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.     

Chromosome length influences replication-induced topological stress

During chromosome duplication the parental DNA molecule becomes overwound, or positively supercoiled, in the region ahead of the advancing replication fork. To allow fork progression, this superhelical tension has to be removed by topoisomerases, which operate by introducing transient DNA breaks. Positive supercoiling can also be diminished if the advancing fork rotates along the DNA helix, but then sister chromatid intertwinings form in its wake. Despite these insights it remains largely unknown how replication-induced superhelical stress is dealt with on linear, eukaryotic chromosomes. Here we show that this stress increases with the length of Saccharomyces cerevisiae chromosomes. This highlights the possibility that superhelical tension is handled on a chromosome scale and not only within topologically closed chromosomal domains as the current view predicts. We found that inhibition of type I topoisomerases leads to a late replication delay of longer, but not shorter, chromosomes. This phenotype is also displayed by cells expressing mutated versions of the cohesin- and condensin-related Smc5/6 complex. The frequency of chromosomal association sites of the Smc5/6 complex increases in response to chromosome lengthening, chromosome circularization, or inactivation of topoisomerase 2, all having the potential to increase the number of sister chromatid intertwinings. Furthermore, non-functional Smc6 reduces the accumulation of intertwined sister plasmids after one round of replication in the absence of topoisomerase 2 function. Our results demonstrate that the length of a chromosome influences the need of superhelical tension release in Saccharomyces cerevisiae, and allow us to propose a model where the Smc5/6 complex facilitates fork rotation by sequestering nascent chromatid intertwinings that form behind the replication machinery.     

Recognition sequence of bacteriophage phi X174 gene A protein--an initiator of DNA replication

Gene A protein, the initiator protein of bacteriophage phi X174 DNA replication, cleaves synthetic single-stranded oligodeoxyribonucleotides at the same site as the corresponding sequence at the phi X origin. The results identify the recognition sequence within the decamer CAACTTGATA which is cleaved next to the G residue. Further requirements for cleavage of double-stranded DNA by the gene A protein are supercoiling and an A + T-rich domain adjacent to the recognition sequence.     

灵芝三萜类成分抑制拓扑异构酶I活性的研究

以灵芝中的三萜类组分(灵芝酸T)为实验药物，考察其对拓扑异构酶I活性的影响。结果表明：灵芝酸T能抑制拓扑异构酶I活性，且具有浓度依赖性。进一步机理研究表明灵芝酸T可以抑制拓扑异构酶-底物复合物的形成，阻止DNA和酶的相互作用。因此，灵芝酸T属于拓扑异构酶I的催化型抑制剂，这可为灵芝中三萜类物质的研究开发提供理论依据。     

Single-molecule analysis of DNA uncoiling by a type II topoisomerase

Type II DNA topoisomerases are ubiquitous ATP-dependent enzymes capable of transporting a DNA through a transient double-strand break in a second DNA segment. This enables them to untangle DNA and relax the interwound supercoils (plectonemes) that arise in twisted DNA. In vivo, they are responsible for untangling replicated chromosomes and their absence at mitosis or meiosis ultimately causes cell death. Here we describe a micromanipulation experiment in which we follow in real time a single Drosophila melanogaster topoisomerase II acting on a linear DNA molecule which is mechanically stretched and supercoiled. By monitoring the DNA's extension in the presence of ATP, we directly observe the relaxation of two supercoils during a single catalytic turnover. By controlling the force pulling on the molecule, we determine the variation of the reaction rate with the applied stress. Finally, in the absence of ATP, we observe the damping of a DNA crossover by a single topoisomerase on at least two different timescales (configurations). These results show that single molecule experiments are a powerful new tool for the study of topoisomerases.     

Need for DNA topoisomerase activity as a swivel for DNA replication for transcription of ribosomal RNA

Yeast strains with mutations in the genes for DNA topoisomerases I and II have been identified previously in both Saccharomyces cerevisiae and Schizosaccharomyces pombe. The topoisomerase II mutants (top2) are conditional-lethal temperature-sensitive (ts) mutants. They are defective in the termination of DNA replication and the segregation of daughter chromosomes, but otherwise appear to replicate and transcribe DNA normally. Topoisomerase I mutants (top1), including strains with null mutations are viable and exhibit no obvious growth defects, demonstrating that DNA topoisomerase I is not essential for viability in yeast. In contrast to the single mutants, top1 top2 ts double mutants from both Schizosaccharomyces pombe and Saccharomyces cerevisiae grow poorly at the permissive temperature and stop growth rapidly at the non-permissive temperature. Here we report that DNA and ribosomal RNA synthesis are drastically inhibited in an S. cerevisiae top1 top2 ts double mutant at the restrictive temperature, but that the rate of poly(A)+ RNA synthesis is reduced only about threefold and transfer DNA synthesis remains relatively normal. The results suggest that DNA replication and at least ribosomal RNA synthesis require an active topoisomerase, presumably to act as a swivel to relieve torsional stress, and that either topoisomerase can perform the required function (except in termination of DNA replication where topoisomerase II is required).     

萘亚胺类化合物对DNA光敏剪切作用的初步研究

研究了Ｎ－（Ｎ,Ｎ－二甲基）－乙胺－１,８－萘硫酰亚胺和Ｎ－（Ｎ,Ｎ－二甲基）－乙胺－１,８－萘酰亚胺对小牛胸腺ＤＮＡ的嵌入结合反应,并求取了嵌入常数,它们可以把质粒ｐＵＣ１９的超螺旋ＤＮＡ剪切为开环ＤＮＡ,在紫外光作用下,这种能力会得到不同程度的提高。     

用STM证实质粒pUC18DNA分子新构象的存在

用清高妥液法从大肠杆菌ＢＨ１０１细胞制备出的多拷贝质粒ＰＵＣ１８ＤＮＡ分子的构象具有复杂的多样性，我们在对其进行ＳＴＭ研究计，证实了一种不同于已知构象的新构象的存在。     

Activating protein factor binds in vitro to upstream control sequences in heat shock gene chromatin

DNA sequences, important for the control of Drosophila heat shock gene expression, are packaged in chromatin in a nuclease hypersensitive configuration. Recently, two protein-binding (exonuclease-resistant) sites which cover the TATA box sequence and an upstream control element were shown to occur in vivo amidst the 5' terminal hypersensitive regions of several heat shock genes. Protein-binding at the TATA box is independent of heat shock, but the binding at the upstream element is heat shock dependent, and it was proposed that a heat shock activator protein, HAP, positively regulates the genes. Here, I report the detection of HAP activity in heat shocked cell extracts by reconstituting specific binding to hsp82 gene chromatin in vitro. Inhibition of the binding by free DNA from the 5' region of heat shock genes implies a coordinate regulation of the gene family through HAP interaction with the upstream heat shock consensus sequence. Furthermore, the special ease of induction of the hsp82 gene over other heat shock genes can be explained in molecular terms by the higher affinity of HAP for the hsp82 binding site, which contains a 28 base sequence with almost perfect dyad symmetry, GAAGCCTCTAGAAG/TTTCTAGAGACTTC.     

Domain interactions of H-2 class I antigens alter cytotoxic T-cell recognition sites

H-2 class I antigens appear to direct the recognition of virus-infected and neoplastic transformed cells by cytotoxic T lymphocytes (CTLs). Here, to identify the regions of class I antigens involved in CTL recognition, four hybrid class I genes were constructed in which exons were exchanged between the H-2Kb and H-2Db genes. These class I genes were expressed in mouse L cells and recognition of the hybrid Kb/Db antigens by CTLs and monoclonal antibodies specific for either Kb or Db was investigated. The pattern of CTL and monoclonal antibody recognition obtained indicates three correlations between structure and function of class I antigens. First, most CTL recognition sites and alloantigenic determinants are located on domains 1 and 2 of the antigen molecule. Second, these CTL recognition sites and alloantigenic determinants are not influenced by interaction of domains 1 and 2 with polymorphic regions of domain 3. Third, in contrast, interaction between domains 1 and 2 alters these CTL recognition sites and alloantigenic determinants. The alteration of CTL recognition sites by interaction between domains 1 and 2 suggests that a CTL site may be formed by amino acids from both domains 1 and 2, or that the conformation of amino acids at a CTL site may be altered by interactions between domains 1 and 2. Through these two features, the conformation of CTL recognition sites on H-2 class I antigens may be sensitive to alteration by interaction of either domain 1 or 2 with viral antigens.     

Recognition of a chromosome truncation site associated with alpha-thalassaemia by human telomerase

Telomeres define the ends of chromosomes; they consist of short tandemly repeated DNA sequences loosely conserved in eukaryotes (G1-8(T/A)1-4). Telomerase is a ribonucleoprotein which, in vitro, recognizes a single-stranded G-rich telomere primer and adds multiple telomeric repeats to its 3' end by using a template in the RNA moiety. In conjunction with other components, telomerase may balance the loss of telomeric repeats due to DNA replication. Another role of telomerase may be the de novo formation of telomeres. In eukaryotes like Tetrahymena, this process is an integral part of the formation of macronuclear chromosomes. In other eukaryotes this process stabilizes broken chromosomes. A case of human alpha-thalassaemia is caused by a truncation of chromosome 16 that has been healed by the addition of telomeric repeats (TTAGGG)n. Using an in vitro assay, I show here that human telomerase correctly recognizes the chromosome 16 breakpoint sequence and adds (TTAGGG)n repeats. The DNA sequence requirements are minimal and seem to define two modes of DNA recognition by telomerase.