Transformation in pneumococcus: protein content of eclipse complex.

A two-step purification of pneumococcal eclipse complex is described, which uses sucrose gradient sedimentation followed by agarose gel permeation chromatography. Purified complex contains, in addition to donor DNA single strands, macromolecular material that can be labeled with methionine or leucine during development of competence. This material co-chromatographed with eclipse complex DNA on hydroxylapatite, was dissociated from the DNA by sodium dodecyl sulfate, and was completely digested by Pronase. The sodium dodecyl sulfate-released material eluted as a single peak in sodium dodecyl sulfate chromatography. These properties were consistent with the noncovalent association with eclipse complex of a protein or class of proteins with a narrow range of polypeptide sizes. Evidence for the specific association of this protein with transforming DNA is eclipse was also obtained from parallel purification from 35S-labeled nontransformed cells; the amount of methionine label in the corresponding fractions in such cells was only 5% of that in transformed cells.     

Transformation in pneumococcus: existence and properties of a complex involving donor deoxyribonucleate single strands in eclipse.

Donor deoxyribonucleic acid (DNA) single strands exist in a complex during the eclipse phase in pneumococcal transformation. This eclipse complex exhibited specific physical properties distinct from those of both pure DNA single strands and native DNA. These included a lower affinity for diethylaminoethyl-cellulose and hydroxylapatite than that of single-strand DNA, faster sedimentation than the DNA chains that it contains, and a buoyant density in Cs2SO4 lower than that of native DNA. The complex was dissociated by treatments with sodium dodecyl sulfate, NaOH, guanidine-hydrochloride, chloroform, and proteinase K but was insensitive to ribonuclease.     

Transformation in Streptococcus pneumoniae: formation of eclipse complex in a coiA mutant implicates CoiA in genetic recombination

CoiA is a transient protein expressed specifically during competence and required for genetic transformation in Streptococcus pneumoniae, but not for DNA uptake. It is widely conserved among Gram-positive bacteria but its function is unknown. Here we report that although the rate of DNA uptake was not affected in a coiA mutant, the internalized donor DNA did not recombine into the host chromosome to form a physical and genetic heteroduplex. Instead, DNA taken up by a coiA mutant accumulated in the form of a single-stranded (ss) DNA-protein complex indistinguishable from the eclipse complex formed as a recombination intermediate in wild-type competent cells. Internalized donor DNA in a dprA mutant did not accumulate either as ss DNA or as an eclipse complex. Together, these results establish that a coiA mutant exhibits a phenotype different from that of dprA or recA mutants, and that CoiA functions at a later step in promoting recombination during genetic transformation in Streptococcus pneumoniae.     

Recovery of Donor Deoxyribonucleic Acid Marker Activity from Eclipse in Pneumococcal Transformation

After the uptake of deoxyribonucleic acid (DNA), donor marker-transforming activity is temporarily lost. Restoration of the activity by annealing in vitro supports the idea that donor DNA is single-stranded at this stage. Kinetics of in vivo recovery from eclipse were examined for various markers at three temperatures. Sigmoidal recovery curves at lower temperatures indicate that the process consists of several steps. Rate of recovery was found to depend on the nature of the donor marker. Single-site markers recover much more rapidly than multisite markers corresponding to recipient deletions. Single-site markers vary somewhat in recovery rate, with rapidity of recovery inversely related to integration efficiency. Appearance of a recombinant-transforming activity lags only slightly behind recovery of its constituent donor marker.     

Fate of transforming DNA following uptake by competent Bacillus subtilis. I. Formation and properties of the donor-recipient complex

Following uptake by competent Bacillus subtilis, transforming DNA is converted to two distinct slowly sedimenting molecular forms which possess little transforming activity (eclipse). A few minutes after uptake is initiated, a physical complex of donor and recipient DNA begins to form. The recovery of donor transforming activity following eclipse, and the appearance of recombinant activity, previously reported by Venema, Pritchard &; Venema-Schröder (1965), is shown to be due to changes occurring in the donor—recipient complex. This complex exists transiently in a form with low recombinant-type transforming activity. This transient form may be one in which the donor and recipient components are joined non-covalently. The donor-recipient complex is shown to be a heteroduplex structure in which the donor moiety has an approximate molecular weight of 750,000.     

Identification of the major protein component of the pneumococcal eclipse complex

During genetic transformation of Streptococcus pneumoniae, single strands from native donor DNA enter competent cells, where they associate with an unidentified protein with a molecular mass of 15 to 20 kDa to form the eclipse complex. Using Western blotting, we identify the principal protein cofractionating with donor DNA in this complex as SsbB.     

Eclipse kinetics as a probe of quaternary structure in bacteriophage phi X174

The extracellular form of bacteriophage phi X174 consists of single-stranded DNA within an icosahedral capsid, which has short spikes at each of its vertices. Each spike is composed of gene G and H proteins, while the capsid itself consists of gene F protein. Since several molecules of gene H protein are injected into the cell along with the DNA, specific protein--protein and DNA--protein interactions must be broken when the genome exits and leaves an intact capsid structure at the receptor site. To demonstrate this we examined the eclipse (DNA ejection) reaction with two types of phi X174 mutants. The first contains missense mutations in a capsid or spike protein gene, and the second involves insertions or deletions in non-coding regions of the DNA. Using an improved procedure, the eclipse rate in vivo of the eclipse mutants Fcs70 has been redetermined over a larger temperature range than in previous studies. The three- to fivefold decrease in rate between 37 degrees C and 25 degrees C is due to an increase in both the enthalpy and entropy of activation when compared to the wild-type values of these kinetic parameters. This missence mutation also confers an increase in virus stability in 2 to 3 M-urea. In contrast to this, inserting 163 bases into the length of DNA packaged within the phi X174 capsid does not lead to a detectable change in eclipse rate over the same temperature range. yet this insertion into the J--F intercistronic region imparts a significant decrease in virus stability in urea. These results suggest that a specific set of non-covalent interactions is involved in phi X174 DNA ejection. This is supported by the small (50%), but significant, increase in eclipse rate that occurs when 27 bases are deleted from the J--F intercistronic region. The latter effect must be base-sequence-specific since no change in rate is observed when only seven of the 27 bases are deleted. Thus, the kinetics of the phi X174 eclipse reaction can be used as a sensitive probe of quaternary structure by correlating the change in reaction rate with alterations in amino acid and base sequences in the structural components of the virus.     

日偏食对乌鲁木齐空气可培养细菌群落的影响

利用自然沉降法采集2009年7月19日至24日日偏食前后乌鲁木齐空气微生物,以可培养法分析日偏食对其细菌群落组成的影响。结果如下：（1）细菌数量和种类均随日偏食临近而增多,当天达到峰值,随后减少。（2）所获81株细菌经测序及系统发育分析将其归为四个门,分别为放线菌门(Actinobacteria)、厚壁菌门(Firmicutes)、变形菌门(Proteobacteria)和拟杆菌门(Bacteroidetes),其中放线菌门为优势类群,占细菌总数的54%。（3）不同采样时间细菌群落组成的聚类分析显示,日偏食发生前日（21日）和当日（22日）空气细菌组成较为相似聚为一类,其余日期的聚为一类。（4）典型相关分析(Canonical Correlation Analysis, CCA)发现,放线菌门中菌株与绝大多数大气环境因子呈正相关性;变形菌门和厚壁菌门与大多数大气环境因子呈正相关性;而拟杆菌门中的菌株只与温度、风速和太阳风速度呈正相关。结果表明,日偏食会增加乌鲁木齐空气可培养细菌的数量和种类。     

Retroviral DNA integration: reaction pathway and critical intermediates

The key DNA cutting and joining steps of retroviral DNA integration are carried out by the viral integrase protein. Structures of the individual domains of integrase have been determined, but their organization in the active complex with viral DNA is unknown. We show that HIV-1 integrase forms stable synaptic complexes in which a tetramer of integrase is stably associated with a pair of viral DNA ends. The viral DNA is processed within these complexes, which go on to capture the target DNA and integrate the viral DNA ends. The joining of the two viral DNA ends to target DNA occurs sequentially, with a stable intermediate complex in which only one DNA end is joined. The integration product also remains stably associated with integrase and likely requires disassembly before completion of the integration process by cellular enzymes. The results define the series of stable nucleoprotein complexes that mediate retroviral DNA integration.     

Intracellular Uncoating of Type 5 Adenovirus Deoxyribonucleic Acid

Highly purified, (32)P-labeled type 5 adenovirus was employed to study "uncoating" of viral deoxyribonucleic acid (DNA)-defined as the development of sensitivity to deoxyribonuclease. Viral infectivity and radioactivity adsorbed to KB cells at the same rate, and significant amounts of (32)P did not elute from cells throughout the eclipse period. Kinetic studies of viral penetration, eclipse of infectivity, and uncoating of viral DNA indicated that the three events were closely related temporally, that the rates of each were similar, and that they were completed within 60 to 90 min after infection. Viral penetration, eclipse, and uncoating proceeded normally under conditions which blocked protein synthesis, but they did not occur at 0 to 4 C. Neither viral DNA nor viral protein was degraded to acid-soluble material during the eclipse period. The nature of adenovirus DNA was studied after it was converted intracellularly from deoxyribonuclease-resistant to deoxyribonuclease-susceptible. Intact virions centrifuged in sucrose gradients had a sedimentation coefficient of approximately 800, and viral DNA sedimented as a particle of about 30S. Infection of KB cells with purified (32)P-labeled virus yielded deoxyribonuclease-susceptible viral nucleic acid which was in particles with sedimentation coefficients of 350 to 450S, i.e., greater than 10 times faster than DNA obtained from purified virions which had been disrupted by exposure to pH 10.5. When the DNA from disrupted virions was mixed with cell lysates, its sedimentation characteristics were essentially unchanged by the presence of cellular material.     

A biological assay for intracellular SPP1 DNA

Summary Transfection with marker rescue techniques provides a sensitive assay for the DNA of phage SPP1. The method was used in a study of the process of replication of this phage. The data show that early during the eclipse, SPP1 DNA increases exponentially, suggesting a geometric mode of replication. DNA replication ceases at the time of the appearance of the first intracellular phage particles.     

The eclipse period of Escherichia coli

The minimal time between successive initiations on the same origin (the eclipse) in Escherichia coli was determined to be approximately 25-30 min. An inverse relationship was found between the length of the eclipse and the amount of Dam methyltransferase in the cell, indicating that the eclipse corresponds to the period of origin hemimethylation. The SeqA protein was absolutely required for the eclipse, and DnaA titration studies suggested that the SeqA protein prevented the binding of multiple DnaA molecules on oriC (initial complex formation). No correlation between the amount of SeqA and eclipse length was revealed, but increased SeqA levels affected chromosome partitioning and/or cell division. This was corroborated further by an aberrant nucleoid distribution in SeqA-deficient cells. We suggest that the SeqA protein's role in maintaining the eclipse is tied to a function in chromosome organization.     

Asymmetric replication in vitro from a human sequence element is dependent on adeno-associated virus Rep protein.

The DNA of human parvovirus adeno-associated virus type 2 (AAV) integrates preferentially into a defined region of human chromosome 19. Southern blots of genomic DNA from latently infected cell lines revealed that the provirus was not simply inserted into the cellular DNA. Both the proviral and adjoining cellular DNA organization indicated that integration occurred by a complex, coordinated process involving limited DNA replication and rearrangements. However, the mechanism for targeted integration has remained obscure. The two larger nonstructural proteins (Rep68 and Rep78) of AAV bind to a sequence element that is present in both the integration locus (P1) and the AAV inverted terminal repeat. This binding may be important for targeted integration. To investigate the mechanism of targeted integration, we tested the cloned integration site subfragment in a cell-free replication assay in the presence or absence of recombinant Rep proteins. Extensive, asymmetric replication of linear or open-circular template DNA was dependent on the presence of P1 sequence and Rep protein. The activities of Rep on the cloned P1 element are analogous to activities on the AAV inverted terminal repeat. Replication apparently initiates from a 3'-OH generated by the sequence-specific nicking activity of Rep. This results in a covalent attachment between Rep and the 5'-thymidine of the nick. The complexity of proviral structures can be explained by the participation of limited DNA replication facilitated by Rep during integration.     

Retroviral DNA Integration

DNA integration is a unique enzymatic process shared by all retroviruses and retrotransposons. During integration, double-stranded linear viral DNA is inserted into the host genome in a process catalyzed by the virus-encoded integrase (IN). The mechanism involves a series of nucleophillic attacks, the first of which removes the terminal 2 bases from the 3′ ends of the long terminal repeats and of the second which inserts the viral DNA into the host genome. IN specifically recognizes the DNA sequences at the termini of the viral DNA, juxtaposing both ends in an enzyme complex that inserts the viral DNA into a single site in a concerted manner. Small duplications of the host DNA, characteristic of the viral IN, are found at the sites of insertion. At least two host proteins, HMG-I(Y) and BAF, have been shown to increase the efficiency of the integration reaction.     

Functional coupling between HIV-1 integrase and the SWI/SNF chromatin remodeling complex for efficient in vitro integration into stable nucleosomes

Establishment of stable HIV-1 infection requires the efficient integration of the retroviral genome into the host DNA. The molecular mechanism underlying the control of this process by the chromatin structure has not yet been elucidated. We show here that stably associated nucleosomes strongly inhibit in vitro two viral-end integration by decreasing the accessibility of DNA to integrase. Remodeling of the chromatinized template by the SWI/SNF complex, whose INI1 major component interacts with IN, restores and redirects the full-site integration into the stable nucleosome region. These effects are not observed after remodeling by other human remodeling factors such as SNF2H or BRG1 lacking the integrase binding protein INI1. This suggests that the restoration process depends on the direct interaction between IN and the whole SWI/SNF complex, supporting a functional coupling between the remodeling and integration complexes. Furthermore, in silico comparison between more than 40,000 non-redundant cellular integration sites selected from literature and nucleosome occupancy predictions also supports that HIV-1 integration is promoted in the genomic region of weaker intrinsic nucleosome density in the infected cell. Our data indicate that some chromatin structures can be refractory for integration and that coupling between nucleosome remodeling and HIV-1 integration is required to overcome this natural barrier.     

T-DNA转移研究进展

植物遗传转化技术近年在农作物性状改良、植物生物反应器利用以及基因功能鉴定等方面得到了广泛的应用.T-DNA转移是植物细胞农杆菌介导遗传转化整合和表达外源基因的基础.农杆菌Ti质粒vir基因编码蛋白、农杆菌一些染色体基因编码蛋白及植物细胞一些基因编码蛋白或因子均参与T-DNA转移.转移过程包括农杆菌对植物细胞的识别、附着,细菌对植物信号物质的感受,细菌vir基因的诱导表达,T复合体的形成,跨膜运输,进核运输和整合等一序列过程.植物细胞因子与农杆菌T-DNA转移相关蛋白的相互作用最近被认为在T-DNA转移过程中起重要作用.     

HIV-1 integrase strand transfer inhibitors stabilize an integrase-single blunt-ended DNA complex

Integration of human immunodeficiency virus cDNA ends by integrase (IN) into host chromosomes involves a concerted integration mechanism. IN juxtaposes two DNA blunt ends to form the synaptic complex, which is the intermediate in the concerted integration pathway. The synaptic complex is inactivated by strand transfer inhibitors (STI) with IC₅₀ values of ∼ 20 nM for inhibition of concerted integration. We detected a new nucleoprotein complex on a native agarose gel that was produced in the presence of > 200 nM STI, termed the IN-single DNA (ISD) complex. Two IN dimers appear to bind in a parallel fashion at the DNA terminus, producing an ∼ 32-bp DNase I protective footprint. In the presence of raltegravir (RAL), MK-2048, and L-841,411, IN incorporated ∼ 20-25% of the input blunt-ended DNA substrate into the stabilized ISD complex. Seven other STI also produced the ISD complex (≤ 5% of input DNA). The formation of the ISD complex was not dependent on 3′OH processing, and the DNA was predominantly blunt ended in the complex. The RAL-resistant IN mutant N155H weakly forms the ISD complex in the presence of RAL at ∼ 25% level of wild-type IN. In contrast, MK-2048 and L-841,411 produced ∼ 3-fold to 5-fold more ISD than RAL with N155H IN, which is susceptible to these two inhibitors. The results suggest that STI are slow-binding inhibitors and that the potency to form and stabilize the ISD complex is not always related to inhibition of concerted integration. Rather, the apparent binding and dissociation properties of each STI influenced the production of the ISD complex.     

Site-specific gene integration in rice genome mediated by the FLP-FRT recombination system

Plant transformation based on random integration of foreign DNA often generates complex integration structures. Precision in the integration process is necessary to ensure the formation of full-length, single-copy integration. Site-specific recombination systems are versatile tools for precise genomic manipulations such as DNA excision, inversion or integration. The yeast FLP-FRT recombination system has been widely used for DNA excision in higher plants. Here, we report the use of FLP-FRT system for efficient targeting of foreign gene into the engineered genomic site in rice. The transgene vector containing a pair of directly oriented FRT sites was introduced by particle bombardment into the cells containing the target locus. FLP activity generated by the co-bombarded FLP gene efficiently separated the transgene construct from the vector-backbone and integrated the backbone-free construct into the target site. Strong FLP activity, derived from the enhanced FLP protein, FLPe, was important for the successful site-specific integration (SSI). The majority of the transgenic events contained a precise integration and expressed the transgene. Interestingly, each transgenic event lacked the co-bombarded FLPe gene, suggesting reversion of the integration structure in the presence of the constitutive FLPe expression. Progeny of the precise transgenic lines inherited the stable SSI locus and expressed the transgene. This work demonstrates the application of FLP-FRT system for site-specific gene integration in plants using rice as a model.     

In vitro HIV-1 selective integration into the target sequence and decoy-effect of the modified sequence

Although there have been a few reports that the HIV-1 genome can be selectively integrated into the genomic DNA of cultured host cell, the biochemistry of integration selectivity has not been fully understood. We modified the in vitro integration reaction protocol and developed a reaction system with higher efficiency. We used a substrate repeat, 5'-(GTCCCTTCCCAGT)(n)(ACTGGGAAGGGAC)(n)-3', and a modified sequence DNA ligated into a circular plasmid. CAGT and ACTG (shown in italics in the above sequence) in the repeat units originated from the HIV-1 proviral genome ends. Following the incubation of the HIV-1 genome end cDNA and recombinant integrase for the formation of the pre-integration (PI) complex, substrate DNA was reacted with this complex. It was confirmed that the integration selectively occurred in the middle segment of the repeat sequence. In addition, integration frequency and selectivity were positively correlated with repeat number n. On the other hand, both frequency and selectivity decreased markedly when using sequences with deletion of CAGT in the middle position of the original target sequence. Moreover, on incubation with the deleted DNAs and original sequence, the integration efficiency and selectivity for the original target sequence were significantly reduced, which indicated interference effects by the deleted sequence DNAs. Efficiency and selectivity were also found to vary discontinuously with changes in manganese dichloride concentration in the reaction buffer, probably due to its influence on the secondary structure of substrate DNA. Finally, integrase was found to form oligomers on the binding site and substrate DNA formed a loop-like structure. In conclusion, there is a considerable selectivity in HIV-integration into the specified sequence; however, similar DNA sequences can interfere with the integration process, and it is therefore difficult for in vivo integration to occur selectively in the actual host genome DNA.     

Stimulation of the human RAD51 nucleofilament restricts HIV-1 integration in vitro and in infected cells

Stable HIV-1 replication requires the DNA repair of the integration locus catalyzed by cellular factors. The human RAD51 (hRAD51) protein plays a major role in homologous recombination (HR) DNA repair and was previously shown to interact with HIV-1 integrase (IN) and inhibit its activity. Here we determined the molecular mechanism of inhibition of IN. Our standard in vitro integration assays performed under various conditions promoting or inhibiting hRAD51 activity demonstrated that the formation of an active hRAD51 nucleofilament is required for optimal inhibition involving an IN-DNA complex dissociation mechanism. Furthermore we show that this inhibition mechanism can be promoted in HIV-1-infected cells by chemical stimulation of the endogenous hRAD51 protein. This hRAD51 stimulation induced both an enhancement of the endogenous DNA repair process and the inhibition of the integration step. Elucidation of this molecular mechanism leading to the restriction of viral proliferation paves the way to a new concept of antiretroviral therapy based on the enhancement of endogenous hRAD51 recombination activity and highlights the functional interaction between HIV-1 IN and hRAD51.