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DNA/RNA structure

Builds and plots 3D structures. DNA/RNA Builder. Protein Predictor and N.N.Charge both based on neutral network approach. Macintosh. [Pg.232]

In contrast, RNA occurs in multiple copies and various forms (Table 11.2). Cells contain up to eight times as much RNA as DNA. RNA has a number of important biological functions, and on this basis, RNA molecules are categorized into several major types messenger RNA, ribosomal RNA, and transfer RNA. Eukaryotic cells contain an additional type, small nuclear RNA (snRNA). With these basic definitions in mind, let s now briefly consider the chemical and structural nature of DNA and the various RNAs. Chapter 12 elaborates on methods to determine the primary structure of nucleic acids by sequencing methods and discusses the secondary and tertiary structures of DNA and RNA. Part rV, Information Transfer, includes a detailed treatment of the dynamic role of nucleic acids in the molecular biology of the cell. [Pg.338]

Fig. 1 Chemical structures of backbone modifications used in therapeutic nucleic acid analogs. Shown are the unmodified DNA/RNA chemical structures in addition to a selection of first (PS), second (OMe, MOE), and third generation (PNA, LNA, MF) nucleic acid modifications... Fig. 1 Chemical structures of backbone modifications used in therapeutic nucleic acid analogs. Shown are the unmodified DNA/RNA chemical structures in addition to a selection of first (PS), second (OMe, MOE), and third generation (PNA, LNA, MF) nucleic acid modifications...
Figure 37-9. The eukaryotic basal transcription complex. Formation of the basal transcription complex begins when TFIID binds to the TATA box. It directs the assembly of several other components by protein-DNA and protein-protein interactions. The entire complex spans DNA from position -30 to +30 relative to the initiation site (+1, marked by bent arrow). The atomic level, x-ray-derived structures of RNA polymerase II alone and ofTBP bound to TATA promoter DNA in the presence of either TFIIB or TFIIA have all been solved at 3 A resolution. The structure of TFIID complexes have been determined by electron microscopy at 30 A resolution. Thus, the molecular structures of the transcription machinery are beginning to be elucidated. Much of this structural information is consistent with the models presented here. Figure 37-9. The eukaryotic basal transcription complex. Formation of the basal transcription complex begins when TFIID binds to the TATA box. It directs the assembly of several other components by protein-DNA and protein-protein interactions. The entire complex spans DNA from position -30 to +30 relative to the initiation site (+1, marked by bent arrow). The atomic level, x-ray-derived structures of RNA polymerase II alone and ofTBP bound to TATA promoter DNA in the presence of either TFIIB or TFIIA have all been solved at 3 A resolution. The structure of TFIID complexes have been determined by electron microscopy at 30 A resolution. Thus, the molecular structures of the transcription machinery are beginning to be elucidated. Much of this structural information is consistent with the models presented here.
This technique provides an easy and convenient method to evaluate the association of small molecules to various polymorphic forms of nucleic acid structures from the measurement of absorbance changes in the absorption maximum of the hgand, where the nucleic acid has no absorbance. Information about overall DNA/RNA base preference and nature of binding can also... [Pg.167]

Fig. 10 Charge transport is observed in a variety of nucleic acid assemblies over a wide distance regime (3.4-200 A). Shown are examples of nucleic acid structures through which charge transport has been examined a B-form DNA b DNA-RNA hybrids c cross-over junctions and d nucleosome core particles. In all assemblies, the charge transport chemistry is extremely sensitive to the structure of the -stacked nucleic acid bases... Fig. 10 Charge transport is observed in a variety of nucleic acid assemblies over a wide distance regime (3.4-200 A). Shown are examples of nucleic acid structures through which charge transport has been examined a B-form DNA b DNA-RNA hybrids c cross-over junctions and d nucleosome core particles. In all assemblies, the charge transport chemistry is extremely sensitive to the structure of the -stacked nucleic acid bases...
The chromosome structure is visible only during the mitotic portion of the cell cycle. The constituent parts of the chromosomes are nucleoprotein fibers called chromatin. When condensed, chromatin forms a microscop-ically visible chromosome-like structure. The chromosomes are composed of DNA, RNA, and proteins. The relative amounts of the three vary, but chromatin is primarily protein and DNA. [Pg.218]

Mg2+ Glycolytic pathway (enolase) All kinases and NTP reactions" Signalling (transcription factors) DNA/RNA structures Light capture... [Pg.231]

Ribonucleic acid (RNA) Molecules including messenger RNA, transfer RNA, ribosomal RNA, or small RNA. RNA serves as a template for protein synthesis and other biochemical processes of the cell. The structure of RNA is similar to that of DNA except for the base thymidine being replaced by uracil. [Pg.537]

Other zinc solutions, free of formaldehyde, have been proposed.29 31 All of these simple buffered salt solutions preserve immunoreactivity well and are suitable for DNA, RNA, and proteomics research. Judging by published photomicrographs of hematoxylin and eosin-stained specimens, cytological detail is inferior to that achieved with standard formalin. Nuclei are condensed to the point where many lack chromatin patterns.3132 Such zinc salt solutions may be good for specialized purposes but are best used as special fixatives. To get good structural detail as well, specimens should be split so that a portion can... [Pg.211]

RNA RNA (ribonucleic acid) is an information encoded strand of nucleotides, similar to DNA, but with a slightly different chemical structure. In RNA, the letter U (uracil) is substituted for T in the genetic code. RNA delivers DNA s genetic message to the cytoplasm of a cell where proteins are made. [Pg.499]

The general types of protein-protein interactions that occur in cells include receptor-ligand, enzyme-substrate, multimeric complex formations, structural scaffolds, and chaperones. However, proteins interact with more targets than just other proteins. Protein interactions can include protein-protein or protein-peptide, protein-DNA/RNA or protein-nucleic acid, protein-glycan or protein-carbohydrate, protein-lipid or protein-membrane, and protein-small molecule or protein-ligand. It is likely that every molecule within a cell has some kind of specific interaction with a protein. [Pg.1003]

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See also in sourсe #XX -- [ Pg.192 ]



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