DNA依赖蛋白激酶研究进展

DNA依赖蛋白激酶由Ku异二聚体和DNA-PKcs组成,结合Ku蛋白后,DNA-PK激酶活性激活,DNA依赖蛋白激酶具有多功能性,参与DNA修复、基因重组以及复制、转录等多种细胞学过程.     

The J gene of bacteriophage phi X174: in vitro analysis of J protein function.

The J protein of phi X174 is a small, highly basic protein and is a component of the phage capsid. We have investigated the role of J protein during single-stranded viral DNA synthesis and phage morphogenesis by using an in vitro system composed of purified viral and host components (Aoyama et al., Proc. Natl. Acad. Sci. U.S.A. 80:4195-4199, 1983). The characterization of the products made in the presence and absence of J protein shows that J protein is not required for viral DNA synthesis, but is required for the packaging of DNA into infectious phage. The ability of J protein to bind to double-stranded DNA as well as single-stranded DNA and other interactions with DNA suggest a model in which J protein binds to double-stranded, replicative form DNA and enters the phage prohead by remaining bound to viral DNA as it is encapsidated.     

Development of a protein microarray using sequence-specific DNA binding domain on DNA chip surface

A protein microarray based on DNA microarray platform was developed to identify protein-protein interactions in vitro. The conventional DNA chip surface by 156-bp PCR product was prepared for a substrate of protein microarray. High-affinity sequence-specific DNA binding domain, GAL4 DNA binding domain, was introduced to the protein microarray as fusion partner of a target model protein, enhanced green fluorescent protein. The target protein was oriented immobilized directly on the DNA chip surface. Finally, monoclonal antibody of the target protein was used to identify the immobilized protein on the surface. This study shows that the conventional DNA chip can be used to make a protein microarray directly, and this novel protein microarray can be applicable as a tool for identifying protein-protein interactions.     

The A* protein of phi X174 is an inhibitor of DNA replication

Extracts prepared from phi X174 infected E. coli cells inhibited in vitro RF replication The inhibition was dependent upon the presence of A* protein in the reaction and served as an assay to highly purify the A* protein. Purified A* protein bound tightly to duplex DNA as well as single-stranded DNA. The binding of the A* protein to duplex DNA inhibited (I) its single-stranded DNA specific endonucleolytic activity; (II) in vitro synthesis of viral (+) single stranded DNA on an A-RFII DNA complex template; (III) ATP hydrolysis by rep protein and unwinding of the strands of RF DNA. We propose that this inhibitory activity is responsible in vivo for the shut off of E. coli chromosome replication during phi X174 infection, and has a role in the transition from semiconservative RF DNA replication to single-stranded DNA synthesis in the life cycle of phi X174.     

Interaction of RecA protein with pBR322 DNA modified by N-hydroxy-2-acetylaminofluorene and 4-hydroxyaminoquinoline 1-oxide.

Interaction of RecA protein of Escherichia coli with pBR322 DNA modified by N-hydroxy-2-acetylaminofluorene (N-OH-AAF) and 4-hydroxyaminoquinoline 1-oxide (4HAQO) was investigated. RecA protein bound more efficiently to modified DNA than to unmodified DNA as judged by filter-binding and gel electrophoresis assay. The binding of RecA protein with modified DNA resulted in the stimulation of ATPase activity and the activation for RecA protein to stimulate the repressor cleavage. These abilities of RecA protein were increased proportionally to the number of adducts in the plasmid DNA (0-5 adducts). Apurinic and alkylated DNA did not activate RecA protein. We suggest that modification of DNA by N-OH-AAF and 4HAQO provides binding sites for RecA protein and may act as an activation signal for SOS response.     

Inhibition of RecA protein function by the RdgC protein from Escherichia coli

The Escherichia coli RdgC protein is a potential negative regulator of RecA function. RdgC inhibits RecA protein-promoted DNA strand exchange, ATPase activity, and RecA-dependent LexA cleavage. The primary mechanism of RdgC inhibition appears to involve a simple competition for DNA binding sites, especially on duplex DNA. The capacity of RecA to compete with RdgC is improved by the DinI protein. RdgC protein can inhibit DNA strand exchange catalyzed by RecA nucleoprotein filaments formed on single-stranded DNA by binding to the homologous duplex DNA and thereby blocking access to that DNA by the RecA nucleoprotein filaments. RdgC protein binds to single-stranded and double-stranded DNA, and the protein can be visualized on DNA using electron microscopy. RdgC protein exists in solution as a mixture of oligomeric states in equilibrium, most likely as monomers, dimers, and tetramers. This concentration-dependent change of state appears to affect its mode of binding to DNA and its capacity to inhibit RecA. The various species differ in their capacity to inhibit RecA function.     

Activities of the feline immunodeficiency virus integrase protein produced in Escherichia coli.

Retroviral DNA integration requires the activity of at least one viral protein, the integrase (IN) protein. We cloned and expressed the integrase gene of feline immunodeficiency virus (FIV) in Escherichia coli as a fusion to the malE gene and purified the IN fusion protein by affinity chromatography. The protein is active in site-specific cleavage of the viral DNA ends, DNA strand transfer, and disintegration. FIV IN has a relaxed viral DNA substrate requirement: it cleaves and integrates FIV DNA termini, human immunodeficiency virus DNA ends, and Moloney murine leukemia virus DNA ends with high efficiencies. In the cleavage reaction, IN exposes a specific phosphodiester bond near the viral DNA end to nucleophilic attack. In vitro, either H2O, glycerol, or the 3' OH group of the viral DNA terminus can serve as nucleophile in this reaction. We found that FIV IN preferentially uses the 3' OH ends of the viral DNA as nucleophile, whereas HIV IN protein preferentially uses H2O and glycerol as nucleophiles.     

Visualization of recA protein and its association with DNA: a priming effect of single-strand-binding protein

A stoichiometric interaction of RecA protein with single-stranded DNA promotes homologous pairing of the single strand with duplex DNA and subsequent polar formation of a heteroduplex joint. Escherichia coli single-strand-binding (SSB) protein augments these reactions. Electron microscopic observations suggest structural bases for these interactions. Without triphosphates or DNA, RecA protein forms short linear filaments. With added circular single-stranded DNA, it forms extended circular filaments as well as collapsed and aggregated complexes of protein and DNA. The extended circular filaments are stiff and regular in appearance, contrasting with the convoluted structure formed by SSB protein and single-stranded DNA. Together, these two proteins form mixed filaments, which mostly resemble the extended structures containing RecA protein; moreover, SSB protein accelerates formation of extended filaments more than 50-fold, increasing the yield of these structures at the expense of heterogeneous aggregates. Other observations further define the interactions of RecA protein with partially single-stranded DNA, and the effects of ATP gamma S on the tendency of RecA protein to form polymeric structures even in the absence of DNA.     

Stimulation by Cyclic Adenosine Monophosphate of Plasmid Deoxyribonucleic Acid Replication and Catabolite Repression of the Plasmid Deoxyribonucleic Acid-Protein Relaxation Complex

Colicinogenic factors ColE1 and ColE2 are bacterial plasmids that exist in Escherichia coli as supercoiled deoxyribonucleic acid (DNA) and as strand-specific, relaxation complexes of supercoiled DNA and protein. Newly replicated ColE1 DNA becomes complexed with protein after the replication event. This association of DNA and protein can take place under conditions in which DNA or protein synthesis is arrested. The addition of cyclic adenosine monophosphate (c-AMP) to normal cells growing in glucose medium results in a six- to tenfold stimulation in the rate of synthesis of the protein component(s) of the complex and a three- to fivefold stimulation in the rate of ColE1 DNA replication. Employing mutants deficient in catabolite gene activator protein or adenylate cyclase, it was shown that synthesis of both the plasmid-determined protein colicin E1 and the protein component(s) of the ColE1 relaxation complex is mediated through the c-AMP-catabolite gene activator protein system. Addition of c-AMP to ColE2-containing cells results in the stimulation of synthesis of ColE2 DNA and relaxation protein(s) as well as in the production of a protein component of the ColE2 relaxation complex that renders it sensitive to induced relaxation by heat treatment. In the case of ColE2, synthesis of the relaxation protein(s) is not dependent upon catabolite gene activator protein.     

Transfection of a DNA/protein complex into nuclei of mammalian cells using polyoma capsids and electroporation

We used empty capsids ofpolyoma virus to transfer DNA fragments and DNA/protein complexes into human cells. We encapsulated labeled and unlabeled single stranded DNA fragments by viral capsids. A complex of DNA with a DNA binding protein, recA, will also be taken up by the capsids, whereas the free protein is not incorporated. We further compared this gentle biological method of DNA transfection with a well-established physical method, electroporation. Electroporation also allows the transfer of DNA as well as protein into cells, although there is no proof that a DNA/protein complex can survive the procedure functionally. Whereas the viability of capsid transfected cells is unaffected (100%), electroporation reduces the viability to 90–95%. On the other hand, the amount of DNA found in the nucleus of electroporated cells is higher than for cells treated with loaded viral capsids.     

Rep protein as a helicase in an active, isolatable replication fork of duplex phi X174 DNA

Rep protein as a helicase combines its actions with those of gene A protein and single-stranded DNA binding protein to separate the strands of phi X174 duplex DNA and thereby can generate and advance a replication fork (Scott, J. F., Eisenberg, S., Bertsch, L. L., and Kornberg, A. (1977) Proc. Natl. Acad. Sci. U. S. A. 74, 193-197). Tritium-labeled rep protein is bound in an active gene A protein. phi X174 closed circular duplex supercoiled DNA complex in a 1:1 ratio. Catalytic separation of the strands of the duplex by rep protein, as measured by incorporation of tritium-labeled single-stranded DNA binding protein, requires ATP at a Km value of 8 microM, and hydrolyzes two molecules of ATP for every base pair melted. When coupled to replication in the synthesis of single-strand viral circles, a "looped" rolling-circle intermediate is formed that can be isolated in an active form containing gene A protein, rep protein, single-stranded DNA binding protein, and DNA polymerase III holoenzyme. Unlike the binding of rep protein to single-stranded DNA, where its ATPase activity is distributive, binding to the replicating fork is not affected by ATP, further suggesting a processive action linked to gene A protein. Limited tryptic hydrolysis of rep protein abolishes its replicative activity without affecting significantly its binding of ATP and its ATPase action on single-stranded DNA. These results augment earlier findings by describing the larger role of rep proteins as a helicase, linked in a complex ith other proteins, at the replication fork of a duplex DNA.     

Functional rules for lac repressor�Coperator associations and implications for protein�CDNA interactions

The Lac repressor has been used as a tool to understand protein–DNA recognition for many years. Recent experiments have demonstrated the ability of the Lac repressor to control gene expression in various eukaryotic systems, making the quest for an arsenal of protein–DNA binding partners desirable for potential therapeutic applications. Here, we present the results of the most exhaustive screen of Lac repressor‐DNA binding partners to date, resulting in the elucidation of functional rules for Lac–DNA binding. Even within the confines of a single protein–DNA scaffold, modes of binding of different protein–DNA partners are sufficiently diverse so as to prevent elucidation of generalized rules for recognition for a single protein, much less an entire protein family.     

A single-stranded DNA-binding protein of bacteriophage T7 defective in DNA annealing

The annealing of complementary strands of DNA is a vital step during the process of DNA replication, recombination, and repair. In bacteriophage T7-infected cells, the product of viral gene 2.5, a single-stranded DNA-binding protein, performs this function. We have identified a single amino acid residue in gene 2.5 protein, arginine 82, that is critical for its DNA annealing activity. Expression of gene 2.5 harboring this mutation does not complement the growth of a T7 bacteriophage lacking gene 2.5. Purified gene 2.5 protein-R82C binds single-stranded DNA with a greater affinity than the wild-type protein but does not mediate annealing of complementary strands of DNA. A carboxyl-terminal-deleted protein, gene 2.5 protein-Delta26C, binds even more tightly to single-stranded DNA than does gene 2.5 protein-R82C, but it anneals homologous strands of DNA as well as does the wild-type protein. The altered protein forms dimers and interacts with T7 DNA polymerase comparable with the wild-type protein. Gene 2.5 protein-R82C condenses single-stranded M13 DNA in a manner similar to wild-type protein when viewed by electron microscopy.     

DNA Binding and Bending Protein-Based DNA Actuator and its Practical Realization

In the life forms, the biomolecules such as DNA and protein are interacting with each other to maintain their life activity. Simultaneously, these biomolecules form DNA–protein complexes; as a result, the life forms can adjust to the external environment and continue its life activities. Therefore, using these characteristics of the DNA recognition ability of proteins, the novel molecular devices can be established. Here, we show the application of DNA binding and bending protein for design of the DNA actuator and its practical realization. The single polypeptide chain integrated host factor 2 (scIHF2), which is a DNA binding and bending protein, was used to bind to and/or bend the specific domains of DNA. Using this protein and designing the sequences of DNA, mechanical-functionalized DNA-based biomolecular device could be fabricated. Using these mechanisms, DNA binding and bending proteins have great potentials for establishing the DNA actuator for nanobiotechnology and nanotechnology applications.     

Purification and characterization of the RecA protein from Streptococcus pneumoniae

Streptococcus pneumoniae is a naturally transformable bacterium that is able to take up single-stranded DNA from its environment and incorporate the exogenous DNA into its genome. This process, known as transformational recombination, is dependent upon the presence of the recA gene, which encodes an ATP-dependent DNA recombinase whose sequence is 60% identical to that of the RecA protein from Escherichia coli. We have developed an overexpression system for the S. pneumoniae RecA protein and have purified the protein to greater than 99% homogeneity. The S. pneumoniae RecA protein has ssDNA-dependent NTP hydrolysis and NTP-dependent DNA strand exchange activities that are generally similar to those of the E. coli RecA protein. In addition to its role as a DNA recombinase, the E. coli RecA protein also acts as a coprotease, which facilitates the cleavage and inactivation of the E. coli LexA repressor during the SOS response to DNA damage. Interestingly, the S. pneumoniae RecA protein is also able to promote the cleavage of the E. coli LexA protein, even though a protein analogous to the LexA protein does not appear to be present in S. pneumoniae.     

Interaction between bacteriophage PM2 protein IV and DNA.

The interaction between DNA and the structural protein IV of bacteriophage PM2 was studied by co-sedimentation, filter binding and electron microscopy. The co-sedimentation data and the sigmoid-shaped filter binding curve were interpreted in terms of co-operative binding. At a given DNA/protein input ratio, some DNA molecules were associated with a large amount of protein IV while others had no detectable protein bound to them. Electron microscopic examination of DNA-protein IV mixtures showed highly condensed DNA molecules alongside uncomplexed native DNA. Dissociation experiments revealed the presence of two types of complexes. Type I dissociated rapidly while type II had a long half-life. Dissociation of complexes obtained with increasing protein/DNA ratios suggested that the type I complex was a precursor of type II complex. Protein IV binds equally well to superhelical, relaxed or linear DNA as well as to single-stranded DNA. These observations lead to a model for the interaction and for the consequent alterations in the DNA structure.     

Direct DNA binding activity of the Fanconi anemia D2 protein

It is known that the Fanconi anemia D2 protein is vital for protecting the genome from DNA damage, but what activities this protein has are unknown. In these experiments we purified full-length Fanconi anemia protein D2 (FANCD2), and we found that FANCD2 bound to DNA with specificity for certain structures: double strand DNA ends and Holliday junctions. Proteins containing patient-derived mutations or artificial variants of the FANCD2 protein were similarly expressed and purified, and each variant bound to the Holliday junction DNA with similar affinity as did the wild-type protein. There was no single discrete domain of FANCD2 protein that bound to DNA, but rather the full-length protein was required for structure-specific DNA binding. This finding of DNA binding is the first biochemical activity identified for this key protein in the Fanconi anemia pathway.     

Protein—nucleic acid interactions in bacteriophage φ29 DNA replication

Abstract: φ29 DNA replication starts at both DNA ends by a protein priming mechanism. The formation of the terminal protein-dAMP initiation complex is directed by the second nucleotide from the 3' end of the template. The transition from protein-primed initiation to normal DNA elongation has been proposed to occur by a sliding-back mechanism that is necessary for maintaining the sequences at the φ29 DNA ends. Structure—function studies have been carried out in the φ29 DNA polymerase. By site-directed mutagenesis of amino acids conserved among distantly related DNA polymerases we have shown that the N-terminal domain of φ29 DNA polymerase contains the 3'–5' exonuclease activity and the strand-displacement capacity, whereas the C-terminal domain contains the synthetic activities (protein-primed initiation and DNA polymerization). Viral protein p6 stimulates the initiation of φ29 DNA replication. The structure of the protein p6—DNA complex has been determined, as well as the main signals at the φ29 DNA ends recognized by protein p6. The DNA binding domain of protein p6 has been studied. The results indicate that an α-helical structure located in the N-terminal region of protein p6 is involved in DNA binding through the minor groove. The φ29 protein p5 is the single-stranded DNA binding (SSB) protein involved in φ29 DNA replication, by binding to the displaced single-stranded DNA (ssDNA) in the replication intermediates. In addition, protein p5 is able to unwind duplex DNA. The properties of the φ29 SSB—ssDNA complex are described. Using the four viral proteins, terminal protein, DNA polymerase, protein p6 and the SSB protein, it was possible to amplify the 19285-bp φ29 DNA molecule by a factor of 4000 after 1 h of incubation at 30°C. The infectivity of the in vitro amplified DNA was identical to that of φ29 DNA obtained from virions.