Genetic Studies of Recombining DNA in Pneumococcal Transformation

The results of genetic fine structure experiments, performed on the amiA locus of Pneumococcus are summarized. The peculiar feature of transformation genetics is that a given donor marker mutation transforms with an efficiency characteristic of the mutated site. In spite of this difficulty, mapping procedures have been devised and quantitative recombination studies performed. It is concluded from these studies that transformation, in this locus, is the consequence of frequent, and essentially random exchanges occurring between donor DNA and the chromosomal DNA of the recipient cell. The average length of uninterrupted donor DNA polynucleotide strand which could be inserted into the chromosome of a transformed cell is estimated, from genetic data, to be probably not greater than 3·10⁵ daltons (for a double-stranded insertion). It is proposed, on the basis of genetic evidence, that following essentially random exchanges between donor DNA and recipient chromosome, a revision process, specific for certain types of mutated sites, occurs. The revision process appears to remove preferentially donor DNA sequences from the primary recombinant structure, and allow repair along the chromosomal template, leading to low efficiency in the genetic integration of these sites. A mechanism for this "destruction-choice" process is presented, and evidence in support of this mechanism discussed.     

Competence-Independent Activity of Pneumococcal Enda Mediates Degradation of Extracellular DNA and Nets and Is Important for Virulence

Membrane surface localized endonuclease EndA of the pulmonary pathogen Streptococcus pneumoniae (pneumococcus) is required for both genetic transformation and virulence. Pneumococcus expresses EndA during growth. However, it has been reported that EndA has no access to external DNA when pneumococcal cells are not competent for genetic transformation, and thus, unable to degrade extracellular DNA. Here, by using both biochemical and genetic methods, we demonstrate the existence of EndA-mediated nucleolytic activity independent of the competence state of pneumococcal cells. Pneumococcal mutants that are genetically deficient in competence development and genetic transformation have extracellular nuclease activity comparable to their parental wild type, including their ability to degrade neutrophil extracellular traps (NETs). The autolysis deficient ΔlytA mutant and its isogenic choline-treated parental wild-type strain D39 degrade extracellular DNA readily, suggesting that partial cell autolysis is not required for DNA degradation. We show that EndA molecules are secreted into the culture medium during the growth of pneumococcal cells, and contribute substantially to competence-independent nucleolytic activity. The competence-independent activity of EndA is responsible for the rapid degradation of DNA and NETs, and is required for the full virulence of Streptococcus pneumoniae during lung infection.     

肺炎链球菌粘附和毒力因子A研究进展

肺炎链球菌（Streptococcus pneumoniae,SP）普遍定植于呼吸道,是人类重要的侵袭性病原菌之一,是社区获得性肺炎、中耳炎、脑膜炎、菌血症、鼻窦炎的主要病原菌。肺炎链球菌粘附和毒力因子A（pneumococcal adherence and virulence factor A,PavA）是肺炎链球菌早期感染和侵袭过程中关键的毒力因子。体外试验表明,缺失PavA的肺炎链球菌的突变株其粘附和侵入上皮细胞和内皮细胞的能力明显下降。作为一种保护性抗原,其诱导的细胞和体液免疫可以有效的抵抗肺炎链球菌的感染,是肺炎链球菌新一代疫苗的候选蛋白。但是,PavA在肺炎链球菌与人肺上皮细胞交互对话中作用机制的研究尚属空白,本文就肺炎链球菌粘附和毒力因子A得最新研究进展作一综述。     

Concerted Spatio-Temporal Dynamics of Imported DNA and ComE DNA Uptake Protein during Gonococcal Transformation

Competence for transformation is widespread among bacterial species. In the case of Gram-negative systems, a key step to transformation is the import of DNA across the outer membrane. Although multiple factors are known to affect DNA transport, little is known about the dynamics of DNA import. Here, we characterized the spatio-temporal dynamics of DNA import into the periplasm of Neisseria gonorrhoeae. DNA was imported into the periplasm at random locations around the cell contour. Subsequently, it was recruited at the septum of diplococci at a time scale that increased with DNA length. We found using fluorescent DNA that the periplasm was saturable within minutes with ∼40 kbp DNA. The DNA-binding protein ComE quantitatively governed the carrying capacity of the periplasm in a gene-dosage-dependent fashion. As seen using a fluorescent-tagged derivative protein, ComE was homogeneously distributed in the periplasm in the absence of external DNA. Upon addition of external DNA, ComE was relocalized to form discrete foci colocalized with imported DNA. We conclude that the periplasm can act as a considerable reservoir for imported DNA with ComE governing the amount of DNA stored potentially for transport through the inner membrane.     

Cloning and Characterization of a Periplasmic Nuclease of Vibrio vulnificus and Its Role in Preventing Uptake of Foreign DNA

We have cloned a nuclease gene, vvn, from Vibrio vulnificus, an estuarine bacterium that causes wound infections and septicemia in humans and eels. The gene contained a 696-bp open reading frame encoding 232 amino acids (aa), including a signal sequence of 18 aa. The deduced amino acid sequence of the mature nuclease predicted a molecular mass of 25 kDa, which was confirmed by vital stain, and a pI of 8.6. Vvn was produced in the periplasm of either V. vulnificus or recombinant Escherichia coli strains and was active in the oxidized (but not the reduced) form. This nuclease was able to digest DNA and RNA, with differential thermostability in DNase and RNase activities. Expression of Vvn in E. coli DH5α reduced the frequencies of transformation with the divalent ion-treated cells and electroporation by about 6 and 2 logs, respectively. In addition, the transformation frequency of a Vvn-deficient V. vulnificus mutant (ND) was 10-fold higher than that of the parent strain. These data suggested that Vvn may be involved in preventing uptake of foreign DNA by transformation. However, Vvn expressed in the recipients had little effect on the conjugation frequency in either E. coli or V. vulnificus. Some other DNase(s) may be present in the periplasm and responsible for a residual DNase activity, which was about one-fourth of that of the parent strain, detected in the ND mutant. We also demonstrated that Vvn was not required for the virulence of V. vulnificus mice.     

Diffusion of the Restriction Nuclease EcoRI along DNA

Many specific sequence DNA binding proteins locate their target sequence by first binding to DNA nonspecifically, then by linearly diffusing or hopping along DNA until either the protein dissociates from the DNA or it finds the recognition sequence. We have devised a method for measuring one-dimensional diffusion along DNA based on the ratio of the dissociation rate of protein from DNA fragments containing one specific binding site to the dissociation rate from DNA fragments containing two specific binding sites. Our extensive measurements of dissociation rates and specific-nonspecific relative binding constants of the restriction nuclease EcoRI enable us to determine the diffusion rate of nonspecifically bound protein along the DNA. By varying the distance between the two binding sites, we confirm a linear diffusion mechanism. The sliding rate is relatively insensitive to salt concentration and osmotic pressure, indicating that the protein moves smoothly along the DNA probably following the helical phosphate-sugar backbone of DNA. We calculate a diffusion coefficient for EcoRI of 3 × 10⁴ bp² s^− 1 EcoRI is able to diffuse ∼ 150 bp, on average, along the DNA in 1 s. This diffusion rate is about 2000-fold slower than the diffusion of free protein in solution. A factor of 40-50 can be accounted for by rotational friction resulting from following the helical path of the DNA backbone. Two possibilities could account for the remaining activation energy: salt bridges between the DNA and the protein are transiently broken, or the water structure at the protein-DNA interface is disrupted as the two surfaces move past each other.     

Transformation During Mixed Pneumococcal Infection of Mice

The recent demonstration by others of transformation during peritoneal infection of mice by two genetically distinct pneumococcal strains supports the notion that transformation may be significant in pneumococcal infection in nature. These studies confirm the occurrence of transformation during mixed infection of mice and define some conditions for its occurrence and its significance. Mice were inoculated with deoxyribonucleic acid (DNA) donor (small type III capsule, low virulence, streptomycin-susceptible) and recipient (noncapsulated, low virulence, streptomycin-resistant) pneumococci, and the bacteremia in mice that died was evaluated. Transformants (large type III capsule, virulent, streptomycin-resistant) were isolated from up to 80% of mice that died from mixed peritoneal infection. Transformation occurred in mice that received donor and recipient 6 hr apart; hence, active DNA was released and competence developed during growth in vivo. Transformation was detected only with progressive infection by both strains, and then transformants were few in the blood and apparently were not responsible for the death of the animals. In doubly infected mice treated with streptomycin, transformation was enhanced; transformants numerically dominated the bacteremia and seemed to cause the death of the mice. Transformation was also demonstrated for the first time during infection of the respiratory tract.     

Discovery of Immunodominant B Cell Epitopes within Surface Pneumococcal Virulence Proteins in Pediatric Patients with Invasive Pneumococcal Disease

The identification of immunodominant B cell epitopes within surface pneumococcal virulence proteins in pediatric patients with invasive pneumococcal disease (IPD) is a valuable approach to define novel vaccine candidates. To this aim, we evaluated sera from children with IPD and age-matched controls against 141 20-mer synthetic peptides covering the entire sequence of major antigenic fragments within pneumococcal virulence proteins; namely, choline-binding protein D (CbpD), pneumococcal histidine triad proteins (PhtD and PhtE), pneumococcal surface protein A (PspA), plasminogen and fibronectin binding protein B (PfbB), and zinc metalloproteinase B (ZmpB). Ten immunodominant B cell epitopes were identified: CbpD-pep4 (amino acids (aa) 291–310), PhtD-pep11 (aa 88–107), PhtD-pep17 (aa 172–191), PhtD-pep19 (aa 200–219), PhtE-pep32 (aa 300–319), PhtE-pep40 (aa 79–98), PfbB-pep76 (aa 180–199), PfbB-pep79 (aa 222–241), PfbB-pep90 (aa 484–503), and ZmpB-pep125 (aa 431–450). All epitopes were highly conserved among different pneumococcal serotypes, and four of them were located within the functional zinc-binding domain of the histidine triad proteins PhtD and PhtE. Peptides CbpD-pep4, PhtD-pep19, and PhtE-pep40 were broadly recognized by IPD patient sera with prevalences of 96.4%, 92.9%, and 71.4%, respectively, whereas control sera exhibited only minor reactivities (<10.7%). Their specificities for IPD were 93.3%, 95%, and 96.7%; their sensitivities were 96.4%, 92.9%, and 71.4% and their positivity likelihood ratios for IPD were 14.5, 18.6, and 21.4, respectively. Furthermore, purified antibodies against CbpD-pep4, PhtD-pep19, and PhtE-pep40 readily bound on the surfaces of different pneumococcal serotypes, as assessed by FACS and immunofluorescence analysis. The identified immunodominant B cell epitopes provide a better understanding of immune response in IPD and are worth evaluation in additional studies as potential vaccine candidates.     

A Ferric Dicitrate Uptake System Is Required for the Full Virulence of Bacillus cereus

Bacillus cereus is an opportunistic human pathogen of increasing prevalence. Analysis of the Bacillus cereus genome sequence identified a potential ferric dicitrate uptake system. The three-gene operon was confirmed to be negatively regulated by the ferric uptake repressor (Fur). The Fec operon was genetically silenced using the integration suicide vector pMUTIN4. The mutant strain displayed no growth defect under iron-limited conditions but was unable to grow on ferric citrate as a sole iron source. The virulence of the mutant strain was attenuated in a lepidopteran infection model, highlighting the importance of iron uptake systems to the virulence of B. cereus and the potential of these systems to act as targets for novel antimicrobial agents.     

Nuclease S1 cleavage and the primary structure of mitochondrial DNA.

The single-strand-specific nuclease S1 from Aspergillus oryzae rapidly converts superhelical mitochondrial DNA (African Green Monkey cells, Vero ATCC; CCL 81) into nicked circular DNA. These nicked mitochondrial DNA molecules contain two nicks, one in each strand. The phosphodiester backbones are cleaved during this reaction at or near sites that are alkali-labile. In a second slow reaction the circular mitochondrial DNA is converted into a linear duplex DNA. Permutation tests indicate that this linear DNA represents a nonpermutated collection of DNA molecules. These results suggest that two of the alkai-labile sites in the phosphodiester backbones of the mitochondrial chromosome are closely spaced on opposite strands and at specific positions.     

外源DNA直接导入小麦及其在育种上的应用

本研究选用两个白粒小麦品种作供体,提取其总ＤＮＡ,采用花粉管直接携带法导入７５（１９８）红粒品种受体植株。ＤＮＡ导入的第一代（Ｄ１）,目的性状的转化频率为１．７５％和２．９４％。Ｄ２代变异率显著低于Ｄ１代。对Ｄ１,Ｄ２代所得目的性状变异后代,按照常规育种程序进行Ｄ３代观察与鉴定,得到已稳定遗传的后代,从中选取保持原品种其它优良性状而籽粒为的白色的变异类型混合脱粒,获得７５（１９８）改良新品系。     

Dual Nuclease and Helicase Activities of Helicobacter pylori AddAB Are Required for DNA Repair, Recombination, and Mouse Infectivity

Helicobacter pylori infection of the human stomach is associated with disease-causing inflammation that elicits DNA damage in both bacterial and host cells. Bacteria must repair their DNA to persist. The H. pylori AddAB helicase-exonuclease is required for DNA repair and efficient stomach colonization. To dissect the role of each activity in DNA repair and infectivity, we altered the AddA and AddB nuclease (NUC) domains and the AddA helicase (HEL) domain by site-directed mutagenesis. Extracts of Escherichia coli expressing H. pylori addA^NUCB or addAB^NUC mutants unwound DNA but had approximately half of the exonuclease activity of wild-type AddAB; the addA^NUCB^NUC double mutant lacked detectable nuclease activity but retained helicase activity. Extracts with AddA^HELB lacked detectable helicase and nuclease activity. H. pylori with the single nuclease domain mutations were somewhat less sensitive to the DNA-damaging agent ciprofloxacin than the corresponding deletion mutant, suggesting that residual nuclease activity promotes limited DNA repair. The addA^NUC and addA^HEL mutants colonized the stomach less efficiently than the wild type; addB^NUC showed partial attenuation. E. coli ΔrecBCD expressing H. pylori addAB was recombination-deficient unless H. pylori recA was also expressed, suggesting a species-specific interaction between AddAB and RecA and also that H. pylori AddAB participates in both DNA repair and recombination. These results support a role for both the AddAB nuclease and helicase in DNA repair and promoting infectivity.Infection of the stomach with Helicobacter pylori causes a variety of diseases including gastritis, peptic ulcers, and gastric cancer (1). A central feature of the pathology of these conditions is the establishment of a chronic inflammatory response that acts both on the host and the infecting bacteria (2). Both epithelial (3, 4) and lymphoid (5, 6) cells in the gastric mucosa of infected individuals release DNA-damaging agents that can introduce double-stranded (ds)² breaks into the bacterial chromosome (7). The ds breaks must be repaired for the bacteria to survive and establish chronic colonization of the stomach. Homologous recombination is required for the faithful repair of DNA damage and bacterial survival. Alteration of the expression of one of a series of cell surface proteins on H. pylori occurs by an apparent gene conversion of babA, the frequency of which is reduced in repair-deficient strains (8, 9). This change in the cell surface, which may allow H. pylori to evade the host immune response, is a second means by which recombination can promote efficient colonization of the stomach by H. pylori.The initiation or presynaptic steps of recombination at dsDNA breaks in most bacteria involves the coordinated action of nuclease and helicase activities provided by one of two multisubunit enzymes, the AddAB and RecBCD enzymes (10). Escherichia coli recBCD null mutants have reduced cell viability, are hypersensitive to DNA-damaging agents, and are homologous recombination-deficient (11–14). Similarly, H. pylori addA and addB null mutants are hypersensitive to DNA-damaging agents, have reduced frequencies of babA gene conversion, and colonize the stomach of mice less efficiently than wild-type strains (8).The activities of RecBCD enzyme from E. coli (15–19) and AddAB from H. pylori (8) or Bacillus subtilis (20–23) indicate some common general features of the presynaptic steps of DNA repair. In the case of E. coli, repair begins when the RecBCD enzyme binds to a dsDNA end and unwinds the DNA using its ATP-dependent helicase activities (17, 24). Single-stranded (ss) DNA produced during unwinding, with or without accompanying nuclease, is coated with RecA protein (16, 25). This recombinogenic substrate engages in strand exchange with a homologous intact duplex to form a joint molecule. Joint molecules are thought to be converted into intact, recombinant DNA either by replication or by cutting and ligation of exchanged strands (26).Although the AddAB and RecBCD enzymes appear to play similar roles in promoting recombination and DNA repair, they differ in several ways. RecBCD is a heterotrimer, composed of one copy of the RecB, RecC, and RecD gene products (27), whereas AddAB has two subunits, encoded by the addA and addB genes (21, 28). The enzyme subunit(s) responsible for helicase activity can be inferred from the presence of conserved protein domains or the activity of purified proteins. AddA, RecB, and RecD are superfamily I helicases with six highly conserved helicase motifs, including the conserved Walker A box found in many enzymes that bind ATP (29–32). A Walker A box is defined by the consensus sequence (G/A)XXGXGKT (X is any amino acid (29). RecBCD enzymes in which the conserved Lys in this motif is changed to Gln have a reduced affinity for ATP binding (33, 34) and altered helicase activity (17, 35–37).A nuclease domain with the conserved amino acid sequence LDYK is found in RecB, AddA, AddB, and many other nucleases (38). The conserved Asp plays a role in Mg²⁺ binding at the active site; Mg²⁺ is required for nuclease activity (39). The recB1080 mutation, which changes codon 1080 from the conserved Asp in this motif to Ala, eliminates nuclease activity (39).We have recently shown that addA and addB deletion mutants are hypersensitive to DNA-damaging agents and impaired in colonization of the mouse stomach compared with wild-type strains (8). To determine the roles of the individual helicase and nuclease activities of H. pylori AddAB in DNA repair and infectivity, we used site-directed mutagenesis to inactivate the conserved nuclease domains of addA and addB and the conserved ATPase (helicase) domain of AddA. Here, we report that loss of the AddAB helicase is sufficient to impair H. pylori DNA repair and infectivity and, when the genes are expressed in E. coli, homologous recombination. AddAB retains partial activity in biochemical and genetic assays when either of the two nuclease domains is inactivated but loses all detectable nuclease activity when both domains are inactivated. Remarkably, H. pylori AddAB can produce recombinants in E. coli only in the presence of H. pylori RecA, suggesting a species-specific interaction in which AddAB facilitates the production of ssDNA-coated with RecA protein. Our results show that both the helicase and nuclease activities are required for the biological roles of H. pylori AddAB.     

转基因植物对有机污染物的吸收、转化和降解

有机污染物是土壤、水体和大气环境的重要污染物.利用和加强植物修复作用是控制环境污染的有效途径.近年来,一些具有修复功能的外源基因被陆续引入到植物中,使转基因植物的生物修复能力大大增强.文章介绍了植物对污染环境中有机污染物,尤其是持久性有机污染物(POPs)的吸收、转化和降解作用,阐述了转基因植物用于被污染环境修复方面的研究进展和应用前景.     

Mechanism of DNA cleavage catalyzed by Mung Bean Nuclease

The interaction of zinc with different forms of DNA (λ phage DNA, ss-oligo, ds-oligo) and Mung Bean Nuclease was studied by voltammetric techniques in order to investigate the mechanism of DNA cleavage catalyzed by a zinc metalloenzyme. Stoichiometry, dissociation constant, zinc binding sites and functions were determined for these systems. Two zinc ions were found to be involved in stabilization of a 19 mer ds-oligodeoxyribonucleotide, which was synthesized by the phosphoramidite method and used as a DNA model in the studies. Three zinc ions (Zn1, Zn2, and Zn3), which have different roles in ds-oligo cleavage, were identified in the active site of Mung Bean Nuclease. A concerted S_N2 mechanism, which assigns a catalytic function to Zn2 and structural functions to Zn1 and Zn3, was proposed. The hydrolysis of phosphodiester bonds proceeds with inversion of configuration at the phosphorus center, forming a pentacoordinate transition state, which is stabilized by an arginine. Zn2 supplies the nucleophile, which is oriented by an aspartic acid, and activates the ds-oligo by its coordination to the phosphate free oxygen of the phosphodiester bond. Zn1 and Zn3 ions, besides stabilizing the tertiary structure of Mung Bean Nuclease, bind to the leaving group, blocking the cleavage reverse reaction.