition of individual monomers, macromolecules, cofactors, etc. Special cycles are extremely diversified, especially in the plant kingdom. For this reason, the plant metabolism is conventionally classified into primary and secondary metabolisms. The primary metabolism includes the classical processes of synthesis and deeradation of major macromolecules (proteins, carbohydrates, lipids, nucleic acids, etc.), while the secondary metabolism ensuing from the primary one includes the conversions of special biomolecules (for example, alkaloids, terpenes, etc.) that perform regulatory or other functions, or simply are metabolic end byproducts. 

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... 

Subsequently, similar experiments were done with viral nucleic acids. The pure viral nucleic acid, when added to cells, led to the synthesis of complete virus particles the protein coat was not required. This process is called transfection. More recently, DNA has been used in cell-free extracts to program the synthesis of RNA that functions as the template for the synthesis of proteins characteristic of the DNA... 

Natural viruses provide us with perfect demonstrations of how effective nucleic acid transfer into mammalian cells can proceed. The secret of their efficiency is their dynamic, bioresponsive behavior during delivery, which distinguishes them from classic synthetic nanoparticles. Thus, it has been tempting for us and many research colleagues [69, 92, 164, 188-194] to design nucleic acid nanoparticles with virus-like characteristics ( synthetic viruses ). 

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