Protein DNA polymerase

The nucleus is not capable of synthesizing proteins. All of the nuclear proteins therefore have to be imported—the histones with which DNA is associated in chromatin, and also the so-called non-histone proteins (DNA polymerases and RNA polymerases, auxiliary and structural proteins, transcription factors, and ribosomal proteins). Ribosomal RNA (rRNA) already associates with proteins in the nucleolus to form ribosome precursors. 

Exonuclease activities, proofreading, and editing. DNA polymerase I not only catalyzes the growth of DNA chains at the 3 end of a primer strand but also, at about a 10-fold slower rate, the hydrolytic removal of nucleotides from the 3 end (31- 5 exonuclease activity). The same enzyme also catalyzes hydrolytic removal of nucleotides from the 5 end of DNA chains. This latter 5 - 3 exonuclease activity, the DNA polymerase activity, and the 3 -5 exonuclease activity all arise from separate active sites in the protein. DNA polymerases II and III do not catalyze... 

Another class of DNA-binding proteins are the polymerases. These have a nonspecific interaction with DNA because the same protein acts on all DNA sequences. DNA polymerase performs the dual function of DNA repHcation, in which nucleotides are added to a growing strand of DNA, and acts as a nuclease to remove mismatched nucleotides. The domain that performs the nuclease activity has an a/P-stmcture, a deep cleft that can accommodate double-stranded DNA, and a positively charged surface complementary to the phosphate groups of DNA. The smaller domain contains the exonuclease active site at a smaller cleft on the surface which can accommodate a single nucleotide. 

The sharp bend of DNA at the TATA box induced by TBP binding is favorable for the formation of the complete DNA control module in particular, for the interaction of specific transcription factors with TFIID. Since these factors may bind to DNA several hundred base pairs away from the TATA box, and at the same time may interact with TBP through one or several TAFs, there must be several protein-DNA interactions within this module that distort the regular B-DNA structure (see Figure 9.2). The DNA bend caused by the binding of TBP to the TATA box is one important step to bring activators near to the site of action of RNA polymerase. 

Examples (a) nucleosome K Huger, AW Mader, RK Richmond, DF Sargent, TJ Richmond. Nature 389 251-260, 1997 (b) DNA polymerases CA Brautigam, TA Steitz. Curr. Opin. Struct. Biol. 8 54-63, 1998 (c) single-stranded binding protein Y Shamoo, AM Friedman, MR Parsons, WH Konigsberg, TA Steitz. Nature 376 362-366, 1995 (d) restriction endonucleases RA Kovall, BW Matthews. Curr. Opin. Chem. Biol. 3 578-583, 1999 (e) DNA lig-ase S Shuman. Structure 4 653-656, 1996 (f) DNA helicases MC Hall, SW Matson. Mol. Microbiol. 34 867-877, 1999 (g) zinc-finger proteins Y Choo, JW Schwabe. Nat. Struct. Biol. 5 253-255, 1998. 

Each strand of the double helix is replicated simultaneously but by somewhat different mechanisms. A complex of proteins, including DNA polymerase, replicates the leading strand continuously in the 5 to 3 direction. The lagging strand is replicated discon-tinuously, in short pieces of 150-250 nucleotides, in the 3 to 5 direction. 

Sequences farther upstream from the start site determine how frequently the transcription event occurs. Mutations in these regions reduce the frequency of transcriptional starts tenfold to twentyfold. Typical of these DNA elements are the GC and CAAT boxes, so named because of the DNA sequences involved. As illustrated in Figure 37—7, each of these boxes binds a protein, Spl in the case of the GC box and CTF (or C/EPB,NF1,NFY) by the CAAT box both bind through their distinct DNA binding domains (DBDs). The frequency of transcription initiation is a consequence of these protein-DNA interactions and complex interactions between particular domains of the transcription factors (distinct from the DBD domains—so-called activation domains ADs) of these proteins and the rest of the transcription machinery (RNA polymerase II and the basal factors TFIIA, B, D, E, F). (See... 

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.

Detailed analysis of the lambda repressor led to the important concept that transcription regulatory proteins have several functional domains. For example, lambda repressor binds to DNA with high affinity. Repressor monomers form dimers, dimers interact with each other, and repressor interacts with RNA polymerase. The protein-DNA interface and the three protein-protein interfaces all involve separate and distinct domains of the repressor molecule. As will be noted below (see Figure 39—17), this is a characteristic shared by most (perhaps all) molecules that regulate transcription. 

The ability of natural products to inhibition of topoisomerase and precipitate apoptosis mentioned in this chapter are two abilities among several others, of which inhibition of microtubule formation, inhibition of DNA polymerase, protein kinases, protein phosphatase and aromatase, and the use of cytokines, interleukins, and tumor necrosis factor and yet uncovered cellular targets. 

DNA has two broad functions replication and expression. First, DNA must be able to replicate itself so that the information coded into its primary structure is transmitted faithfully to progeny cells. Second, this information must be expressed in some useful way. The method for this expression is through RNA intermediaries, which in turn act as templates for the synthesis of every protein in the body. The relationships of DNA to RNA and to protein are often expressed in a graphic syllogism called the central dogma. The concept was proposed by Crick in 1958 and was revised in 1970 to accommodate the discovery of the RNA-dependent DNA polymerase. Crick s original theory suggested that the flow of information was always from RNA to protein and could not be reversed, yet it allowed for the possibility of DNA synthesis from RNA. 

Alley, S.C., Ishmael, F.T., Jones, A.D., and Benkovic, S.J. (2000) Mapping protein-protein interactions in the bacteriophage T4 DNA polymerase holoenzyme using a novel trifunctional photo-cross-linking and affinity reagent./. Am. Chem. Soc. 122, 6126-6127. 

There s not just one DNA polymerase there s a whole army. DNA replication actually occurs in large complexes containing many proteins and sometimes many polymerases. In eukaryotic cells we have to replicate both mitochondrial and nuclear DNA, and there are specific DNA polymerases for each. In addition to DNA replication, you have to make new DNA when you repair. Consequently, the function may be specialized for repair or replication. There can also be specialization for making the leading or lagging strand. Some of the activities of DNA polymerases from eukaryotes and prokaryotes are shown in the table on the next page. 

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