Rescue of abortive T7 gene 2 mutant phage infection by rifampin.

Infection of Escherichia coli with T7 gene 2 mutant phage was abortive; concatemeric phage DNA was synthesized but was not packaged into the phage head, resulting in an accumulation of DNA species shorter in size than the phage genome, concomitant with an accumulation of phage head-related structures. Appearance of concatemeric T7 DNA in gene 2 mutant phage infection during onset of T7 DNA replication indicates that the product of gene 2 was required for proper processing or packaging of concatemer DNA rather than for the synthesis of T7 progeny DNA or concatemer formation. This abortive infection by gene 2 mutant phage could be rescued by rifampin. If rifampin was added at the onset of T7 DNA replication, concatemeric DNA molecules were properly packaged into phage heads, as evidenced by the production of infectious progeny phage. Since the gene 2 product acts as a specific inhibitor of E. coli RNA polymerase by preventing the enzyme from binding T7 DNA, uninhibited E. coli RNA polymerase in gene 2 mutant phage-infected cells interacts with concatemeric T7 DNA and perturbs proper DNA processing unless another inhibitor of the enzyme (rifampin) was added. Therefore, the involvement of gene 2 protein in T7 DNA processing may be due to its single function as the specific inhibitor of the host E. coli RNA polymerase.     

DNA polymerase III, a second essential DNA polymerase, is encoded by the S. cerevisiae CDC2 gene

Three nuclear DNA polymerases have been described in yeast: DNA polymerases I, II, and III. DNA polymerase I is encoded by the POL1 gene and is essential for DNA replication. Since the S. cerevisiae CDC2 gene has recently been shown to have DNA sequence similarity to the active site regions of other known DNA polymerases, but to nevertheless be different from DNA polymerase I, we examined cdc2 mutants for the presence of DNA polymerases II and III. DNA polymerase II was not affected by the cdc2 mutation. DNA polymerase III activity was significantly reduced in the cdc2-1 cell extracts. We conclude that the CDC2 gene encodes yeast DNA polymerase III and that DNA polymerase III, therefore, represents a second essential DNA polymerase in yeast.     

水稻愈伤组织形成过程中甲基化对OsMAPK2的表达调控

利用MSAP方法从经过5-azaC处理和未处理的水稻愈伤组织中获得了1个存在甲基化位点的片段。测序后比对分析表明,该片段为水稻MAPK家族OsMAPK2基因的5′端区域。该基因5′端区域有一个CpG岛,与拟南芥AtMAPK12基因序列高度相似。利用实时定量PCR和HpaII-McrBC PCR分析了在水稻芽段受生长素刺激后形成愈伤组织过程中OsMAPK2基因的表达与甲基化的关系。结果表明:该基因表达量与基因5′端甲基化水平相对应,甲基化调控基因的表达。在愈伤组织形成过程中2.0mg/L的2,4-D诱导该基因5′端区域去甲基化,使基因表达,而长时间(100h)的诱导后或导致重新甲基化,基因表达量降低;低浓度的2,4-D(0.5和1.0mg/L)也可以产生同样的趋势,但是基因的表达量低于2.0mg/L的2,4-D的诱导;高浓度的2,4-D(5.0mg/L)可以在较短的时间内完成对基因的诱导和抑制。     

Transfection of Escherichia coli spheroplasts. VI. Transfection of nonpermissive spheroplasts by T5 and BF23 bacteriophage DNA carrying amber mutations in DNA transfer genes.

DNA was extracted from T5 and BF23 phage carrying amber mutations in genes A2, A1, or D9 and tested for its ability to transfect su minus spheroplasts. DNA from T5 am231, defective in gene A2, transfects Escherichia coli su minus recB minus spheroplasts with an efficiency of 16% of that of wild-type T5 DNA, whereas DNA from T5 am16d or BF23 am57, both defective in gene A1 or its equivalent, transfects E. coli su minus recB minus spheroplasts with an efficiency of 1.4% of that of wild-type T5 DNA, provided E. coli su+ bacteria is used as the indicator in all cases. More than 95% of the progeny from the am231, am16d, and am57 DNA that transfects su minus recB minus spheroplasts is still amber mutant. From these efficiencies of transfection we conclude that the product of gene A2 functions mainly in the mechanism of transfer of phage DNA to intact host cells, and that this function is not essential for transfection of spheroplasts. We also conclude that gene A1 controls functions in addition to DNA transfer, in agreement with previous studies which show that mutations in gene A1 have a pleiotropic effect. Apparently, the absence of these additional functions controlled by gene A1 leads to a high frequency of abortive infection. DNA from amber mutants defective in either gene A1 or A2 does not appreciably transfect su minus rec+ spheroplasts, indicating that the products of these two genes may both be needed to protect T5 DNA from the very active rec BC nuclease in spheroplasts.     

Efficient non-viral gene delivery mediated by nanostructured calcium carbonate in solution-based transfection and solid-phase transfection

Among different non-viral gene delivery methods, the technique of co-precipitation of Ca(2+) with DNA in the presence of inorganic anions is an attractive option because of the biocompatibility and biodegradability. In this study, nano-sized CaCO(3)/DNA co-precipitates for gene delivery were prepared. The effect of Ca(2+)/CO(3)(2-) molar ratio on the gene delivery was investigated. The mechanism of the transfection mediated by CaCO(3)/DNA co-precipitates was studied by treatment of the cells with chloroquine, wortmannin and cytochalasin D, respectively. The in vitro gene transfections in different cells were carried out for both solution-based transfection and solid-phase transfection. The gene expression of the calcium carbonate based approach is strongly affected by the Ca(2+)/CO(3)(2-) ratio because the size of CaCO(3)/DNA co-precipitates is mainly determined by the Ca(2+)/CO(3)(2-) ratio. In addition, the encapsulation efficiency of DNA increases with decreasing Ca(2+)/CO(3)(2-) ratio. With a suitable Ca(2+)/CO(3)(2-) ratio, CaCO(3)/DNA co-precipitates could effectively mediate gene transfection with the expression levels higher than that of Lipofectamine 2000 in the presence of serum. The mechanism study shows that CaCO(3)/DNA co-precipitates are internalized via endocytosis of the cells and macropinocytosis is the main route of internalization. Compared with the solution-based transfection, CaCO(3)/DNA co-precipitates in the solid-phase transfection exhibit a lower gene expression level. The calcium carbonate based approach has great potential in gene delivery.     

Characterization of a human SWI2/SNF2 like protein hINO80: demonstration of catalytic and DNA binding activity

The proteins belonging to SWI2/SNF2 family of DNA dependent ATPases are important members of the chromatin remodeling complexes that are implicated in epigenetic control of gene expression. We have identified a human gene with a putative DNA binding domain, which belongs to the INO80 subfamily of SWI2/SNF2 proteins. Here we report the cloning, expression, and functional activity of the domains from hINO80 gene both in terms of the DNA dependent ATPase as well as DNA binding activity. A differential expression of the various domains within this gene is detected in human tissues while a ubiquitous expression is detected in mice. The intranuclear localization is demonstrated using antibodies directed against the DBINO domain of hINO80.     

Role of gene 2 in bacteriophage T7 DNA synthesis.

Studies have been carried out to elucidate the in vivo function of gene 2 in T7 DNA synthesis. In gene 2-infected cells the rate of incorporation of (3-H)thymidine into acid-insoluble material is about 60% that of cells infected with T7 wild type. Gene 2 mutants do not however produce viable phage after infection of the nonpermissive host. In T7 wild type-infected cells, a major portion of the newly alkaline sucrose gradients. The concatemers serve as precursors for the formation of mature T7 DNA as demonstrated in pulse-chase experiments. In similar studies carried out with gene 2-infected cells, concatemers are not detected when the intracellular DNA is analyzed at several different times during the infection process. The DNA made during a gene 2 infection is present as duplex structures with a sedimentation rate close to mature T7 DNA.     

Novel gene exon homologous to pancreatic phospholipase A2: sequence and chromosomal mapping of both human genes

We described previously the cloning and DNA sequence of the human gene encoding pancreatic phospholipase A2 [DNA 5, 519]. When pancreatic phospholipase A2 (PLA2) cDNA was used to screen a human genomic library, two classes of clones were obtained. One class encoded the pancreatic enzyme, and a second class encoded one exon of an apparently related PLA2. No additional PLA2 gene exons displayed sufficient homology to be detected by the probe. A homologous sequence in both rat and porcine genomic DNA was detected by DNA blot hybridization, and the corresponding gene fragments were cloned and sequenced. Within the deduced amino acid sequences, the presence of known functional residues along with the high degree of interspecies conservation suggests the genes encode a functional PLA2 enzyme form. The encoded sequence lacks Cys11, as do the "type II" viperid venom and other nonpancreatic mammalian PLA2 enzymes. The sequence is distinct from porcine intestinal PLA2 and appears not to be a direct homolog of the recently published rabbit ascites and rat platelet enzymes. Hybridization of DNA probes containing sequences from these genes to genomic DNA blots of mouse/human somatic cell hybrids permitted chromosomal assignment for both. The pancreatic gene mapped to human chromosome 12, and the homologous gene mapped to chromosome 1.     

Bacteriophage P2 ogr and P4 delta genes act independently and are essential for P4 multiplication.

Satellite bacteriophage P4 requires the products of the late genes of a helper phage such as P2 for lytic growth. Expression of the P2 late genes is positively regulated by the P2 ogr gene in a process requiring P2 DNA replication. Transactivation of P2 late gene expression by P4 requires the P4 delta gene product and works even in the absence of P2 DNA replication. We have made null mutants of the P2 ogr and P4 delta genes. In the absence of the P4 delta gene product, P4 multiplication required both the P2 ogr protein and P2 DNA replication. In the absence of the P2 ogr gene product, P4 multiplication required the P4 delta protein. In complementation experiments, we found that the P2 ogr protein was made in the absence of P2 DNA replication but could not function unless P2 DNA replicated. We produced P4 delta protein from a plasmid and found that it complemented the null P4 delta and P2 ogr mutants.     

Targeted transformation of Ascobolus immersus and de novo methylation of the resulting duplicated DNA sequences.

To develop a method to modify genomic sequences in Ascobolus immersus by precisely reintroducing defined DNA segments previously manipulated in vitro, we investigated the effect of transforming DNA conformation on recombination with chromosomal sequences. Circular single-stranded DNA carrying the met2 gene and double-stranded DNA linearized by cutting within the met2 gene both transformed protoplasts of a met2 mutant strain of A. immersus to prototrophy. In contrast to the equivalent circular double-stranded DNA, which chiefly integrated at nonhomologous chromosomal sites, single-stranded and double-stranded cut DNAs recombined primarily with the homologous chromosomal met2 sequence. Of the single-stranded DNA transformants, 65% resulted from replacement of the resident met2 mutation by the exogenous wild-type allele. In 70% of the double-stranded-cut DNA transformants, one or more copies of the transforming DNA had integrated at the met2 locus, leading to tandem duplications of the met2 target region separated by plasmid DNA. These duplicated sequences could recombine, leading to progeny containing only one copy of the met2 region. This resulted in a precise gene replacement if the wild-type allele had been retained. In addition, we show that newly duplicated sequences were most often de novo methylated at the cytosine residues during the sexual phase. Cytosine methylation was associated with inactivation of the integrated met2 gene(s) in segregants of crosses. However, methylation was not accurately maintained at each DNA replication cycle, so that Met- segregants recovered a wild-type phenotype through successive mitotic divisions. This finding indicated that met2 genes were silenced by methylation alone.     

Stable integration of foreign DNA into the chromosome of the cyanobacterium Synechococcus R2

The blue-green alga, Synechococcus R2, is transformed to antibiotic resistance by chimeric DNA molecules consisting of Synechococcus R2 chromosomal DNA linked to antibiotic-resistance genes from Escherichia coli. Chimeric DNA integrates into the Synechococcus R2 chromosome by homologous recombination. The efficiency of transformation, as well as the stability of integrated foreign DNA, depends on the position of the foreign genes relative to Synechococcus R2 DNA in the chimeric molecule. When the Synechococcus R2 DNA fragment is interrupted by foreign DNA, integration occurs through replacement of chromosomal DNA by homologous chimeric DNA containing the foreign insert; transformation is efficient and the foreign gene is stable. Mutagenesis in some cases attends integration, depending on the site of insertion. Foreign DNA linked to the ends of Synechococcus R2 DNA in a circular molecule, however, integrates less efficiently. Integration results in duplicate copies of Synechococcus R2 DNA flanking the foreign gene and the foreign DNA is unstable. Transformation in Synechococcus R2 can be exploited to modify precisely and extensively the genome of this photosynthetic microorganism.