Although researchers have established that DNA methylation and active demethylation are dynamically regulated in plant cells, the molecular mechanism for the regulation of active DNA demethylation is not well understood. By using an Arabidopsis (Arabidopsis thaliana) line expressing the Promoter RESPONSIVE TO DEHYDRATION 29A:LUCIFERASE (ProRD29A:LUC) and Promoter cauliflower mosaic virus 35S:NEOMYCIN PHOSPHOTRANSFERASE II (Pro35S:NPTII) transgenes, we isolated an mbd7 (for methyl-CpG-binding domain protein7) mutant. The mbd7 mutation causes an inactivation of the Pro35S:NPTII transgene but does not affect the expression of the ProRD29A:LUC transgene. The silencing of the Pro35S:NPTII reporter gene is associated with DNA hypermethylation of the reporter gene. MBD7 interacts physically with REPRESSOR OF SILENCING5/INCREASED DNA METHYLATION2, a protein in the small heat shock protein family. MBD7 prefers to target the genomic loci with high densities of DNA methylation around chromocenters. The Gypsy-type long terminal repeat retrotransposons mainly distributed around chromocenters are most affected by mbd7 in all transposons. Our results suggest that MBD7 is required for active DNA demethylation and antisilencing of the genomic loci with high densities of DNA methylation in Arabidopsis.DNA methylation is an important epigenetic marker for genome stability and the regulation of gene expression in both plants and animals (Law and Jacobsen, 2010; He et al., 2011). In plants, the molecular mechanisms for DNA methylation have been well characterized by the use of powerful genetic screening systems (Bartee et al., 2001; Lindroth et al., 2001; Matzke et al., 2004; He et al., 2009). A transgene or an endogenous gene may be silenced because of DNA hypermethylation in the promoter region. Screenings for mutants with release of the silenced marker genes have identified many components that are involved in RNA-directed DNA methylation (RdDM) and in maintaining DNA methylation (Matzke and Birchler, 2005; Law and Jacobsen, 2009; He et al., 2011; Bender, 2012). DNA methylation is catalyzed by DNA methyltransferases including DNA METHYLTRANSFERASE1 (MET1) and CHROMOMETHYLASE3 (CMT3), which maintain symmetric CG and CHG methylation, respectively, during DNA replication, and DOMAINS REARRANGED METHYLASE2 (DRM2) and CMT2, which are required for establishing CHG and asymmetric CHH methylation during each cell cycle. DRM2 also catalyzes CG methylation (Law and Jacobsen, 2010; Haag and Pikaard, 2011; He et al., 2011; Zemach et al., 2013; Stroud et al., 2014). Twenty-four-nucleotide small RNAs produced through the RdDM pathway target genomic regions to guide the establishment of DNA methylation by DRM2 (Cao et al., 2003).DNA methylation can be actively removed by a subfamily of bifunctional DNA glycosylases/lyases including REPRESSOR OF SILENCING1 (ROS1; Gong et al., 2002) and its paralogs DEMETER and DEMETER-LIKE2/3 (Gehring et al., 2006; Ortega-Galisteo et al., 2008). DNA methylation can also be passively lost during DNA replication when DNA methylation cannot be maintained (Zhu, 2009). Promoter RESPONSIVE TO DEHYDRATION 29A:LUCIFERASE (ProRD29A:LUC) in the ProRD29A:LUC/Promoter cauliflower mosaic virus 35S:NEOMYCIN PHOSPHOTRANSFERASE II (Pro35S:NPTII) transgenic Arabidopsis (Arabidopsis thaliana) line has been used as a marker to identify ros1 and ros3 mutants in which both ProRD29A:LUC and Pro35S:NPTII are silenced (Gong et al., 2002; Zheng et al., 2008). ROS3 is an RNA-binding protein that facilitates the function of ROS1 in active DNA demethylation at certain genomic loci. Using Pro35S:NPTII as a selection marker for kanamycin-sensitive mutants and the 35S-SUC2 transgene or a chop PCR marker for assaying DNA methylation at the 3′ region of At1g26400 from transfer DNA (T-DNA) insertion mutants, researchers recently identified two genes involved in active DNA demethylation: ROS4/INCREASED DNA METHYLATION1 (IDM1) and ROS5/IDM2 (Li et al., 2012; Qian et al., 2012, 2014; Zhao et al., 2014). ROS4/IDM1 is a plant homeodomain-finger domain-containing histone acetyltransferase that catalyzes histone H3 lysine18 (H3K18) and lysine23 (H3K23) acetylation (Li et al., 2012; Qian et al., 2012). ROS5/IDM2 is a member of the small heat shock protein family that interacts physically with ROS4/IDM1 for the regulation of active DNA demethylation. Genetic analysis indicates that ROS1, ROS4/IDM1, and ROS5/IDM2 are in the same genetic pathway and that ROS4/IDM1 and ROS5/IDM2 may form a protein complex for the regulation of active DNA demethylation (Qian et al., 2014; Zhao et al., 2014).During the genetic screening for kanamycin-sensitive mutants using the ProRD29A:LUC/Pro35S:NPTII transgenic line in this study, we identified another mutant, mbd7, where the Pro35S:NPTII transgene is specifically silenced. MBD7 is a methyl-CpG-binding domain (MBD) protein containing three MBD motifs that bind in vitro to methylated symmetric CG sites. MBD7 localizes to all highly CpG-methylated chromocenters in vivo (Zemach and Grafi, 2003; Zemach et al., 2008). Recruitment of MBD7 to chromocenters is disrupted in decrease in DNA methylation1 (ddm1) and met1, two mutants with great reductions in DNA methylation, suggesting that DNA methylation is required for proper MBD7 localization (Zemach et al., 2005). In this study, we found that MBD7 interacts physically with ROS5/IDM2 and is required for the active DNA demethylation of certain genomic loci, especially for the Gypsy-type long terminal repeat (LTR) retrotransposons with high densities of DNA methylation around chromocenters in Arabidopsis. 相似文献
Effects of inorganic arsenicals on DNA synthesis in unsensitized human blood lymphocytes were biphasic: The chemicals at very low concentrations enhanced DNA synthesis, whereas higher concentrations inhibited DNA synthesis. The concentrations of arsenicals at which the maximum stimulating effect was found were 1×10?5M, 1×10?6 or 2×10?6M, and 0.8×10?6 or 1×10?6M for sodium arsenite exposure of 1 h, 3 d, and 6 d, respectively; for sodium arsenate, 1× 10?5M, 1×10?5M, and 2×10?6 or 5×10?6M, respectively. Arsenicals must be present for the entire 6-d culture period to produce maximum stimulation of DNA synthesis in human lymphocytes. The longer exposure of the lymphocytes to arsenicals, the lower the concentrations of arsenicals at which the maximum stimulating effect on DNA synthesis was found. Stimulating effect of trivalent arsenic (sodium arsenite) on DNA synthesis was stronger than pentavalent arsenic (sodium arsenate), and the stronger the effect of trivalent arsenic than pentavalent, the longer exposure of the cells to the chemicals. Both sodium arsenite and sodium arsenate stimulated DNA synthesis in human lymphocytes to a lower degree than phytohemagglutinin (PHA). 相似文献
DNA vaccines are a promising approach to vaccination since they circumvent the problem of vector-induced immunity. DNA plasmid cytokine adjuvants have been shown to augment immune responses in small animals and in macaques.
Methodology/Principal Findings
We performed two first in human HIV vaccine trials in the US, Brazil and Thailand of an RNA-optimized truncated HIV-1 gag gene (p37) DNA derived from strain HXB2 administered either alone or in combination with dose-escalation of IL-12 or IL-15 plasmid cytokine adjuvants. Vaccinations with both the HIV immunogen and cytokine adjuvant were generally well-tolerated and no significant vaccine-related adverse events were identified. A small number of subjects developed asymptomatic low titer antibodies to IL-12 or IL-15. Cellular immunogenicity following 3 and 4 vaccinations was poor, with response rates to gag of 4.9%/8.7% among vaccinees receiving gag DNA alone, 0%/11.5% among those receiving gag DNA+IL-15, and no responders among those receiving DNA+high dose (1500 ug) IL-12 DNA. However, after three doses, 44.4% (4/9) of vaccinees receiving gag DNA and intermediate dose (500 ug) of IL-12 DNA demonstrated a detectable cellular immune response.
Conclusions/Significance
This combination of HIV gag DNA with plasmid cytokine adjuvants was well tolerated. There were minimal responses to HIV gag DNA alone, and no apparent augmentation with either IL-12 or IL-15 plasmid cytokine adjuvants. Despite the promise of DNA vaccines, newer formulations or methods of delivery will be required to increase their immunogenicity.
To study double-strand break (DSB)-induced mutations in mammalian chromosomes, we stably transfected thymidine kinase (tk)-deficient mouse fibroblasts with a DNA substrate containing a recognition site for yeast endonuclease I-SceI embedded within a functional tk gene. Cells were then electroporated with a plasmid expressing endonuclease I-SceI to induce a DSB, and clones that had lost tk function were selected. In a previous study of DSB-induced tk-deficient clones, we found that ~8% of recovered tk mutations involved the capture of one or more DNA fragments at the DSB site. Almost half of the DNA capture events involved the I-SceI expression plasmid, and several events involved retrotransposable elements. To learn whether only certain DNA sequences or motifs are efficiently captured, in the current work we electroporated an I-SceI expression plasmid along with HaeIII fragments of X174 genomic DNA. We report that 18 out of 132 tk-deficient clones recovered had captured DNA fragments, and 14 DNA capture events involved one or more fragments of X174 DNA. Microhomology existed at most junctions between X174 DNA and genomic sequences. Our work suggests that virtually any extrachromosomal DNA molecule may be recruited for the patching of DSBs in a mammalian genome. 相似文献
A targeting method to insert genes at a previously characterized genetic locus to make plant transformation and transgene expression predictable is highly desirable for plant biotechnology. We report the successful targeting of transgenes to predefined soybean (Glycine max) genome sites using the yeast FLP-FRT recombination system. First, a target DNA containing a pair of incompatible FRT sites flanking a selection gene was introduced in soybean by standard biolistic transformation. Transgenic events containing a single copy of the target were retransformed with a donor DNA, which contained the same pair of FRT sites flanking a different selection gene, and a FLP expression DNA. Precise DNA cassette exchange was achieved between the target and donor DNA via recombinase-mediated cassette exchange, so that the donor DNA was introduced at the locus previously occupied by the target DNA. The introduced donor genes expressed normally and segregated according to Mendelian laws.Plant transformation has challenges such as random integration, multiple transgene copies, and unpredictable expression. Homologous recombination (Iida and Terada, 2005; Wright et al., 2005) and DNA recombinase-mediated site-specific integration (SSI) are promising technologies to address the challenges for placing a single copy of transgenes into a precharacterized site in a plant genome.Several site-specific DNA recombination systems, such as the bacteriophage Cre-lox and the yeast FLP-FRT and R-RS, have been used in SSI studies (Ow, 2002; Groth and Calos, 2003). A common feature of these systems is that each system consists of a recombinase Cre, FLP, or R and two identical or similar palindromic recognition sites, lox, FRT, or RS. Each recognition site contains a short asymmetric spacer sequence where DNA strand exchange takes place, flanked by inverted repeat sequences where the corresponding recombinase specifically binds. If two recognition sites are located in cis on a DNA molecule, the DNA segment can be excised if flanked by two directionally oriented sites or inverted if flanked by two oppositely oriented sites. If two recognition sites are located in trans on two different DNA molecules, a reciprocal translocation can happen between the two DNA molecules or the two molecules can integrate if at least one of them is a circular DNA (Ow, 2002; Groth and Calos, 2003).Single-site SSI can integrate a circular donor DNA containing one recognition site into a similar site previously placed in a plant genome. The integrated transgene now flanked by two recognition sites is vulnerable to excision. Transient Cre expression and the use of mutant lox sites to create two less compatible sites after integration helped reduce the subsequent excision in tobacco (Nicotiana tabacum; Albert et al., 1995; Day et al., 2000). A similar approach was used to produce SSI events in rice (Oryza sativa), and the transgene was proven stably expressed over generations (Srivastava and Ow, 2001; Srivastava et al., 2004; Chawla et al., 2006). Using a promoter trap to displace a cre gene in the genome with a selection gene from the donor, approximately 2% SSI was achieved in Arabidopsis (Arabidopsis thaliana; Vergunst et al., 1998).When two recognition sites located on a linear DNA molecule are similar enough to be recognized by the same recombinase but different enough to reduce or prevent DNA recombination from happening between them, the DNA segment between the two sites may not be easily excised or inverted. When a circular DNA molecule carrying the same two incompatible sites is introduced, the circular DNA can integrate by the corresponding recombinase at either site on the linear DNA to create a collinear DNA with four recognition sites, two from the original linear DNA and two from the circular DNA. DNA excision can subsequently occur between any pair of compatible sites to restore the two original DNA molecules or to exchange the intervening DNA segments between the two DNA molecules. This process, termed recombinase-mediated cassette exchange (RMCE), can be employed to integrate transgenes directionally into predefined genome sites (Trinh and Morrison, 2000; Baer and Bode, 2001).RMCE using two oppositely oriented identical RS sites, a donor containing the R recombinase gene and a third RS site to limit random integration, resulted in cassette exchange between the donor and a previously placed target in tobacco (Nanto et al., 2005). RMCE using both the Cre-lox and FLP-FRT systems improved RMCE frequency in animal cell cultures (Lauth et al., 2002). RMCE using two directly oriented incompatible FRT sites and transiently expressed FLP recombinase achieved cassette exchange between a target previously placed in the Drosophila genome and a donor introduced as a circular DNA (Horn and Handler, 2005). A gene conversion approach involving Cre-lox- and FLP-FRT-mediated SSI, RMCE, and homologous recombination was explored in maize (Zea mays; Djukanovic et al., 2006). RMCE using two oppositely oriented incompatible lox sites and transiently expressed Cre recombinase produced single-copy RMCE plants in Arabidopsis (Louwerse et al., 2007).To develop FLP-FRT-mediated RMCE in soybean (Glycine max), we created transgenic target lines containing a hygromycin resistance gene flanked by two directly oriented incompatible FRT sites via biolistic transformation. Single-copy target lines were selected and retransformed with a donor DNA containing a chlorsulfuron resistance gene flanked by the same pair of FRT sites. An FLP expression DNA was cobombarded to transiently provide FLP recombinase. RMCE events were obtained from multiple target lines and confirmed by extensive molecular characterization. 相似文献
Nucleotide excision repair (NER) removes a variety of DNA lesions. Using a yeast cell-free repair system, we have analyzed the repair synthesis step of NER. NER was proficient in yeast mutant cell-free extracts lacking DNA polymerases (Pol) β, ζ or η. Base excision repair was also proficient without Polβ. Repair synthesis of NER was not affected by thermal inactivation of the temperature-sensitive mutant Polα (pol1-17), but was reduced after thermal inactivation of the temperature-sensitive mutant Polδ (pol3-1) or Pol (pol2-18). Residual repair synthesis was observed in pol3-1 and pol2-18 mutant extracts, suggesting a repair deficiency rather than a complete repair defect. Deficient NER in pol3-1 and pol2-18 mutant extracts was specifically complemented by purified yeast Polδ and Pol, respectively. Deleting the polymerase catalytic domain of Pol (pol2-16) also led to a deficient repair synthesis during NER, which was complemented by purified yeast Pol, but not by purified yeast Polη. These results suggest that efficient repair synthesis of yeast NER requires both Polδ and Pol in vitro, and that the low fidelity Polη is not accessible to repair synthesis during NER. 相似文献
The persistence of naturally occurring campylobacteria in aerobic compost constructed of manure from beef cattle that were administered chlortetracycline and sulfamethazine (AS700) or from cattle not administered antibiotics (control) was examined. Although there were no differences in population sizes of heterotrophic bacteria, the temperature of AS700 compost was more variable and did not become as high as that of control compost. There were significant differences in water content, total carbon (C), total nitrogen (N), and electrical conductivity but not in the C/N ratio or pH between the two compost treatments. Campylobacteria were readily isolated from pen manure, for up to day 15 from control compost, and throughout the active phase of AS700 compost. Campylobacter DNA (including Campylobacter coli, Campylobacter fetus, Campylobacter hyointestinalis, and Campylobacter jejuni) was detected over the ca. 10-month composting period, and no reductions in quantities of C. jejuni DNA were observed over the duration of the active phase. The utilization of centrifugation in combination with ethidium monoazide (EMA) significantly reduced (>90%) the amplification of C. jejuni DNA that did not originate from cells with intact cell membranes. No differences were observed in the frequency of Campylobacter DNA detection between EMA- and non-EMA-treated samples, suggesting that Campylobacter DNA amplified from compost was extracted from cells with intact cell membranes (i.e., from viable cells). The findings of this study indicate that campylobacteria excreted in cattle feces persist for long periods in compost and call into question the common belief that these bacteria do not persist in manure.Campylobacter jejuni and, to a lesser extent, Campylobacter coli incite serious acute and chronic afflictions. Enteritis caused by C. jejuni (i.e., campylobacteriosis) is the most common cause of bacterial enteritis in Canada (http://dsol-smed.phac-aspc.gc.ca/dsol-smed/ndis/index-eng.php). Although the epidemiology of campylobacteriosis is poorly understood, sporadic outbreaks of campylobacteriosis involving contaminated water have occurred when water treatment has failed. The most serious outbreak in Canada occurred in Walkerton Ontario in 2000; more than 2,300 people became infected with waterborne Escherichia coli O157:H7 and/or C. jejuni originating from cattle feces (3). Alberta, Canada, possesses a very large beef cattle population (≈6 million animals) primarily concentrated in the southern region of the province, and ≈2 million of these animals are in finishing feedlots (1). Large quantities of manure are produced by feedlot cattle. For example, in the Chinook Health Region of Southwestern Alberta in which Lethbridge is situated, there are ≈700,000 cattle in feedlots at any given time, producing ≈12 million kg of manure (fresh weight) per day. Several Campylobacter species, including C. jejuni and C. coli, are frequently shed in beef cattle feces in large numbers (15, 16). Although the impact of cattle-borne campylobacters on human health has not been definitely determined, the southern region of Alberta possesses one of the highest rates of campylobacteriosis in Canada among its human inhabitants, concomitant with the very high density of cattle in this region.Large-scale windrow composting of bovine manure from intensive cattle operations is practiced by some Alberta feedlots. Composting is an aerobic process in which organic matter in manure is stabilized into a humus-like product (30). The process results in water loss and mass reduction, nutrient transformation (22), alteration of physical structure (23), elimination of weed seeds (21), and the inactivation of coliform bacteria (25), protozoan cysts and oocysts (34), and viruses (39). Limited research has investigated the impact of manure management systems, such as aerobic composting, on deactivation of campylobacters. Furthermore, the impact of antimicrobial agents excreted into the manure on the efficacy of the composting process on Campylobacter deactivation has not been investigated. Most studies conducted to date have indicated that campylobacters do not persist well in solid manure once excreted (7, 11, 12, 26, 32, 39). Although it is difficult to isolate or enumerate Campylobacter species within microbiologically complex substrates, molecular detection and/or quantification methods have not been extensively applied to study the persistence of campylobacteria. Furthermore, the persistence of naturally shed campylobacteria has largely been overlooked. Thus, the overall objective of the current study was to measure the ability of campylobacteria naturally shed in bovine feces to persist in manure compost using a combination of culture- and culture-independent methods. Specific objectives were (i) to develop and utilize a centrifugation method to facilitate isolation and detection of DNA from Campylobacter species in bovine manure compost, (ii) to apply qualitative and quantitative PCR methods to evaluate persistence of campylobacteria in compost, (iii) to validate the molecular methods used to amplify DNA from viable cells, and (iv) to contrast the persistence of Campylobacter species in composted manure obtained from beef cattle maintained on a diet supplemented with chlortetracycline and sulfamethazine (AS700) with composted manure from animals not administered antimicrobial agents. 相似文献
The mobilization proteins of the broad-host-range plasmid R1162 can initiate conjugative transfer of a plasmid from a 19-bp locus that is partially degenerate in sequence. Such loci are likely to appear by chance in the bacterial chromosome and could act as cryptic sites for transfer of chromosomal DNA when R1162 is present. The R1162-dependent transfer of chromosomal DNA, initiated from one such potential site in Pectobacterium atrosepticum, is shown here. A second active site was identified in Escherichia coli, where it is also shown that large amounts of DNA are transferred. This transfer probably reflects the combined activity of the multiple cryptic origins in the chromosome. Transfer of chromosomal DNA due to the presence of a plasmid in the cytoplasm describes a previously unrecognized potential for the exchange of bacterial DNA.The discovery over 50 years ago of bacterial mating by Lederberg and Cavalli-Sforza (summarized by Cavalli-Sforza [10]) was a major step in the development of modern microbial genetics. It was later realized that chromosomal DNA transfer was due to the integration of a plasmid, the F factor. This plasmid is able to effect its own transfer and, in the integrated state, chromosomal DNA as well. A unique site on the plasmid, the origin of transfer (oriT), is essential for this process. A complex of plasmid- and host-encoded proteins assemble at oriT (15); the F-encoded relaxase then cleaves one of the DNA strands, forming a covalent, protein-DNA intermediate (27) that is delivered to the type IV secretion apparatus, also encoded by F (24). The possibility of low-level transfer initiating from chromosomal sites was raised early in the history of conjugation (12). However, it is now clear that the exacting architecture of the oriT DNA-protein complex, both for the F factor and related oriTs, results in a very high degree of sequence and structural specificity, and no secondary origins in the chromosome have been identified.The broad-host-range plasmid R1162 (RSF1010), like the F factor, is also transferred from cell to cell. Although the mechanism of transfer is similar for the two plasmids, the oriTs are structurally very different. In prior studies we have determined that the R1162 oriT is small, structurally simple, and able to accommodate base changes at different positions without a complete loss of function (5, 21). As a result of this relaxed specificity, the R1162 mobilization (Mob) proteins can activate the related but different oriT of another plasmid, pSC101 (28).The R1162 oriT is shown in Fig. Fig.1.1. The R1162 relaxase MobA interacts with the core region, highly conserved in the R1162 Mob family (5), and the adjacent, inner arm of the inverted repeat (23). The protein forms at nic a tyrosyl phosphodiester linkage with the 5′ end of the DNA strand (30), which is then unwound from its complement as the protein-DNA complex is passed into the recipient cell. Circular plasmid DNA is reformed by a reverse of the initial protein-DNA transesterification, with the relaxase now binding to the 3′ end of the transferred DNA. This binding requires the complete inverted repeat, which probably forms a hairpin loop to recreate the double-stranded character of the relaxase binding site on duplex DNA.Open in a separate windowFIG. 1.Base sequence of R1162 oriT on the nicked strand. The relaxase cleaves at nic; subsequent transfer is 5′ to 3′ so that most of oriT is transferred last. Below is the consensus sequence of DNA active for initiation of transfer.An important feature of the steps in DNA processing at the R1162 oriT is that an inverted repeat is not required for the initiation of transfer or passage of DNA into a new cell. As a result of this and the permissiveness of the relaxase to base changes within oriT, different sites in the chromosome that are not part of a plasmid oriT might nevertheless be capable of initiating transfer when cloned into a plasmid. We previously identified one such site in the chromosome of Erwinia carotovora subsp. atroseptica (now Pectobacterium atrosepticum) (21). In addition, by testing libraries of oriTs with one or more mutations for relaxase-induced nicking, we found that a large population of DNAs with different sequences was potentially active (21). The consensus sequence for activity, derived from these studies, is shown in Fig. Fig.11.I show here that ectopic sites on the bacterial chromosome, active for the initiation of transfer of plasmid DNA, can also serve for the transfer of chromosomal DNA when the Mob proteins are provided in trans. Thus, the presence of R1162 in the cell can result in a cryptic sexuality in bacteria, resulting in the transfer of chromosomal genes. Although such events are likely to be infrequent, the broad-host-range of R1162 and its close relatives, with their ability to reside stably in the cytoplasms of many different bacteria, could be another source of gene exchange for a variety of different species. 相似文献
The formation of heteroduplex DNA is a central step in the exchange of DNA sequences via homologous recombination, and in the accurate repair of broken chromosomes via homology-directed repair pathways. In cells, heteroduplex DNA largely arises through the activities of recombination proteins that promote DNA-pairing and annealing reactions. Classes of proteins involved in pairing and annealing include RecA-family DNA-pairing proteins, single-stranded DNA (ssDNA)-binding proteins, recombination mediator proteins, annealing proteins, and nucleases. This review explores the properties of these pairing and annealing proteins, and highlights their roles in complex recombination processes including the double Holliday junction (DhJ) formation, synthesis-dependent strand annealing, and single-strand annealing pathways—DNA transactions that are critical both for genome stability in individual organisms and for the evolution of species.A central step in the process of homologous recombination is the formation of heteroduplex DNA. In this article, heteroduplex DNA is defined as double-stranded DNA that arose from recombination, in which the two strands are derived from different parental DNA molecules or regions. The two strands of the heteroduplex may be fully complementary in sequence, or may contain small regions of noncomplementarity embedded within their otherwise complementary sequences. In either case, Watson-Crick base pairs must stabilize the heteroduplex to the extent that it can exist as free DNA following the dissociation of the recombination proteins that promoted its formation.The ability to form heteroduplex DNA using strands from two different parental DNA molecules lies at the heart of fundamental biological processes that control genome stability in individual organisms, inheritance of genetic information by their progeny, and genetic diversity within the resulting populations (Amunugama and Fishel 2012). During meiosis, the formation of heteroduplex DNA facilitates crossing-over and allelic exchange between homologous chromosomes; this process ensures that progeny are not identical clones of their parents and that sexual reproduction between individuals will result in a genetically diverse population (see Lam and Keeney 2015; Zickler and Kleckner 2015). Heteroduplex DNA generated by meiotic COs also ensures proper segregation of homologous chromosomes, so that each gamete receives a complete but genetically distinct set of chromosomes (Bascom-Slack et al. 1997; Gerton and Hawley 2005). In mitotic cells, heteroduplex DNA formation between sister chromatids is essential for homology-directed repair (HR) of DNA double-strand breaks (DSBs), stalled replication forks, and other lesions (Maher et al. 2011; Amunugama and Fishel 2012; Mehta and Haber 2014). Prokaryotic organisms also generate heteroduplex DNA to perform HR transactions, and to promote genetic exchanges, such as occur during bacterial conjugation (Cox 1999; Thomas and Nielsen 2005).Fundamentally, heteroduplex DNA generation involves the formation of tracts of Watson-Crick base pairs between strands of DNA derived from two different progenitor (parental) DNA molecules. Mechanistically, the DNA transactions giving rise to heteroduplex may involve two, three, or four strands of DNA (Fig. 1). DNA annealing refers to heteroduplex formation from two complementary (or nearly complementary) molecules or regions of single-stranded DNA (ssDNA) (Fig. 1A). DNA annealing may occur spontaneously, but it is promoted in vivo by certain classes of annealing proteins. Three-stranded reactions yielding heteroduplex DNA proceed by a different mechanism referred to as DNA pairing, strand invasion, or strand exchange. These reactions involve the invasion of a duplex DNA molecule by homologous (or nearly homologous) ssDNA. The invading DNA may be completely single stranded, as is often the case in in vitro assays for DNA-pairing activity (Fig. 1B) (Cox and Lehman 1981). Under physiological conditions, however, the invading ssDNA is contained as a single-stranded tail or gap within a duplex (Fig. 1C,D). DNA-pairing reactions are promoted by DNA-pairing proteins of the RecA family (Bianco et al. 1998), and proceed via the formation of D-loop or joint molecule intermediates that contain the heteroduplex DNA (Fig. 1B–D). Three-stranded reactions may also be promoted by exonuclease/annealing protein complexes found in certain viruses. Four-stranded reactions generating heteroduplex DNA involve branch migration of a Holliday junction (Fig. 1D). In practice, a four-stranded reaction must be initiated by a three-stranded pairing reaction catalyzed by a DNA-pairing protein, after which the heteroduplex is extended into duplex regions through the action of the DNA-pairing protein or of an associated DNA helicase/translocase (Das Gupta et al. 1981; Kim et al. 1992; Tsaneva et al. 1992).Open in a separate windowFigure 1.Common DNA annealing and pairing reactions. (A) Simple annealing between two complementary molecules of single-stranded DNA to form a heteroduplex. (B) Three-stranded DNA-pairing reaction of the type used for in vitro assays of RecA-family DNA-pairing proteins. The single-stranded circle is homologous to the linear duplex. Formation of heteroduplex (red strand base-paired to black) requires protein-promoted invasion of the duplex by the ssDNA to form a joint molecule or D-loop (i). The length of the heteroduplex may be extended by branch migration (ii). (C) Three-stranded DNA-pairing reaction of the type used for high-fidelity repair of DNA DSBs in vivo. The invading strand is the ssDNA tail of a resected DSB. The 3′ end of the invading strand is incorporated into the heteroduplex within the D-loop intermediate. (D) Example of a four-stranded DNA-pairing transaction that is initiated by a three-stranded pairing event and extended by branch migration. The ssDNA in a gapped duplex serves as the invading strand to generate a joint molecule (i), reminiscent of the reaction shown in panel B. Protein-directed branch migration may proceed into the duplex region adjacent to the original gap, generating α-structure intermediates (ii), or eventually a complete exchange of strands (iii). 相似文献
Earlier, we discovered that, along with linear DNA fragments, nano- and microparticles of DNA and their aggregates are formed in the PCR with yeast genomic DNA used as a template and gene-specific or partially complementary primers. The size of the microparticles (microspheres) varied in the range of 0.5 to 3–4 μm. Only thermostable KlenTaq polymerase but not Taq polymerase could effectively generate microspheres. In this work, we demonstrate that KlenTaq polymerase can produce microspheres of variable size (1 to 7 μm in diameter) if genomic DNA of the bacterium Acidithiobacillus ferrooxidans and partially complementary primers are present in the PCR mixture. Conditions for generation of DNA microparticles in PCR with Taq-polymerase and bacterial genomic DNA as template were also elaborated. It was also found that mainly large microspheres of up to 7 μm accumulated in PCR with plasmid DNAs used as templates and gene-specific primers in the presence of KlenTaq polymerase or mixtures of KlenTaq and Pfu polymerases. Besides, small aggregates, as well as linear branched structures and three-dimensional conglomerates of fused microspheres, were also revealed in the PCR mixtures. UV absorption spectra of native DNA microspheres and microspheres that had undergone heating at 93°C were registered. The key role of Mg2+ cations in the formation and stabilization of the microsphere structure was established. 相似文献
Endosymbiotic bacteria were identified in the parasitic ciliate Ichthyophthirius multifiliis, a common pathogen of freshwater fish. PCR amplification of DNA prepared from two isolates of I. multifiliis, using primers that bind conserved sequences in bacterial 16S rRNA genes, generated an ∼1,460-bp DNA product, which was cloned and sequenced. Sequence analysis demonstrated that 16S rRNA gene sequences from three classes of bacteria were present in the PCR product. These included Alphaproteobacteria (Rickettsiales), Sphingobacteria, and Flavobacterium columnare. DAPI (4′,6-diamidino-2-phenylindole) staining showed endosymbionts dispersed throughout the cytoplasm of trophonts and, in most, but not all theronts. Endosymbionts were observed by transmission electron microscopy in the cytoplasm, surrounded by a prominent, electron-translucent halo characteristic of Rickettsia. Fluorescence in situ hybridization demonstrated that bacteria from the Rickettsiales and Sphingobacteriales classes are endosymbionts of I. multifiliis, found in the cytoplasm, but not in the macronucleus or micronucleus. In contrast, F. columnare was not detected by fluorescence in situ hybridization. It likely adheres to I. multifiliis through association with cilia. The role that endosymbiotic bacteria play in the life history of I. multifiliis is not known.The ciliate Ichthyophthirius multifiliis is an obligate parasite of freshwater fish that infects epithelia of the skin and gills. The life cycle of I. multifiliis consists of three stages: an infective theront, a parasitic trophont, and a reproductive tomont. Infection is initiated by invasion of the skin and gills by free-swimming, 40-μm-long, pyriform-shaped theronts that burrow several cell layers deep into epithelial tissue of the skin and gills and rapidly differentiate into trophonts. Trophonts feed on epithelial cells and grow into 500- to 800-μm-diameter cells, causing extensive damage to skin and gills, which in severe infections results in mortality (10-12). After feeding for 5 to 7 days, trophonts leave the host, form encysted tomonts, and undergo up to 10 cell divisions over 18 to 24 h, producing as many as 103 daughter cells, which exit the cyst as infective theronts to reinitiate the life cycle. I. multifiliis is ciliated at all stages (9).DNA sequencing of the I. multifiliis genome at the J. Craig Venter Institute unexpectedly revealed that bacterial DNA sequences, including sequences with homology to Rickettsia, were present in the DNA preparations (R. S. Coyne, 2009 [http://www.jcvi.org/cms/research/projects/ich/overview]). The origin of these sequences was unclear, but they represented evidence for either horizontal gene transfer into the I. multifiliis genome (17, 27) or the presence of intracellular bacteria. No previous evidence suggested the presence of intracellular bacteria in I. multifiliis, even though the fine structure of I. multifiliis theronts and trophonts has been examined by transmission electron microscopy (10-12). Intracellular or endosymbiotic bacteria, however, are commonly found in protists, and about 200 ciliate species are known to harbor intracellular bacteria (13, 15). Sonneborn and Preer in their classic studies on endosymbionts in Paramecium characterized a number of different endosymbionts, including “killers,” named for their ability to kill uninfected strains of Paramecium. Cytoplasmic endosymbionts in Paramecium now include Caedibacter taeniospiralis (Gammaproteobacteria), and Pseudocaedibacter conjugates, Tectibacter vulgaris, and Lyticum flagellatum (Alphaproteobacteria). Macronuclear endosymbionts include the Alphaproteobacteria, Holospora caryophila, and Caedibacter caryophila, which can also infect the cytoplasm (4, 16, 22, 26). The roles these endosymbionts play in protists are not well understood.The presence of sequences with homology to bacterial genomes prompted us to determine if I. multifiliis contained endosymbionts, or if these sequences represented evidence for horizontal gene transfer into the I. multifiliis genome. Our identification of the same two endosymbionts, in two different isolates of I. multifiliis, suggests that endosymbionts are common in I. multifiliis. However, the physiological relationships between I. multifiliis and its resident endosymbionts are unclear. It is not known if the endosymbionts contribute to the growth of I. multifiliis, if they contribute to the severity or pathogenicity of infection, or if they provide their host with any selective advantage, as occurs with Paramecium containing killer particles (4). It has not been determined if they influence the immune response of fish infected with I. multifiliis. It is possible that they may simply be parasites of this parasitic ciliate. 相似文献
Highlights► Individual DNA molecules hundreds of kbp long may be stretched and visualized by optical microscopy. ► An optical barcode is generated by fluorescent labeling of short sequence motifs along the stretched DNA. ► Optical maps complement DNA sequencing for gap closing, finishing, validation and de novo assembly of genomes. ► Genome structural variations not accessible to sequencing or DNA arrays may be directly visualized. ► Epigenetic marks such as DNA methylation and DNA binding proteins may also be mapped on single genomic fragments. 相似文献
A restriction endonuclease, SalI, has been partially purified from Streptomyces albus G. This enzyme cleaves adenovirus-2 DNA at three sites, bacteriophage λ DNA at two sites, but does not cleave simian virus 40 DNA or φX174 DNA. It recognizes the sequence and cuts at the sites indicated by the arrows. An endonuclease (XamI) with similar specificity has also been isolated from Xanthomonas amaranthicola. 相似文献
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