Selective cleavage of human DNA: RecA-assisted restriction endonuclease (RARE) cleavage

Current methods for sequence-specific cleavage of large segments of DNA are severely limited because of the paucity of possible cleavage sites. A method is described whereby any Eco RI site can be targeted for specific cleavage. The technique is based on the ability of RecA protein from Escherichia coli to pair an oligonucleotide to its homologous sequence in duplex DNA and to form a three-stranded complex. This complex is protected from Eco RI methylase; after methylation and RecA protein removal, Eco RI restriction enzyme cleavage was limited to the site previously protected from methylation. When pairs of oligonucleotides are used, a specific fragment can be cleaved out of genomes. The method was tested on lambda phage, Escherichia coli, and human DNA. Fragments exceeding 500 kilobases in length and yields exceeding 80 percent could be obtained.     

Sequence-specific molecular lithography on single DNA molecules

Recent advances in the realization of individual molecular-scale electronic devices emphasize the need for novel tools and concepts capable of assembling such devices into large-scale functional circuits. We demonstrated sequence-specific molecular lithography on substrate DNA molecules by harnessing homologous recombination by RecA protein. In a sequence-specific manner, we patterned the coating of DNA with metal, localized labeled molecular objects and grew metal islands on specific sites along the DNA substrate, and generated molecularly accurate stable DNA junctions for patterning the DNA substrate connectivity. In our molecular lithography, the information encoded in the DNA molecules replaces the masks used in conventional microelectronics, and the RecA protein serves as the resist. The molecular lithography works with high resolution over a broad range of length scales from nanometers to many micrometers.     

耐辐射异常球菌DNA损伤修复重要功能蛋白的研究进展

耐辐射异常球菌(DR)具有对致死剂量的电离辐射极端的抗性,但对其超强辐射抗性的分子机制仍缺乏深入了解。耐辐射异常球菌基因组分析显示其拥有许多与修复相关的基因或蛋白,转录组学和蛋白组学分析等研究表明该菌能通过复杂的代谢途径控制的网络系统有效地调整并修复DNA。近年来已分析和鉴定了许多与DNA损伤修复,特别是辐射诱导的DNA双链断裂修复相关的蛋白,这些功能蛋白的研究有助于我们加深对其极端抗性机理的认识。主要针对DR双链断裂修复系统中重要功能蛋白的研究进展进行了概述,以期为DNA修复机理的基础研究及应用研究奠定基础。     

Single-Stranded DNA Binding Protein Encoded by the virE Locus of Agrobacterium tumefaciens

The transfer process of T (transfer)-DNA of Agrobacterium tumefaciens is activated after the induction of the expression of the Ti plasmid virulence (vir) loci by plant signal molecules such as acetosyringone. The vir gene products then act to generate a free transferable single-stranded copy of the T-DNA, designated the T-strand. Although some vir proteins are responsible for the synthesis of the T-strand, others may mediate T-strand transfer to plant cells as part of a DNA-protein complex. Here, a novel 69-kilodalton vir-specific single-stranded DNA binding protein is identified in Agrobacterium harboring a nopaline-type Ti plasmid. This protein binds single-stranded but not double-stranded DNA regardless of nucleotide sequence composition. The molecular size of the vir-specific single-stranded DNA binding protein and its relative abundance in acetosyringone-induced Agrobacterium suggested that it might be the product of the virE locus; molecular cloning and expression of the virE region in Escherichia coli confirmed this prediction.     

Human immunodeficiency virus may encode a novel protein on the genomic DNA plus strand

The genome of the human immunodeficiency virus (HIV) is known to contain eight open reading frames (ORFs) on the minus strand of the double-stranded DNA replicative intermediate. Data presented here indicate that the DNA plus strand of HIV contains a previously unidentified ORF in a region complementary to the envelope gene sequence. This ORF could encode a protein of approximately 190 amino acid residues with a relative molecular mass of 20 kilodaltons if translation began from the first initiation codon. The predicted protein is highly hydrophobic and thus could be membrane associated. It is possible, therefore, that the HIV genome encodes a protein on antisense messenger RNA.     

Three-dimensional structure of the Tn5 synaptic complex transposition intermediate

Genomic evolution has been profoundly influenced by DNA transposition, a process whereby defined DNA segments move freely about the genome. Transposition is mediated by transposases, and similar events are catalyzed by retroviral integrases such as human immunodeficiency virus-1 (HIV-1) integrase. Understanding how these proteins interact with DNA is central to understanding the molecular basis of transposition. We report the three-dimensional structure of prokaryotic Tn5 transposase complexed with Tn5 transposon end DNA determined to 2.3 angstrom resolution. The molecular assembly is dimeric, where each double-stranded DNA molecule is bound by both protein subunits, orienting the transposon ends into the active sites. This structure provides a molecular framework for understanding many aspects of transposition, including the binding of transposon end DNA by one subunit and cleavage by a second, cleavage of two strands of DNA by a single active site via a hairpin intermediate, and strand transfer into target DNA.     

DNA damage-induced replication fork regression and processing in Escherichia coli

DNA lesions that block replication are a primary cause of rearrangements, mutations, and lethality in all cells. After ultraviolet (UV)-induced DNA damage in Escherichia coli, replication recovery requires RecA and several other recF pathway proteins. To characterize the mechanism by which lesion-blocked replication forks recover, we used two-dimensional agarose gel electrophoresis to show that replication-blocking DNA lesions induce a transient reversal of the replication fork in vivo. The reversed replication fork intermediate is stabilized by RecA and RecF and is degraded by the RecQ-RecJ helicase-nuclease when these proteins are absent. We propose that fork regression allows repair enzymes to gain access to the replication-blocking lesion, allowing processive replication to resume once the blocking lesion is removed.     

Topologically linked protein rings in the bacteriophage HK97 capsid

The crystal structure of the double-stranded DNA bacteriophage HK97 mature empty capsid was determined at 3.6 angstrom resolution. The 660 angstrom diameter icosahedral particle contains 420 subunits with a new fold. The final capsid maturation step is an autocatalytic reaction that creates 420 isopeptide bonds between proteins. Each subunit is joined to two of its neighbors by ligation of the side-chain lysine 169 to asparagine 356. This generates 12 pentameric and 60 hexameric rings of covalently joined subunits that loop through each other, creating protein chainmail: topologically linked protein catenanes arranged with icosahedral symmetry. Catenanes have not been previously observed in proteins and provide a stabilization mechanism for the very thin HK97 capsid.     

Parallel association of Fos and Jun leucine zippers juxtaposes DNA binding domains

The protein products of the fos and jun proto-oncogenes form a heterodimeric complex that participates in a stable high affinity interaction with DNA elements containing AP-1 binding sites. The effects of deletions and point mutations in Fos and Jun on protein complex formation and DNA binding have been examined. The data suggest that Fos and Jun dimerize via a parallel interaction of helical domains containing a heptad repeat of leucine residues (the leucine zipper). Dimerization is required for DNA binding and results in the appropriate juxtaposition of basic amino acid regions from Fos and Jun, both of which are required for association with DNA.     

Expression of mitogen-activated protein kinase double-stranded RNA in cucumber has no apparent effect on the diversity of rhizosphere archaea

The expression of mitogen-activated protein kinase(mapk) double-stranded RNA in cucumber is effective in controlling infestations of the root-knot nematode Meloidogyne incognita. However,little is known about the ecological effects of transgenic plants. Here,we analyzed the diversity of 16 S r DNA genes derived from the rhizosphere archaea of transgenic cucumber plants as an indicator of ecological change. A total of 17 and 18 operational taxonomic units were detected in the rhizospheres of non-transgenic cucumber and mapk ds RNA-expressing plants,respectively. No significant difference was observed between the two groups according to Shannon and Simpson indices. In soil samples of the two rhizospheres,the dominant group was Crenarchaeota at the phylum level,with Staphylothermus,Methanococcus,Pyrodictium and Sulfolobus the abundant taxa at the genus level. These results suggest that expressing mapk double-stranded(ds) RNA in cucumber has no apparent effect on the diversity of rhizosphere archaea,and provide powerful evidence for the ecological safety of transgenic cucumber expressing mapk ds RNA.     

Fission yeast Pot1-Tpp1 protects telomeres and regulates telomere length

Telomeres are specialized chromatin structures that protect chromosomal ends. Protection of telomeres 1 (Pot1) binds to the telomeric G-rich overhang, thereby protecting telomeres and regulating telomerase. Mammalian POT1 and TPP1 interact and constitute part of the six-protein shelterin complex. Here we report that Tpz1, the TPP1 homolog in fission yeast, forms a complex with Pot1. Tpz1 binds to Ccq1 and the previously undiscovered protein Poz1 (Pot1-associated in Schizosaccharomyces pombe), which protect telomeres redundantly and regulate telomerase in positive and negative manners, respectively. Thus, the Pot1-Tpz1 complex accomplishes its functions by recruiting effector molecules Ccq1 and Poz1. Moreover, Poz1 bridges Pot1-Tpz1 and Taz1-Rap1, thereby connecting the single-stranded and double-stranded telomeric DNA regions. Such molecular architectures are similar to those of mammalian shelterin, indicating that the overall DNA-protein architecture is conserved across evolution.     

Viroid-induced phosphorylation of a host protein related to a dsRNA-dependent protein kinase

Viroids are very small, unencapsidated RNAs that replicate and induce severe disease in plants without encoding for any proteins. The mechanisms by which the viroid RNA regulates these events and interacts with host factors are unknown. An Mr 68,000 host-encoded protein has been identified that is differentially phosphorylated in extracts from viroid-infected and mock-inoculated tissues. This phosphoprotein is immunologically related to a double-stranded (ds) RNA-dependent protein kinase from virus-infected, interferon-treated human cells. Further, nucleotide photoaffinity labeling indicates that the protein has an ATP binding site. This protein is similar to dsRNA-dependent protein kinases implicated in mammalian systems in the regulation of protein synthesis and virus replication.     

Transition from B to Z DNA: contribution of internal fluctuations to the configurational entropy difference

The internal motions of the double-stranded DNA oligomer (dCdG)3 (dC, deoxycytidylate; dG, deoxyguanylate) in the B and Z forms have been calculated in the harmonic approximation. A complete vibrational analysis has been made, and the resulting normal mode frequencies have been used to evaluate the vibrational entropy of B and Z DNA. The greater flexibility of the B DNA hexamer leads to an entropic stabilization relative to the stiffer Z DNA hexamer of 22 calories per mole per kelvin at 300 K. The calculated value is of the same order as that (21 to 27 calories per mole per kelvin) obtained from nuclear magnetic resonance measurements on the methylated duplexes (m5dCdG)3 and (dCdGm5dCdGdCdG). This result demonstrates the importance of internal motions, which have been neglected in earlier studies of the transition from B to Z DNA, in the stability of different nucleic acid conformers.     

Second cytotoxic pathway of diphtheria toxin suggested by nuclease activity

Diphtheria toxin (DTx) provokes extensive internucleosomal degradation of DNA before cell lysis. The possibility that DNA cleavage stems from direct chromosomal attack by intracellular toxin molecules was tested by in vitro assays for a DTx-associated nuclease activity. DTx incubated with DNA in solution or in a DNA-gel assay showed Ca2+- and Mg2+-stimulated nuclease activity. This activity proved susceptible to inhibition by specific antitoxin and migrated with fragment A of the toxin. Assays in which supercoiled double-stranded DNA was used revealed rapid endonucleolytic attack. Discovery of a DTx-associated nuclease activity lends support to the model that DTx-induced cell lysis is not a simple consequence of protein synthesis inhibition.     

Base sequence and higher-order structure induce the complex excited-state dynamics in DNA

The high photostability of DNA is commonly attributed to efficient radiationless electronic relaxation processes. We used femtosecond time-resolved fluorescence spectroscopy to reveal that the ensuing dynamics are strongly dependent on base sequence and are also affected by higher-order structure. Excited electronic state lifetimes in dG-doped d(A)20 single-stranded DNA and dG.dC-doped d(A)20.d(T)20 double-stranded DNA decrease sharply with the substitution of only a few bases. In duplexes containing d(AGA).d(TCT) or d(AG).d(TC) repeats, deactivation of the fluorescing states occurs on the subpicosecond time scale, but the excited-state lifetimes increase again in extended d(G) runs. The results point at more complex and molecule-specific photodynamics in native DNA than may be evident in simpler model systems.     

Cleaving DNA at any predetermined site with adapter-primers and class-IIS restriction enzymes

A four-component system has been designed that makes it possible to prepare a double-stranded (ds) DNA fragment; one fragment end is predesigned (by the use of a class-IIS restriction enzyme and adapter-primer), and the other end corresponds to any normal restriction cut. The system is composed of the phage M13mp7 single-stranded (ss) target DNA; the Fok I restriction enzyme; an oligodeoxynucleotide adapter-primer, which permits one to introduce Fok I cuts at any specified site in the target DNA; and DNA polymerase, which converts the ss target into a ds form ready for cloning. In this system, the oligodeoxynucleotide adapter-primer serves several purposes. The 5' hairpin ds domain of the adapter-primer contains the Fok I recognition site. Its 3' ss domain selects a complementary site on the target ss DNA, hybridizes with it to form the ds cleavage site, and serves as a primer to convert the ss M13mp7 target to ds DNA.     

A sense of the end

How a cell distinguishes a double-strand break from the end of a chromosome has long fascinated cell biologists. It was thought that the protection of chromosomal ends required either a telomere-specific complex or the looping back of the 3' TG-rich overhang to anneal with a homologous double-stranded repeat. These models must now accommodate the findings that complexes involved in nonhomologous end joining play important roles in normal telomere length maintenance, and that subtelomeric chromatin changes in response to the DNA damage checkpoint. A hypothetical chromatin assembly checkpoint may help to explain why telomeres and the double-strand break repair machinery share essential components.     

MMS19 assembles iron-sulfur proteins required for DNA metabolism and genomic integrity

Instability of the nuclear genome is a hallmark of cancer and aging. MMS19 protein has been linked to maintenance of genomic integrity, but the molecular basis of this connection is unknown. Here, we identify MMS19 as a member of the cytosolic iron-sulfur protein assembly (CIA) machinery. MMS19 functions as part of the CIA targeting complex that specifically interacts with and facilitates iron-sulfur cluster insertion into apoproteins involved in methionine biosynthesis, DNA replication, DNA repair, and telomere maintenance. MMS19 thus serves as an adapter between early-acting CIA components and a subset of cellular iron-sulfur proteins. The function of MMS19 in the maturation of crucial components of DNA metabolism may explain the sensitivity of MMS19 mutants to DNA damage and the presence of extended telomeres.