Expression of a Synthesized Gene Encoding Cationic Peptide Cecropin B in Transgenic Tomato Plants Protects against Bacterial Diseases

The cationic lytic peptide cecropin B (CB), isolated from the giant silk moth (Hyalophora cecropia), has been shown to effectively eliminate Gram-negative and some Gram-positive bacteria. In this study, the effects of chemically synthesized CB on plant pathogens were investigated. The S₅₀s (the peptide concentrations causing 50% survival of a pathogenic bacterium) of CB against two major pathogens of the tomato, Ralstonia solanacearum and Xanthomonas campestris pv. vesicatoria, were 529.6 μg/ml and 0.29 μg/ml, respectively. The CB gene was then fused to the secretory signal peptide (sp) sequence from the barley α-amylase gene, and the new construct, pBI121-spCB, was used for the transformation of tomato plants. Integration of the CB gene into the tomato genome was confirmed by PCR, and its expression was confirmed by Western blot analyses. In vivo studies of the transgenic tomato plant demonstrated significant resistance to bacterial wilt and bacterial spot. The levels of CB expressed in transgenic tomato plants (∼0.05 μg in 50 mg of leaves) were far lower than the S₅₀ determined in vitro. CB transgenic tomatoes could therefore be a new mode of bioprotection against these two plant diseases with significant agricultural applications.Bacterial plant diseases are a source of great losses in the annual yields of most crops (5). The agrochemical methods and conventional breeding commonly used to control these bacterially induced diseases have many drawbacks. Indiscriminate use of agrochemicals has a negative impact on human, as well as animal, health and contributes to environmental pollution. Conventional plant-breeding strategies have limited scope due to the paucity of genes with these traits in the usable gene pools and their time-consuming nature. Consequently, genetic engineering and transformation technology offer better tools to test the efficacies of genes for crop improvement and to provide a better understanding of their mechanisms. One advance is the possibility of creating transgenic plants that overexpress recombinant DNA or novel genes with resistance to pathogens (36). In particular, strengthening the biological defenses of a crop by the production of antibacterial proteins with other origins (not from plants) offers a novel strategy to increase the resistance of crops to diseases (35, 39, 41). These antimicrobial peptides (AMPs) include such peptides as cecropins (2, 15, 20, 23-24, 27, 31, 42, 50), magainins (1, 9, 14, 29, 47), sarcotoxin IA (35, 40), and tachyplesin I (3). The genes encoding these small AMPs in plants have been used in practice to enhance their resistance to bacterial and fungal pathogens (8, 22, 40). The expression of AMPs in vivo (mostly cecropins and a synthetic analog of cecropin and magainin) with either specific or broad-spectrum disease resistance in tobacco (14, 24, 27), potato (17, 42), rice (46), banana (9), and hybrid poplar (32) have been reported. The transgenic plants showed considerably greater resistance to certain pathogens than the wild types (4, 13, 24, 27, 42, 46, 50). However, detailed studies of transgenic tomatoes expressing natural cecropin have not yet been reported.The tomato (Solanum lycopersicum) is one of the most commonly consumed vegetables worldwide. The annual yield of tomatoes, however, is severely affected by two common bacterial diseases, bacterial wilt and bacterial spot, which are caused by infection with the Gram-negative bacteria Ralstonia solanacearum and Xanthomonas campestris pv. vesicatoria, respectively. Currently available pesticides are ineffective against R. solanacearum, and thus bacterial wilt is a serious problem.Cecropins, one of the natural lytic peptides found in the giant silk moth, Hyalophora cecropia (25), are synthesized in lipid bodies as proteins consisting of 31 to 39 amino acid residues. They adopt an α-helical structure on interaction with bacterial membranes, resulting in the formation of ion channels (12). At low concentrations (0.1 μM to 5 μM), cecropins exhibit lytic antibacterial activity against a number of Gram-negative and some Gram-positive bacteria, but not against eukaryotic cells (11, 26, 33), thus making them potentially powerful tools for engineering bacterial resistance in crops. Moreover, cecropin B (CB) shows the strongest activity against Gram-negative bacteria within the cecropin family and therefore has been considered an excellent candidate for transformation into plants to improve their resistance against bacterial diseases.The introduction of genes encoding cecropins and their analogs into tobacco has been reported to have contradictory results regarding resistance against pathogens (20). However, subsequent investigations of these tobacco plants showed that the expression of CB in the plants did not result in accumulation of detectable levels of CB, presumably due to degradation of the peptide by host peptidases (20, 34). Therefore, protection of CB from cellular degradation is considered to be vital for the exploitation of its antibacterial activity in transgenic plants. The secretory sequences of several genes are helpful, because they cooperate with the desired genes to enhance extracellular secretion (24, 40, 46). In the present study, a natural CB gene was successfully transferred into tomatoes. The transgenic plants showed significant resistance to the tomato diseases bacterial wilt and bacterial spot, as well as with a chemically synthesized CB peptide.     

Environmental Factors Shape Sediment Anammox Bacterial Communities in Hypernutrified Jiaozhou Bay,China

Bacterial anaerobic ammonium oxidation (anammox) is an important process in the marine nitrogen cycle. Because ongoing eutrophication of coastal bays contributes significantly to the formation of low-oxygen zones, monitoring of the anammox bacterial community offers a unique opportunity for assessment of anthropogenic perturbations in these environments. The current study used targeting of 16S rRNA and hzo genes to characterize the composition and structure of the anammox bacterial community in the sediments of the eutrophic Jiaozhou Bay, thereby unraveling their diversity, abundance, and distribution. Abundance and distribution of hzo genes revealed a greater taxonomic diversity in Jiaozhou Bay, including several novel clades of anammox bacteria. In contrast, the targeting of 16S rRNA genes verified the presence of only “Candidatus Scalindua,” albeit with a high microdiversity. The genus “Ca. Scalindua” comprised the apparent majority of active sediment anammox bacteria. Multivariate statistical analyses indicated a heterogeneous distribution of the anammox bacterial assemblages in Jiaozhou Bay. Of all environmental parameters investigated, sediment organic C/organic N (OrgC/OrgN), nitrite concentration, and sediment median grain size were found to impact the composition, structure, and distribution of the sediment anammox bacterial community. Analysis of Pearson correlations between environmental factors and abundance of 16S rRNA and hzo genes as determined by fluorescent real-time PCR suggests that the local nitrite concentration is the key regulator of the abundance of anammox bacteria in Jiaozhou Bay sediments.Anaerobic ammonium oxidation (anammox, NH₄⁺ + NO₂⁻ → N₂ + 2H₂O) was proposed as a missing N transformation pathway decades ago. It was found 20 years later to be mediated by bacteria in artificial environments, such as anaerobic wastewater processing systems (see reference 32 and references therein). Anammox in natural environments was found even more recently, mainly in O₂-limited environments such as marine sediments (28, 51, 54, 67, 69) and hypoxic or anoxic waters (10, 25, 39-42). Because anammox may remove as much as 30 to 70% of fixed N from the oceans (3, 9, 64), this process is potentially as important as denitrification for N loss and bioremediation (41, 42, 73). These findings have significantly changed our understanding of the budget of the marine and global N cycles as well as involved pathways and their evolution (24, 32, 35, 72). Studies indicate variable anammox contributions to local or regional N loss (41, 42, 73), probably due to distinct environmental conditions that may influence the composition, abundance, and distribution of the anammox bacteria. However, the interactions of anammox bacteria with their environment are still poorly understood.The chemolithoautotrophic anammox bacteria (64, 66) comprise the new Brocadiaceae family in the Planctomycetales, for which five Candidatus genera have been described (see references 32 and 37 and references therein): “Candidatus Kuenenia,” “Candidatus Brocadia,” “Candidatus Scalindua,” “Candidatus Anammoxoglobus,” and “Candidatus Jettenia.” Due to the difficulty of cultivation and isolation, anammox bacteria are not yet in pure culture. Molecular detection by using DNA probes or PCR primers targeting the anammox bacterial 16S rRNA genes has thus been the main approach for the detection of anammox bacteria and community analyses (58). However, these studies revealed unexpected target sequence diversity and led to the realization that due to biased coverage and specificity of most of the PCR primers (2, 8), the in situ diversity of anammox bacteria was likely missed. Thus, the use of additional marker genes for phylogenetic analysis was suggested in hopes of better capturing the diversity of this environmentally important group of bacteria. By analogy to molecular ecological studies of aerobic ammonia oxidizers, most recent studies have attempted to include anammox bacterium-specific functional genes. All anammox bacteria employ hydrazine oxidoreductase (HZO) (= [Hzo]₃) to oxidize hydrazine to N₂ as the main source for a useable reductant, which enables them to generate proton-motive force for energy production (32, 36, 65). Phylogenetic analyses of Hzo protein sequences revealed three sequence clusters, of which the cladistic structure of cluster 1 is in agreement with the anammox bacterial 16S rRNA gene phylogeny (57). The hzo genes have emerged as an alternative phylogenetic and functional marker for characterization of anammox bacterial communities (43, 44, 57), allowing the 16S rRNA gene-based investigation methods to be corroborated and improved.The contribution of anammox to the removal of fixed N is highly variable in estuarine and coastal sediments (50). For instance, anammox may be an important pathway for the removal of excess N (23) or nearly negligible (48, 54, 67, 68). This difference may be attributable to a difference in the structure and composition of anammox bacterial communities, in particular how the abundance of individual cohorts depends on particular environmental conditions. Anthropogenic disturbance with variable source and intensity of eutrophication and pollution may further complicate the anammox bacterium-environment relationship.Jiaozhou Bay is a large semienclosed water body of the temperate Yellow Sea in China. Eutrophication has become its most serious environmental problem, along with red tides (harmful algal blooms), species loss, and contamination with toxic chemicals and harmful microbes (14, 15, 21, 61, 71). Due to different sources of pollution and various levels of eutrophication across Jiaozhou Bay (mariculture, municipal and industrial wastewater, crude oil shipyard, etc.), a wide spectrum of environmental conditions may contribute to a widely varying community structure of anammox bacteria. This study used both 16S rRNA and hzo genes as targets to measure their abundance, diversity, and spatial distribution and assess the response of the resident anammox bacterial community to different environmental conditions. Environmental factors with potential for regulating the sediment anammox microbiota are discussed.     

Identification of Diverse Antimicrobial Resistance Determinants Carried on Bacterial,Plasmid, or Viral Metagenomes from an Activated Sludge Microbial Assemblage

Using both sequence- and function-based metagenomic approaches, multiple antibiotic resistance determinants were identified within metagenomic libraries constructed from DNA extracted from bacterial chromosomes, plasmids, or viruses within an activated sludge microbial assemblage. Metagenomic clones and a plasmid that in Escherichia coli expressed resistance to chloramphenicol, ampicillin, or kanamycin were isolated, with many cloned DNA sequences lacking any significant homology to known antibiotic resistance determinants.Activated sludge in wastewater treatment plants is an open system with a dynamic and phylogenetically diverse microbial community (2, 3, 6, 7, 10, 11). Since the activated sludge process promotes cellular interactions among diverse microorganisms, there is great potential for the lateral transfer of antibiotic resistance genes between microbes in activated sludge and in downstream environments. Several studies have previously identified antibiotic resistance determinants from wastewater communities that are carried on bacterial chromosomes (1, 4, 14) and plasmids (9, 12, 13), but to our knowledge, a simultaneous metagenomic survey of antibiotic resistance determinants from all three genetic reservoirs (i.e., chromosomes, plasmids, and viruses) has never been performed within the same environment. To achieve a more comprehensive assessment of antibiotic resistance genes in the activated sludge microbial community, this study used both function- and sequence-based metagenomic approaches to identify antibiotic resistance determinants carried on bacterial chromosomes, plasmids, or viruses within an activated sludge microbial assemblage.     

Paenibacillus dendritiformis Bacterial Colony Growth Depends on Surfactant but Not on Bacterial Motion

Most research on growing bacterial colonies on agar plates has concerned the effect of genetic or morphotype variation. Some studies have indicated that there is a correlation between microscopic bacterial motion and macroscopic colonial expansion, especially for swarming strains, but no measurements have been obtained for a single strain to relate the microscopic scale to the macroscopic scale. We examined here a single strain (Paenibacillus dendritiformis type T; tip splitting) to determine both the macroscopic growth of colonies and the microscopic bacterial motion within the colonies. Our multiscale measurements for a variety of growth conditions revealed that motion on the microscopic scale and colonial growth are largely independent. Instead, the growth of the colony is strongly affected by the availability of a surfactant that reduces surface tension.Bacteria are able to colonize many different surfaces through collective behavior such as swarming and biofilm formation. Studies of such behavior (10, 18, 26, 31) have revealed cooperative phenomena on both microscopic and colonial scales (4, 5, 7, 8, 20), including production of extracellular “lubricant-wetting” fluid for movement on medium and hard surfaces (19, 22, 25), chemical signaling such as quorum sensing and chemotactic signaling (1, 12, 27), and the secretion of inhibiting and killing factors (2, 9, 11, 14, 15, 17).Research has suggested possible links between the microscopic behavior of a colony and the rate at which the colony expands (12, 23, 24, 29). For Pseudomonas aeruginosa, increased reversal rates for flagella lead to hyperswarming (a larger colony) (26). Similar flagellar modulation affects Escherichia coli (32); if the bacteria never tumble (flagella rotate only counterclockwise) or only tumble (flagella rotate only clockwise), the final colony is much smaller than a colony formed when the bacteria both swim and tumble. For Rhizobium etli, a correlation has been observed between microscopic swarming motion and expansion of the colony, and an acylhomoserine lactone molecule has been found to be a swarming regulator, as well as a biosurfactant that controls surface activity (12). These studies suggest that there is a correlation between microscopic activity and colonial expansion; however, a mutation may be pleiotropic, affecting both motility and surfactant production. Further, there may be additional, unidentified differences between mutant and wild-type strains. For example, the failure of Bacillus subtilis laboratory strains to swarm is caused by a mutation in a gene (sfp) needed for surfactin synthesis and a mutation(s) in an additional unknown gene(s) (21). Experiments that avoid this ambiguity by studying the response of a single strain exposed to changing physical environments have not been performed. Further, except for measurements of the size of an expanding colony as a function of time (3, 6), no detailed time development studies of a growing bacterial colony have been reported.Here we exposed a single bacterial strain, Paenibacillus dendritiformis type T (tip splitting) (4), to different substrate hardnesses, nutrition levels, and surfactant concentrations to identify the parameters that determine colonial growth. P. dendritiformis is a gram-positive rod-shaped (4 μm by 1 μm) bacterium that swims on top of an agar gel in a thin layer (a few micrometers thick) of fluid, presumably secreted by the bacterial cells. The bacteria develop complex colonial (bush-like) branching patterns that are sensitive to small changes in the environment when the bacteria are grown on nutrient-limited surfaces (low peptone levels [approximately 1 g/liter]) (6). The colonies grow slowly (0.1 mm/h) so the microscopic motion can be followed with a microscope for about 10 min without moving the field of view. Also, this strain shows swarming-like microscopic motion where the bacteria move collectively in whirls and jets. This makes this bacterium well suited for studying simultaneously the development of a colony and the internal structure of branches. We constructed a novel setup to observe 10 growing P. dendritiformis colonies in each experiment, and complementary microscopic measurements were obtained for the velocity field of individual bacteria or small groups of cells within the colonies. Specifically, we measured the “bacterial speed,” which was the average of the values for the velocity vectors for the bacteria in a region near the edge of a growing colony, and the “tip velocity,” which was the speed of the moving growth front at the edge of a colony. We also quantified the collective bacterial motion within the colonies by computing spatial and temporal velocity autocorrelation functions.     

Multiple Interaction Domains in FtsL,a Protein Component of the Widely Conserved Bacterial FtsLBQ Cell Division Complex

A bioinformatic analysis of nearly 400 genomes indicates that the overwhelming majority of bacteria possess homologs of the Escherichia coli proteins FtsL, FtsB, and FtsQ, three proteins essential for cell division in that bacterium. These three bitopic membrane proteins form a subcomplex in vivo, independent of the other cell division proteins. Here we analyze the domains of E. coli FtsL that are involved in the interaction with other cell division proteins and important for the assembly of the divisome. We show that FtsL, as we have found previously with FtsB, packs an enormous amount of information in its sequence for interactions with proteins upstream and downstream in the assembly pathway. Given their size, it is likely that the sole function of the complex of these two proteins is to act as a scaffold for divisome assembly.The division of an Escherichia coli cell into two daughter cells requires a complex of proteins, the divisome, to coordinate the constriction of the three layers of the Gram-negative cell envelope. In E. coli, there are 10 proteins known to be essential for cell division; in the absence of any one of these proteins, cells continue to elongate and to replicate and segregate their chromosomes but fail to divide (29). Numerous additional nonessential proteins have been identified that localize to midcell and assist in cell division (7-9, 20, 25, 34, 56, 59).A localization dependency pathway has been determined for the 10 essential division proteins (FtsZ→FtsA/ZipA→FtsK→FtsQ→FtsL/FtsB→FtsW→FtsI→FtsN), suggesting that the divisome assembles in a hierarchical manner (29). Based on this pathway, a given protein depends on the presence of all upstream proteins (to the left) for its localization and that protein is then required for the localization of the downstream division proteins (to the right). While the localization dependency pathway of cell division proteins suggests that a sequence of interactions is necessary for divisome formation, recent work using a variety of techniques reveals that a more complex web of interactions among these proteins is necessary for a functionally stable complex (6, 10, 19, 23, 24, 30-32, 40). While numerous interactions have been identified between division proteins, further work is needed to define which domains are involved and which interactions are necessary for assembly of the divisome.One subcomplex of the divisome, composed of the bitopic membrane proteins FtsB, FtsL, and FtsQ, appears to be the bridge between the predominantly cytoplasmic cell division proteins and the predominantly periplasmic cell division proteins (10). FtsB, FtsL, and FtsQ share a similar topology: short amino-terminal cytoplasmic domains and larger carboxy-terminal periplasmic domains. This tripartite complex can be divided further into a subcomplex of FtsB and FtsL, which forms in the absence of FtsQ and interacts with the downstream division proteins FtsW and FtsI in the absence of FtsQ (30). The presence of an FtsB/FtsL/FtsQ subcomplex appears to be evolutionarily conserved, as there is evidence that the homologs of FtsB, FtsL, and FtsQ in the Gram-positive bacteria Bacillus subtilis and Streptococcus pneumoniae also assemble into complexes (18, 52, 55).The assembly of the FtsB/FtsL/FtsQ complex is important for the stabilization and localization of one or more of its component proteins in both E. coli and B. subtilis (11, 16, 18, 33). In E. coli, FtsB and FtsL are codependent for their stabilization and for localization to midcell, while FtsQ does not require either FtsB or FtsL for its stabilization or localization to midcell (11, 33). Both FtsL and FtsB require FtsQ for localization to midcell, and in the absence of FtsQ the levels of full-length FtsB are significantly reduced (11, 33). The observed reduction in full-length FtsB levels that occurs in the absence of FtsQ or FtsL results from the degradation of the FtsB C terminus (33). However, the C-terminally degraded FtsB generated upon depletion of FtsQ can still interact with and stabilize FtsL (33).While a portion of the FtsB C terminus is dispensable for interaction with FtsL and for the recruitment of the downstream division proteins FtsW and FtsI, it is required for interaction with FtsQ (33). Correspondingly, the FtsQ C terminus also appears to be important for interaction with FtsB and FtsL (32, 61). The interaction between FtsB and FtsL appears to be mediated by the predicted coiled-coil motifs within the periplasmic domains of the two proteins, although only the membrane-proximal half of the FtsB coiled coil is necessary for interaction with FtsL (10, 32, 33). Additionally, the transmembrane domains of FtsB and FtsL are important for their interaction with each other, while the cytoplasmic domain of FtsL is not necessary for interaction with FtsB, which has only a short 3-amino-acid cytoplasmic domain (10, 33).In this study, we focused on the interaction domains of FtsL. We find that, as with FtsB, the C terminus of FtsL is required for the interaction of FtsQ with the FtsB/FtsL subcomplex while the cytoplasmic domain of FtsL is involved in recruitment of the downstream division proteins. Finally, we provide a comprehensive analysis of the presence of FtsB, FtsL, and FtsQ homologs among bacteria and find that the proteins of this complex are likely more widely distributed among bacteria than was previously thought.     

A New Borrelia Species Defined by Multilocus Sequence Analysis of Housekeeping Genes

Analysis of Lyme borreliosis (LB) spirochetes, using a novel multilocus sequence analysis scheme, revealed that OspA serotype 4 strains (a rodent-associated ecotype) of Borrelia garinii were sufficiently genetically distinct from bird-associated B. garinii strains to deserve species status. We suggest that OspA serotype 4 strains be raised to species status and named Borrelia bavariensis sp. nov. The rooted phylogenetic trees provide novel insights into the evolutionary history of LB spirochetes.Multilocus sequence typing (MLST) and multilocus sequence analysis (MLSA) have been shown to be powerful and pragmatic molecular methods for typing large numbers of microbial strains for population genetics studies, delineation of species, and assignment of strains to defined bacterial species (4, 13, 27, 40, 44). To date, MLST/MLSA schemes have been applied only to a few vector-borne microbial populations (1, 6, 30, 37, 40, 41, 47).Lyme borreliosis (LB) spirochetes comprise a diverse group of zoonotic bacteria which are transmitted among vertebrate hosts by ixodid (hard) ticks. The most common agents of human LB are Borrelia burgdorferi (sensu stricto), Borrelia afzelii, Borrelia garinii, Borrelia lusitaniae, and Borrelia spielmanii (7, 8, 12, 35). To date, 15 species have been named within the group of LB spirochetes (6, 31, 32, 37, 38, 41). While several of these LB species have been delineated using whole DNA-DNA hybridization (3, 20, 33), most ecological or epidemiological studies have been using single loci (5, 9-11, 29, 34, 36, 38, 42, 51, 53). Although some of these loci have been convenient for species assignment of strains or to address particular epidemiological questions, they may be unsuitable to resolve evolutionary relationships among LB species, because it is not possible to define any outgroup. For example, both the 5S-23S intergenic spacer (5S-23S IGS) and the gene encoding the outer surface protein A (ospA) are present only in LB spirochete genomes (36, 43). The advantage of using appropriate housekeeping genes of LB group spirochetes is that phylogenetic trees can be rooted with sequences of relapsing fever spirochetes. This renders the data amenable to detailed evolutionary studies of LB spirochetes.LB group spirochetes differ remarkably in their patterns and levels of host association, which are likely to affect their population structures (22, 24, 46, 48). Of the three main Eurasian Borrelia species, B. afzelii is adapted to rodents, whereas B. valaisiana and most strains of B. garinii are maintained by birds (12, 15, 16, 23, 26, 45). However, B. garinii OspA serotype 4 strains in Europe have been shown to be transmitted by rodents (17, 18) and, therefore, constitute a distinct ecotype within B. garinii. These strains have also been associated with high pathogenicity in humans, and their finer-scale geographical distribution seems highly focal (10, 34, 52, 53).In this study, we analyzed the intra- and interspecific phylogenetic relationships of B. burgdorferi, B. afzelii, B. garinii, B. valaisiana, B. lusitaniae, B. bissettii, and B. spielmanii by means of a novel MLSA scheme based on chromosomal housekeeping genes (30, 48).     

XRCC2 and XRCC3 Regulate the Balance between Short- and Long-Tract Gene Conversions between Sister Chromatids

Sister chromatid recombination (SCR) is a potentially error-free pathway for the repair of DNA lesions associated with replication and is thought to be important for suppressing genomic instability. The mechanisms regulating the initiation and termination of SCR in mammalian cells are poorly understood. Previous work has implicated all the Rad51 paralogs in the initiation of gene conversion and the Rad51C/XRCC3 complex in its termination. Here, we show that hamster cells deficient in the Rad51 paralog XRCC2, a component of the Rad51B/Rad51C/Rad51D/XRCC2 complex, reveal a bias in favor of long-tract gene conversion (LTGC) during SCR. This defect is corrected by expression of wild-type XRCC2 and also by XRCC2 mutants defective in ATP binding and hydrolysis. In contrast, XRCC3-mediated homologous recombination and suppression of LTGC are dependent on ATP binding and hydrolysis. These results reveal an unexpectedly general role for Rad51 paralogs in the control of the termination of gene conversion between sister chromatids.DNA double-strand breaks (DSBs) are potentially dangerous lesions, since their misrepair may cause chromosomal translocations, gene amplifications, loss of heterozygosity (LOH), and other types of genomic instability characteristic of human cancers (7, 9, 21, 40, 76, 79). DSBs are repaired predominantly by nonhomologous end joining or homologous recombination (HR), two evolutionarily conserved DSB repair mechanisms (8, 12, 16, 33, 48, 60, 71). DSBs generated during the S or G₂ phase of the cell cycle may be repaired preferentially by HR, using the intact sister chromatid as a template for repair (12, 26, 29, 32, 71). Sister chromatid recombination (SCR) is a potentially error-free pathway for the repair of DSBs, which has led to the proposal that SCR protects against genomic instability, cancer, and aging. Indeed, a number of human cancer predisposition genes are implicated in SCR control (10, 24, 45, 57, 75).HR entails an initial processing of the DSB to generate a free 3′ single-stranded DNA (ssDNA) overhang (25, 48, 56). This is coupled to the loading of Rad51, the eukaryotic homolog of Escherichia coli RecA, which polymerizes to form an ssDNA-Rad51 “presynaptic” nucleoprotein filament. Formation of the presynaptic filament is tightly regulated and requires the concerted action of a large number of gene products (55, 66, 68). Rad51-coated ssDNA engages in a homology search by invading homologous duplex DNA. If sufficient homology exists between the invading and invaded strands, a triple-stranded synapse (D-loop) forms, and the 3′ end of the invading (nascent) strand is extended, using the donor as a template for gene conversion. This recombination intermediate is thought to be channeled into one of the following two major subpathways: classical gap repair or synthesis-dependent strand annealing (SDSA) (48). Gap repair entails the formation of a double Holliday junction, which may resolve into either crossover or noncrossover products. Although this is a major pathway in meiotic recombination, crossing-over is highly suppressed in somatic eukaryotic cells (26, 44, 48). Indeed, the donor DNA molecule is seldom rearranged during somatic HR, suggesting that SDSA is the major pathway for the repair of somatic DSBs (26, 44, 49, 69). SDSA terminates when the nascent strand is displaced from the D-loop and pairs with the second end of the DSB to form a noncrossover product. The mechanisms underlying displacement of the nascent strand are not well understood. However, failure to displace the nascent strand might be expected to result in the production of longer gene conversion tracts during HR (36, 44, 48, 63).Gene conversion triggered in response to a Saccharomyces cerevisiae or mammalian chromosomal DSB generally results in the copying of a short (50- to 300-bp) stretch of information from the donor (short-tract gene conversion [STGC]) (14, 47, 48, 67, 69). A minority of gene conversions in mammalian cells entail more-extensive copying, generating gene conversion tracts that are up to several kilobases in length (long-tract gene conversion [LTGC]) (26, 44, 51, 54, 64). In yeast, very long gene conversions can result from break-induced replication (BIR), a highly processive form of gene conversion in which a bona fide replication fork is thought to be established at the recombination synapse (11, 36, 37, 39, 61, 63). In contrast, SDSA does not require lagging-strand polymerases and appears to be much less processive than a conventional replication fork (37, 42, 78). BIR in yeast has been proposed to play a role in LOH in aging yeast, telomere maintenance, and palindromic gene amplification (5, 41, 52). It is unclear to what extent a BIR-like mechanism operates in mammalian cells, although BIR has been invoked to explain telomere elongation in tumors lacking telomerase (13). It is currently unknown whether LTGC and STGC in somatic mammalian cells are products of mechanistically distinct pathways or whether they represent alternative outcomes of a common SDSA pathway.Vertebrate cells contain five Rad51 paralogs—polypeptides with limited sequence homology to Rad51—Rad51B, Rad51C, Rad51D, XRCC2, and XRCC3 (74). The Rad51 paralogs form the following two major complexes: Rad51B/Rad51C/Rad51D/XRCC2 (BCDX2) and Rad51C/XRCC3 (CX3) (38, 73). Genetic deletion of any one of the rad51 paralogs in the mouse germ line produces early embryonic lethality, and mouse or chicken cells lacking any of the rad51 paralogs reveal hypersensitivity to DNA-damaging agents, reduced frequencies of HR and of sister chromatid exchanges, increased chromatid-type errors, and defective sister chromatid cohesion (18, 72, 73, 82). Collectively, these data implicate the Rad51 paralogs in SCR regulation. The purified Rad51B/Rad51C complex has been shown to assist Rad51-mediated strand exchange (62). XRCC3 null or Rad51C null hamster cells reveal a bias toward production of longer gene conversion tracts, suggesting a role for the CX3 complex in late stages of SDSA (6, 44). Rad51C copurifies with branch migration and Holliday junction resolution activities in mammalian cell extracts (35), and XRCC3, but not XRCC2, facilitates telomere shortening by reciprocal crossing-over in telomeric T loops (77). These data, taken together with the meiotic defects observed in Rad51C hypomorphic mice, suggest a specialized role for CX3, but not for BCDX2, in resolving Holliday junction structures (31, 58).To further address the roles of Rad51 paralogs in late stages of recombination, we have studied the balance between long-tract (>1-kb) and short-tract (<1-kb) SCR in XRCC2 mutant hamster cells. We found that DSB-induced gene conversion in both XRCC2 and XRCC3 mutant cells is biased in favor of LTGC. These defects were suppressed by expression of wild-type (wt) XRCC2 or XRCC3, respectively, although the dependence upon ATP binding and hydrolysis differed between the two Rad51 paralogs. These results indicate that Rad51 paralogs play a more general role in determining the balance between STGC and LTGC than was previously appreciated and suggest roles for both the BCDX2 and CX3 complexes in influencing the termination of gene conversion in mammals.     

Detection,Distribution, and Organohalogen Compound Discovery Implications of the Reduced Flavin Adenine Dinucleotide-Dependent Halogenase Gene in Major Filamentous Actinomycete Taxonomic Groups

Halogenases have been shown to play a significant role in biosynthesis and introducing the bioactivity of many halogenated secondary metabolites. In this study, 54 reduced flavin adenine dinucleotide (FADH₂)-dependent halogenase gene-positive strains were identified after the PCR screening of a large collection of 228 reference strains encompassing all major families and genera of filamentous actinomycetes. The wide distribution of this gene was observed to extend to some rare lineages with higher occurrences and large sequence diversity. Subsequent phylogenetic analyses revealed that strains containing highly homologous halogenases tended to produce halometabolites with similar structures, and halogenase genes are likely to propagate by horizontal gene transfer as well as vertical inheritance within actinomycetes. Higher percentages of halogenase gene-positive strains than those of halogenase gene-negative ones contained polyketide synthase genes and/or nonribosomal peptide synthetase genes or displayed antimicrobial activities in the tests applied, indicating their genetic and physiological potentials for producing secondary metabolites. The robustness of this halogenase gene screening strategy for the discovery of particular biosynthetic gene clusters in rare actinomycetes besides streptomycetes was further supported by genome-walking analysis. The described distribution and phylogenetic implications of the FADH₂-dependent halogenase gene present a guide for strain selection in the search for novel organohalogen compounds from actinomycetes.It is well known that actinomycetes, notably filamentous actinomycetes, have a remarkable capacity to produce bioactive molecules for drug development (4, 6). However, novel technologies are demanded for the discovery of new bioactive secondary metabolites from these microbes to meet the urgent medical need for drug candidates (5, 9, 31).Genome mining recently has been used to search for new drug leads (7, 20, 42, 51). Based on the hypothesis that secondary metabolites with similar structures are biosynthesized by gene clusters that harbor certain homologous genes, such homologous genes could serve as suitable markers for distinct natural-product gene clusters (26, 51). A wide range of structurally diverse bioactive compounds are synthesized by polyketide synthase (PKS) and nonribosomal peptide synthetase (NRPS) systems in actinomycetes, therefore much attention has been given to revealing a previously unrecognized biosynthetic potential of actinomycetes through the genome mining of these genes (2, 3, 22). However, the broad distribution of PKS and NRPS genes and their high numbers even in a single actinomycete complicate their use (2, 3). To rationally exploit the genetic potential of actinomycetes, more and more special genes, such as tailoring enzyme genes, are being utilized for this sequence-guided genetic screening strategy (20, 38).Tailoring enzymes, which are responsible for the introduction and generation of diversity and bioactivity in several structural classes during or after NRPS, PKS, or NRPS/PKS assembly lines, usually include acyltransferases, aminotransferases, cyclases, glycosyltransferases, halogenases, ketoreductases, methyltransferases, and oxygenases (36, 45). Halogenation, an important feature for the bioactivity of a large number of distinct natural products (16, 18, 30), frequently is introduced by one type of halogenase, called reduced flavin adenine dinucleotide (FADH₂)-dependent (or flavin-dependent) halogenase (10, 12, 35). More than 4,000 halometabolites have been discovered (15), including commercially important antibiotics such as chloramphenicol, vancomycin, and teicoplanin (43).Previous investigations of FADH₂-dependent halogenase genes were focused largely on related gene clusters in the genera Amycolatopsis (33, 44, 53) and Streptomyces (8, 10, 21, 27, 32, 34, 47-49) and also on those in the genera Actinoplanes (25), Actinosynnema (50), Micromonospora (1), and Nonomuraea (39); however, none of these studies has led to the rest of the major families and genera of actinomycetes. In addition, there is evidence that FADH₂-dependent halogenase genes of streptomycetes usually exist in halometabolite biosynthetic gene clusters (20), but we lack knowledge of such genes and clusters in other actinomycetes.In the present study, we show that the distribution of the FADH₂-dependent halogenase gene in filamentous actinomycetes does indeed correlate with the potential for halometabolite production based on other genetic or physiological factors. We also showed that genome walking near the halogenase gene locus could be employed to identify closely linked gene clusters that likely encode pathways for organohalogen compound production in actinomycetes other than streptomycetes.     

Functional Relationships between the AcrA Hairpin Tip Region and the TolC Aperture Tip Region for the Formation of the Bacterial Tripartite Efflux Pump AcrAB-TolC

Tripartite efflux pumps found in Gram-negative bacteria are involved in antibiotic resistance and toxic-protein secretion. In this study, we show, using site-directed mutational analyses, that the conserved residues located in the tip region of the α-hairpin of the membrane fusion protein (MFP) AcrA play an essential role in the action of the tripartite efflux pump AcrAB-TolC. In addition, we provide in vivo functional data showing that both the length and the amino acid sequence of the α-hairpin of AcrA can be flexible for the formation of a functional AcrAB-TolC pump. Genetic-complementation experiments further indicated functional interrelationships between the AcrA hairpin tip region and the TolC aperture tip region. Our findings may offer a molecular basis for understanding the multidrug resistance of pathogenic bacteria.The tripartite efflux pumps that are found in Gram-negative bacteria have been implicated in their intrinsic resistance to diverse antibiotics, as well as their secretion of protein toxins (10, 12, 24, 31). The bacterial efflux pump is typically assembled from three essential components: an inner membrane transporter (IMT), an outer membrane factor (OMF), and a periplasmic membrane fusion protein (MFP) (10, 12, 24, 31). The IMT provides energy for transporters, like the resistance nodulation cell division (RND) type and the ATP-binding cassette (ABC) type (18). The OMF connects to the IMT in the periplasm, providing a continuous conduit to the external medium. This conduit uses the central channel, which is opened only when in complex with other components (11, 18). The third essential component of the pump is the MFP, which is an adapter protein for the direct interaction between the IMT and OMF in the periplasm (32). The MFP consists of four linearly arranged domains: the membrane-proximal (MP) domain, the β-barrel domain, the lipoyl domain, and the α-hairpin domain (1, 6, 16, 22, 30). The MFP α-hairpin domain is known to interact with OMF, while the other domains are related to interaction with the IMT (15, 22).The Escherichia coli AcrAB-TolC pump, comprised of RND-type IMT-AcrB, MFP-AcrA, and OMF-TolC, is the major contributor to the multidrug resistance phenotype of the bacteria (7, 8, 25). The AcrAB-TolC pump, together with its homolog, the Pseudomonas aeruginosa MexAB-OprM pump (7, 13), has primarily been studied in order to elucidate the molecular mechanisms underlying the actions of the tripartite efflux pumps. Whereas the crystal structures of these proteins have revealed that RND-type IMTs (AcrB and MexB) and OMFs (TolC and OprM) are homotrimeric in their functional states (1, 6, 11, 16, 22, 30), the oligomeric state of MFP remains a topic of debate, despite the presence of crystal structures (3, 5, 17, 18, 22, 27, 30).MacAB-TolC, which was identified as a macrolide-specific extrusion pump (9), has also been implicated in E. coli enterotoxin secretion (29). While MFP-MacA shares high sequence similarity with AcrA and MexA, IMT-MacB is a homodimeric ABC transporter that uses ATP hydrolysis as the driving force (9, 14). MacA forms hexamers, and the funnel-like hexameric structure of MacA is physiologically relevant for the formation of a functional MacAB-TolC pump (30). Although the α-hairpins from AcrA and MacA are commonly involved in the interaction with TolC (30, 32), the interaction mode between AcrA and TolC remains to be elucidated. In this study, we provide experimental evidence showing that the conserved amino acid residues in the AcrA hairpin tip region is important for the action of the AcrAB-TolC efflux pump and is functionally related to the TolC aperture tip region.