Crystal structure of T4 endonuclease VII resolving a Holliday junction

Holliday proposed a four-way DNA junction as an intermediate in homologous recombination, and such Holliday junctions have since been identified as a central component in DNA recombination and repair. Phage T4 endonuclease VII (endo VII) was the first enzyme shown to resolve Holliday junctions into duplex DNAs by introducing symmetrical nicks in equivalent strands. Several Holliday junction resolvases have since been characterized, but an atomic structure of a resolvase complex with a Holliday junction remained elusive. Here we report the crystal structure of an inactive T4 endo VII(N62D) complexed with an immobile four-way junction with alternating arm lengths of 10 and 14 base pairs. The junction is a hybrid of the conventional square-planar and stacked-X conformation. Endo VII protrudes into the junction point from the minor groove side, opening it to a 14 A x 32 A parallelogram. This interaction interrupts the coaxial stacking, yet every base pair surrounding the junction remains intact. Additional interactions involve the positively charged protein and DNA phosphate backbones. Each scissile phosphate that is two base pairs from the crossover interacts with a Mg2+ ion in the active site. The similar overall shape and surface charge potential of the Holliday junction resolvases endo VII, RuvC, Ydc2, Hjc and RecU, despite having different folds, active site composition and DNA sequence preference, suggest a conserved binding mode for Holliday junctions.     

Structure of the recA protein-ADP complex.

The recA protein catalyses the ATP-driven homologous pairing and strand exchange of DNA molecules. It is an allosteric enzyme: the ATPase activity is DNA-dependent, and ATP-bound recA protein has a high affinity for DNA, whereas the ADP-bound form has a low affinity. In the absence of ATP hydrolysis, recA protein can still promote homologous pairing, apparently through the formation of a triple-stranded intermediate. The exact role of ATP hydrolysis is not clear, but it presumably drives the triplex intermediate towards products. Here we determine the position of bound ADP diffused into the recA crystal. We show that only the phosphates are bound in the same way as in other NTPases containing the G/AXXXXGKT/S motif. We propose that recA protein may change its conformation upon ATP hydrolysis in a manner analogous to one such protein, the p21 protein from the ras oncogene. A model is presented to account for the allosteric stimulation of DNA binding by ATP. The mechanism by which nucleoside triphosphate hydrolysis is coupled to the binding of another ligand in recA protein and p21 may be typical of the large class of NTPases containing this conserved motif.     

Role of poly(ADP-ribose) formation in DNA repair.

The abundant nuclear enzyme poly(ADP-ribose) polymerase catalyses the synthesis of poly(ADP-ribose) from nicotinamide adenine dinucleotide (NAD+). This protein has an N-terminal DNA-binding domain containing two zinc-fingers, which is linked to the C-terminal NAD(+)-binding domain by a short region containing several glutamic acid residues that are sites of auto-poly(ADP-ribosyl)ation. The intracellular production of poly(ADP-ribose) is induced by agents that generate strand interruptions in DNA. The branched homopolymer chains may attain a size of 200-300 residues but are rapidly degraded after synthesis. The function of poly(ADP-ribose) synthesis is not clear, although it seems to be required for DNA repair. Here we describe a human cell-free system that enables the role of poly(ADP-ribose) synthesis in DNA repair to be characterized. The results indicate that unmodified polymerase molecules bind tightly to DNA strand breaks; auto-poly(ADP-ribosyl)ation of the protein then effects its release and allows access to lesions for DNA repair enzymes.     

Cloning and expression of a rat brain L-glutamate transporter.

Synaptic transmission of most vertebrate synapses is thought to be terminated by rapid transport of the neurotransmitter into presynaptic nerve terminals or neuroglia. L-Glutamate is the major excitatory transmitter in brain and its transport represents the mechanism by which it is removed from the synaptic cleft and kept below toxic levels. Here we use an antibody against a glial L-glutamate transporter from rat brain to isolate a complementary DNA clone encoding this transporter. Expression of this cDNA in transfected HeLa cells indicates that L-glutamate accumulation requires external sodium and internal potassium and transport shows the expected stereospecificity. The cDNA sequence predicts a protein of 573 amino acids with 8-9 putative transmembrane alpha-helices. Database searches indicate that this protein is not homologous to any identified protein of mammalian origin, including the recently described superfamily of neurotransmitter transporters. This protein therefore seems to be a member of a new family of transport molecules.     

Selection of single-stranded DNA molecules that bind and inhibit human thrombin.

Aptamers are double-stranded DNA or single-stranded RNA molecules that bind specific molecular targets. Large randomly generated populations can be enriched in aptamers by in vitro selection and polymerase chain reaction. But so far single-stranded DNA has not been investigated for aptamer properties, nor has a target protein been considered that does not interact physiologically with nucleic acid. Here we describe the isolation of single-stranded DNA aptamers to the protease thrombin of the blood coagulation cascade and report binding affinities in the range 25-200 nM. Sequence data from 32 thrombin aptamers, selected from a pool of DNA containing 60 nucleotides of random sequence, displayed a highly conserved 14-17-base region. Several of these aptamers at nanomolar concentrations inhibited thrombin-catalysed fibrin-clot formation in vitro using either purified fibrinogen or human plasma.     

Bacterial chromatin organization by H-NS protein unravelled using dual DNA manipulation

Both prokaryotic and eukaryotic organisms contain DNA bridging proteins, which can have regulatory or architectural functions. The molecular and mechanical details of such proteins are hard to obtain, in particular if they involve non-specific interactions. The bacterial nucleoid consists of hundreds of DNA loops, shaped in part by non-specific DNA bridging proteins such as histone-like nucleoid structuring protein (H-NS), leucine-responsive regulatory protein (Lrp) and SMC (structural maintenance of chromosomes) proteins. We have developed an optical tweezers instrument that can independently handle two DNA molecules, which allows the systematic investigation of protein-mediated DNA-DNA interactions. Here we use this technique to investigate the abundant non-specific nucleoid-associated protein H-NS, and show that H-NS is dynamically organized between two DNA molecules in register with their helical pitch. Our optical tweezers also allow us to carry out dynamic force spectroscopy on non-specific DNA binding proteins and thereby to determine an energy landscape for the H-NS-DNA interaction. Our results explain how the bacterial nucleoid can be effectively compacted and organized, but be dynamic in nature and accessible to DNA-tracking motor enzymes. Finally, our experimental approach is widely applicable to other DNA bridging proteins, as well as to complex DNA interactions involving multiple DNA molecules.     

Crystal structure of the met repressor-operator complex at 2.8 A resolution reveals DNA recognition by beta-strands.

The crystal structure of the met repressor-operator complex shows two dimeric repressor molecules bound to adjacent sites 8 base pairs apart on an 18-base-pair DNA fragment. Sequence specificity is achieved by insertion of double-stranded antiparallel protein beta-ribbons into the major groove of B-form DNA, with direct hydrogen-bonding between amino-acid side chains and the base pairs. The repressor also recognizes sequence-dependent distortion or flexibility of the operator phosphate backbone, conferring specificity even for inaccessible base pairs.     

DNA trapping electrophoresis

Attempts to improve the size separation of single-stranded DNA in polyacrylamide gels by field-inversion gel electrophoresis (FIGE) have met with limited success. Here we show that attaching a neutral globular protein, streptavidin, to one end of a single-stranded DNA molecule profoundly alters the DNA mobility pattern and increases the band separation manyfold within a size range controlled by voltage and pulse cycle. In constant field, short modified fragments are only slightly retarded but long molecules are retarded dramatically above a 'threshold size' of 0.6 kilobases at 60 V per cm. At this voltage, molecules above a 1.2-kilobase 'cut-off' do not enter the gel. Both the threshold and the cut-off sizes decrease as the voltage increases. In FIGE, the longer the reverse pulse, the larger the modified fragments that enter the gel. We interpret these results as the trapping by the gel matrix of the protein attached to the DNA. The probability of release then depends on the balance between the electric field and thermal motion: the larger the DNA and the higher the voltage, the harder it is to release.     

Covalently closed circles of adenovirus 5 DNA

The genome of adenoviruses is a double-stranded linear DNA molecule with inverted terminal repeats about 100 base pairs (bp) in length and a terminal protein covalently linked to the 5' nucleotide of each strand. Both of these features permit the formation of DNA circles, the inverted repeats allowing the circularization of single-stranded DNA and the terminal protein the joining of one or more molecules to yield double-stranded circles or concatemers. However, although the existence of covalently closed circles has been postulated, double-stranded viral DNA purified from virions or infected cells by conventional methods (that is, using proteases and phenol or chloroform) has always been obtained in a linear form. Here, we present evidence for the existence in adenovirus 5 (Ad5) infected cells of novel structures resulting from covalent head-to-tail joining of viral DNA molecules and show that these structures are due at least in part to the formation of covalently closed circles.     

The cohesin ring concatenates sister DNA molecules

Sister chromatid cohesion, which is essential for mitosis, is mediated by a multi-subunit protein complex called cohesin. Cohesin's Scc1, Smc1 and Smc3 subunits form a tripartite ring structure, and it has been proposed that cohesin holds sister DNA molecules together by trapping them inside its ring. To test this, we used site-specific crosslinking to create chemical connections at the three interfaces between the three constituent polypeptides of the ring, thereby creating covalently closed cohesin rings. As predicted by the ring entrapment model, this procedure produced dimeric DNA-cohesin structures that are resistant to protein denaturation. We conclude that cohesin rings concatenate individual sister minichromosome DNA molecules.     

Domain of E. coli DNA polymerase I showing sequence homology to T7 DNA polymerase

Escherichia coli contains three DNA polymerases that differ in their size, ability to interact with accessory proteins and biological function. Monomeric DNA polymerase I (Pol I) has a relative molecular mass (Mr) of 103,000 (103K) and is involved primarily in the repair of damaged DNA and the processing of Okazaki fragments; polymerase II is of Mr 120K, and polymerase III has a Mr of 140K, is responsible for the replication of the DNA chromosome and is just one of several proteins that are required for replication. DNA polymerases from bacteriophage as well as those of eukaryotic viral and cellular origin also differ with respect to their size and the number of associated proteins that are required for them to function in replication. However, the template-directed copying of DNA is identical in all cases. The crystal structure of the large proteolytic fragment of Pol I shows that it consists of two domains, the larger of which contains a deep crevice whose dimensions are such that it can bind duplex DNA. The T7 polymerase consists of two subunits, the 80K gene 5 protein and the host-encoded 12K thioredoxin of E. coli. We show here that there is an amino acid sequence homology between at least eight polypeptide segments that form the large cleft in the Klenow fragment and polypeptides in T7 DNA polymerase gene 5 protein, suggesting that this domain evolved from a common precursor. The parts of the Pol I and T7 DNA polymerase molecules that bind the DNA substrate appear to share common structural features, and these features may be shared by all of these varied DNA polymerases.     

不同方法提取鳗鲡病原茵DNA模板的差异分析

利用吸光值、琼脂糖电泳及PCR差异扩增等指标,对酚一氯仿法、水煮法、碱裂解法3种方法制备的鳗鲡病原菌DNA模板进行了差异分析．结果表明：1）不同方法提取的病原菌模板DNA的浓度、纯度及分子质量大小存在差异,但以这3种方法提取的病原菌DNA为模板,均能成功扩增到细菌16SrD．NA和外膜蛋白的保守序列．其中,酚一氯仿提取的模板DNA浓度较低、纯度较高;水煮法和碱裂解法提取的模板DNA浓度较高、纯度较低．2）电泳显示,3种方法获得的模板DNA扩增出的16SrDNA保守序列条带均一,没有显著差异,但在外膜蛋白保守序列的扩增中却因菌种和模板提取方法的不同而存在差异．     

Membrane structure and interactions with protein and DNA in bacteriophage PRD1

Membranes are essential for selectively controlling the passage of molecules in and out of cells and mediating the response of cells to their environment. Biological membranes and their associated proteins present considerable difficulties for structural analysis. Although enveloped viruses have been imaged at about 9 A resolution by cryo-electron microscopy and image reconstruction, no detailed crystallographic structure of a membrane system has been described. The structure of the bacteriophage PRD1 particle, determined by X-ray crystallography at about 4 A resolution, allows the first detailed analysis of a membrane-containing virus. The architecture of the viral capsid and its implications for virus assembly are presented in the accompanying paper. Here we show that the electron density also reveals the icosahedral lipid bilayer, beneath the protein capsid, enveloping the viral DNA. The viral membrane contains about 26,000 lipid molecules asymmetrically distributed between the membrane leaflets. The inner leaflet is composed predominantly of zwitterionic phosphatidylethanolamine molecules, facilitating a very close interaction with the viral DNA, which we estimate to be packaged to a pressure of about 45 atm, factors that are likely to be important during membrane-mediated DNA translocation into the host cell. In contrast, the outer leaflet is enriched in phosphatidylglycerol and cardiolipin, which show a marked lateral segregation within the icosahedral asymmetric unit. In addition, the lipid headgroups show a surprising degree of order.     

Discovery and demonstration of small circular DNA molecules derived from Chinese tomato yellow leaf curl virus

Tomato yetlow leaf curl viruses betong to Begomoviruses of geminiviruses. In this work, we first found and demonstrated that the small circular DNA molecules were derived from Chinese tomato yetlow leaf curl viruses (TYLCV-CHI). These small circular DNA molecules are about 1,3 kb, which are half the full-length of TYLCV-CHI DNA A. It was shown by sequence determination and analysis that there was unknown-origin sequence insertion in the middle of the small molecules. These sequences of unknown-origin were neither homologous to DNA A nor to DNA B, and were formed by recombination of virus DNA and plant DNA. Although various defective molecules contained different unknown-origin sequence insertion, all the molecules contained the intergenic region and part of the AC1 (Rep) gene. But they did not contain full ORF.     

Identification of a nanovirus-like DNA molecule associated with Tobacco curly shoot virus isolates containing satellite DNA

A circular single-stranded DNA molecule, designated DNA1, was identified from Tobacco curly shoot virus (TbCSV) isolates Y35 and Y115 containing satellite DNAβ using abutting primers based on the two reported DNA1 sequences of whitefly-transmitted geminiviruses, while DNA1 molecule was not found in TbCSV isolates Y1 and Y121 without DNAβ. The immunotrapping PCR test showed that DNA1 could be encapsidated in virus particles. Southern blot further confirmed that DNA1 molecules were only associated with TbCSV isolates (Y35 and Y115) containing DNAβ. Sequences of Y35 and Y115 DNA1 comprise 1367 and 1368 nucleotides, respectively, each having a conserved ORF encoding nanovirus-like replication-associated protein (Rep). A low nucleotide sequence identity was found between DNA1 molecules and their cognate DNA-As. Y35 and Y115 DNA1 shared 92% overall nucleotide sequence identity and 96% amino acid sequence identity for Rep, while 69%～79% overall nucleotide sequence identity and 87%～90% amino acid sequence identity were found when compared with two reported DNA1 molecules associated with Ageratum yellow vein virus and Cotton leaf curl Multon virus. Sequence analysis showed that DNA1 was less related to nanovirus DNA.     

Determination of the absolute handedness of knots and catenanes of DNA

DNA winds about itself in a right-handed or left-handed fashion at several structural levels. The double helix is generally right-handed and is given a (+) sign by convention, whereas supercoiling of the helix axis is always (-) in the cell. The winding in higher -order forms such as knots and catenanes is unknown, and this has impeded elucidation of the mechanisms of their formation and resolution by replication, recombination and topoisomerase action. We introduce here a procedure for determining the handedness of DNA winding by inspection of electron micrographs of DNA molecules coated with Escherichia coli RecA protein. We demonstrate the validity of the method and show that DNA topoisomerase I of E. coli generates an equal mixture of (+) and (-) duplex DNA knots, and that one product of recombination by resolvase of transposon Tn3 (refs 8, 9) is a catenane of uniquely (+) sign.     

Restoration of antigen presentation to the mutant cell line RMA-S by an MHC-linked transporter.

In mammalian cells, short peptides derived from intracellular proteins are displayed on the cell membrane associated with class I molecules of the major histocompatibility complex (MHC). The surface presentation of class I-peptide complexes presumably alerts the immune system to intracellular viral protein synthesis. Peptides derived from the cytosol must reach the cisternae of the endoplasmic reticulum where they are required for the assembly of stable class I molecules, and it has been proposed that the products of the two MHC-encoded ATP-binding cassette (ABC) transporter genes function to deliver the peptides across the membrane of the endoplasmic reticulum. This idea is supported by experiments in which transfection of a human cell line defective in class I expression with a complementary DNA of one of these genes restored cell surface expression levels. Here we show that the complete phenotype of the mouse mutant cell line RMA-S, in which lack of surface expression of stable class I molecules correlates with an inability to present viral peptides originating in the cytosol, is repaired by the cDNA of the other transporter gene. These results are consistent with the possibility that the two transporter polypeptides form a heterodimer.     

CD21 is a ligand for CD23 and regulates IgE production.

The molecule CD23, a low-affinity receptor for IgE (Fc epsilon R2), is a type II transmembrane molecule expressed on many haemopoietic cell types. CD23 has pleiotropic roles in the control of lymphocyte behaviour, suggesting that CD23 may interact with another ligand in addition to IgE. To identify such a CD23 ligand, we expressed and purified full-length recombinant CD23, incorporated it into fluorescent liposomes and used these as a probe. We report here that fluorescent liposomes carrying CD23 interact specifically with the cell-surface protein CD21, identified as the receptor for Epstein-Barr virus and the complement receptor-2 on B cells, some T cells and follicular dendritic cells. In addition, fluorescent CD23-liposomes were shown to bind to hamster kidney cells (BHK-21) transfected with CD21 complementary DNA. The interaction between fluorescent CD23-liposomes and B cells or CD21-transfected BHK-21 cells was specifically inhibited by anti-CD21 and anti-CD23 monoclonal antibodies. Western blotting analysis revealed that 14C-labelled liposomes carrying CD23, in contrast to anti-CD21 antibodies, reacted with a subtype of CD21 molecules. Triggering of CD21 either with an anti-CD21 antibody or with recombinant soluble CD23 was shown to increase specifically interleukin-4-induced IgE production from blood mononuclear cells. These results demonstrate that the cell-surface protein CD21 is a ligand for CD23 and that the pairing of these molecules may participate in the control of IgE production.