Use of PCR-Targeted Mutagenesis To Disrupt Production of Fusaricidin-Type Antifungal Antibiotics in Paenibacillus polymyxa

Paenibacillus polymyxa (formerly Bacillus polymyxa) PKB1 has been identified as a potential agent for biocontrol of blackleg disease of canola, caused by the pathogenic fungus Leptosphaeria maculans. The factors presumed to contribute to disease suppression by strain PKB1 include the production of fusaricidin-type antifungal metabolites that appear around the onset of bacterial sporulation. The fusaricidins are a family of lipopeptide antibiotics consisting of a β-hydroxy fatty acid linked to a cyclic hexapeptide. Using a reverse genetic approach based on conserved motifs of nonribosomal peptide synthetases, a DNA fragment that appears to encode the first two modules of the putative fusaricidin synthetase (fusA) was isolated from PKB1. To confirm the involvement of fusA in production of fusaricidins, a modified PCR targeting mutagenesis protocol was developed to create a fusA mutation in PKB1. A DNA fragment internal to fusA was replaced by a gene disruption cassette containing two antibiotic resistance genes for independent selection of apramycin resistance in Escherichia coli and chloramphenicol resistance in P. polymyxa. Inclusion of an oriT site in the disruption cassette allowed efficient transfer of the inactivated fusA allele to P. polymyxa by intergeneric conjugation. Targeted disruption of fusA led to the complete loss of antifungal activity against L. maculans, suggesting that fusA plays an essential role in the nonribosomal synthesis of fusaricidins.     

Paenibacillus polymyxa produces fusaricidin-type antifungal antibiotics active against Leptosphaeria maculans, the causative agent of blackleg disease of canola

A bacterial isolate capable of inhibiting the growth of Leptosphaeria maculans (Desmaz.) Ces. & De Not., the causative agent of blackleg disease of canola (Brassica napus L. and Brassica rapa L.), was identified as a potential biological control agent. This environmental isolate was determined to be Paenibacillus polymyxa based on its (i) biochemical and growth characteristics and (ii) 16S rRNA sequence similarity, and was given the strain designation PKB1. Antifungal peptides were produced by P. polymyxa PKB1 around the onset of sporulation, with optimal production on potato dextrose broth. The antifungal peptides were extracted from P. polymyxa PKB1 cells and (or) spores using methanol and were purified using size exclusion and reverse-phase chromatography. Characterization of the antifungal peptides was done using amino acid compositional analysis, Edman degradation sequencing from partially hydrolyzed material, and a variety of mass spectrometric methods. The purified antifungal material was found to be a mixture of related peptides of molecular masses 883, 897, 948, and 961 Da, with the most likely structure of the 897 Da component determined to be a cyclic depsipeptide with an unusual 15-guanidino-3-hydroxypentadecanoic acid moiety bound to a free amino group. These compounds are therefore members of the fusaricidin group of cyclic depsipeptides.     

黑曲霉pepD基因阻断突变菌株的构建及功能分析

运用同源重组技术破坏了黑曲霉基因组中的pepD基因,该基因编码一种类subtilisin的胞外蛋白酶PEPD。实验以黑曲霉GICC2773基因组DNA为模板,PCR扩增pepD基因,并在此基因中间插入潮霉素抗性基因(hph)表达单元,由此产生了3.7kb的pepD阻断基因片段。将此阻断基因片段与载体pBS连接,构建成pepD基因阻断质粒pBSDH。采用原生质体-CaCl2/PEG法将酶切阻断质粒得到的含pepD基因和hph表达单元的3.7kb线性片段转化AspergillusnigerGICC2773菌株,在含潮霉素的平板上筛选潮霉素抗性转化子,从这些抗性转化子中经PCR检测分离到到1个pepD基因阻断突变菌株?pepD66。外源漆酶分泌活性分析显示,黑曲霉pepD基因的破坏使其外源漆酶的分泌表达有所提高。     

Sterptomyces rochei4089的L基因阻断变株的构建及功能研究

运用同源重组技术破坏了一株格尔德霉素产生菌Sterptomyces rochei 4089的L基因,该基因编码氧化还原酶.以Sterptomyces rochei 4089基因组总DNA为模板,PCR扩增AHBA-KLM基因簇,采取Red/ET重组技术,构建L基因阻断质粒pKC1139-KLM-KmR.采用大肠杆菌与链霉菌的结合转移将阻断质粒含AHBA-KLM基因簇和Kan表达单元的3.0 kb线性片段转化Sterptomyces rochei 4089菌株,在卡纳霉素的平板上筛选卡纳霉素抗性转化子,经PCR检测分离到L基因阻断突变菌株.对原、变株的发酵液进行TLC和HPLC分析显示,Sterptomyces rochei 4089基因组中的L基因失活后,导致该菌株不能合成安莎类抗生素格尔德霉素.通过阻断L基因,为筛查这类放线菌产生安莎类抗生素提供了明确的组分指示作用.     

Construction and characterization of ack knock-out mutants of Propionibacterium acidipropionici for enhanced propionic acid fermentation

Propionibacterium acidipropionici produces propionic acid from glucose with acetic acid, succinic acid, and CO2 as byproducts. In this work, inactivation of ack gene, encoding acetate kinase (AK), by gene disruption and integrational mutagenesis was studied as a method to reduce acetate formation in propionic acid fermentation. The partial ack gene of approximately 750 bp in P. acidipropionici was cloned using a PCR-based method with degenerate primers and sequenced. The deduced amino acid sequence had 88% similarity and 76% identity with the amino acid sequence of AK from Bacillus subtilis. The partial ack gene was used to construct a linear DNA fragment with an inserted tetracycline resistance cassette and a nonreplicative integrational plasmid containing a tetracycline resistance gene cassette. These DNA constructs were then introduced into P. acidipropionici by electroporation, resulting in two mutants, ACK-Tet and TAT-ACK-Tet, respectively. Southern hybridization confirmed that the ack gene in the mutant ACK-Tet was disrupted by the inserted tetracycline resistance gene. As compared to the wild-type, the activities of AK were reduced by 26% and 43% in ACK-Tet and TAT-ACK-Tet mutants, respectively. The specific growth rate of these mutants was reduced by approximately 25% to 0.10/h (0.13/h for the wild-type), probably because of reduced acetate and ATP production. Both mutants produced approximately 14% less acetate from glucose. Although ack disruption alone did not completely eliminate acetate production, the propionate yield was increased by approximately 13%.     

Phytoalexins from Thlaspi arvense, a wild crucifer resistant to virulent Leptosphaeria maculans: structures, syntheses and antifungal activity

Phytoalexins are inducible chemical defenses produced by plants in response to diverse forms of stress, including microbial attack. Our search for phytoalexins from cruciferous plants resistant to economically important fungal diseases led us to examine stinkweed or pennycress (Thlaspi arvense), a potential source of disease resistance to blackleg. We have investigated phytoalexin production in leaves of T. arvense under abiotic (copper chloride) and biotic elicitation by Leptosphaeria maculans (Desm.) Ces. et de Not. [asexual stage Phoma lingam (Tode ex Fr.) Desm.], and report here two phytoalexins, wasalexin A and arvelexin (4-methoxyindolyl-3-acetonitrile), their syntheses and antifungal activity against isolates of P. lingam/L. maculans, as well as the isolation of isovitexin, a constitutive glycosyl flavonoid of stinkweed, having antioxidant properties but devoid of antifungal activity.     

Genetics of subpeptin JM4-A and subpeptin JM4-B production by Bacillus subtilis JM4

Subpeptin JM4-A and subpeptin JM4-B are two novel antimicrobial peptides produced by Bacillus subtilis JM4. To identify putative genes involved in their production, degenerate PCR primers targeted to conserved motifs of nonribosomal peptide synthetases (NRPSs) were used. A resulting 1.2 kb PCR product had high sequence similarity to genes of NRPSs, and then a 2.8 kb DNA fragment flanking it was cloned subsequently. Gene disruption of the resulting 4 kb DNA fragment produced subpeptin-deficient mutant, suggesting that subpeptin JM4-A and subpeptin JM4-B were biosynthesized by NRPSs. Based on this result, a 48 kb gene cluster was cloned, which consisted of nine coding sequences (CDSs) involved in antimicrobial peptide biosynthesis, regulation, and resistance. Disruption of two relatively large CDSs subA and subC led to subpeptin-deficient mutants, which supported the involvement of the cloned gene cluster in subpeptin biosynthesis.     

Mapping genes for resistance to Leptosphaeria maculans in Brassica juncea.

Blackleg disease of crucifers, caused by the fungus Leptosphaeria maculans, is a major concern to oilseed rape producers worldwide. Brassica species containing the B genome have high levels of resistance to blackleg. Brassica juncea F2 and first-backcross (B1) populations segregating for resistance to a PG2 isolate of L. maculans were created. Segregation for resistance to L. maculans in these populations suggested that resistance was controlled by two independent genes, one dominant and one recessive in nature. A map of the B. juncea genome was constructed using segregation in the F2 population of a combination of restriction fragment length polymorphism (RFLP) and microsatel lite markers. The B. juncea map consisted of 325 loci and was aligned with previous maps of the Brassica A and B genomes. The gene controlling dominant resistance to L. maculans was positioned on linkage group J13 based on segregation for resistance in the F2 population. This position was confirmed in the B1 population in which the resistance gene was definitively mapped in the interval flanked by pN199RV and sB31143F. The provisional location of the recessive gene controlling resistance to L. maculans on linkage group J18 was identified using a subset of informative F2 individuals.     

A physical map of the syringomycin and syringopeptin gene clusters localized to an approximately 145-kb DNA region of Pseudomonas syringae pv. syringae strain B301D.

Genetic and phenotypic mapping of an approximately 145-kb DraI fragment of Pseudomonas syringae pv. syringae strain B301D determined that the syringomycin (syr) and syringopeptin (syp) gene clusters are localized to this fragment. The syr and syp gene clusters encompass approximately 55 kb and approximately 80 kb, respectively. Both phytotoxins are synthesized by a thiotemplate mechanism of biosynthesis, requiring large multienzymatic proteins called peptide synthetases. Genes encoding peptide synthetases were identified within the syr and syp gene clusters, accounting for 90% of the DraI fragment. In addition, genes encoding regulatory and secretion proteins were localized to the DraI fragment. In particular, the salA gene, encoding a regulatory element responsible for syringomycin production and lesion formation in P. syringae pv. syringae strain B728a, was localized to the syr gene cluster. A putative ATP-binding cassette (ABC) transporter homolog was determined to be physically located in the syp gene cluster, but phenotypically affects production of both phytotoxins. Preliminary size estimates of the syr and syp gene clusters indicate that they represent two of the largest nonribosomal peptide synthetase gene clusters. Together, the syr and syp gene clusters encompass approximately 135 kb of DNA and may represent a genomic island in P. syringae pv. syringae that contributes to virulence in plant hosts.     

Low virulence of a morphological Candida albicans mutant

The DNA fragment encoding malonate decarboxylase, involved in malonate assimilation, was cloned from Pseudomonas putida. The 11-kb DNA fragment contained nine open reading frames, which were designated mdcABCDEGHLM in the given order. N-terminal protein sequencing established that the mdcA, mdcC, mdcD, mdcE and mdcH genes encoded subunits alpha, delta, beta, gamma and epsilon of the malonate decarboxylase, respectively. Malonate decarboxylase was functionally expressed in Escherichia coli from plasmid harboring the entire gene cluster or the mdc genes lacking the mdcL and mdcM genes. The mdcL and mdcM genes encode membrane proteins and disruption of the genes of P. putida by the insertion of a kanamycin resistance cassette reduced the malonate uptake activity of the organism. Thus, we conclude that MdcLM is a malonate transporter.     

Hyper-susceptibility of a fusidic acid-resistant mutant of Salmonella to different classes of antibiotics

Fusidic acid resistance (Fus(R)) in Salmonella enterica serovar Typhimurium is caused by mutations in fusA, encoding elongation factor G (EF-G). Pleiotropic phenotypes are observed in Fus(R) mutants. Thus, the fusA1 allele (EF-G P413L) is associated with slow growth rate, reduced ppGpp and RpoS levels, reduced heme levels, and increased sensitivity to oxidative stress. The fusA1-15 allele, (EF-G P413L and T423I) derived from fusA1 in a selection for growth rate compensation, is partially compensated in each of these phenotypic defects but maintains its resistance to fusidic acid. We show here that the fusA1 allele is associated with sensitivity to ultraviolet light and increased susceptibility to the inhibitory action of several unrelated antibiotic classes (beta-lactam, fluoroquinolone, aminoglycoside, rifampicin, and chloramphenicol). The fusA1-15 allele, in contrast, is less susceptible to UV and to other antibiotics than fusA1. The hyper-susceptibility to multiple antibiotics associated with fusA1 and fusA1-15 is revealed in a novel growth competition assay at sub-MIC concentrations, but not in a standard MIC assay.     

Auxin production and detection of the gene coding for the Auxin Efflux Carrier (AEC) protein in <Emphasis Type="Italic">Paenibacillus polymyxa</Emphasis>

Different species of Paenibacillus are considered to be plant growth-promoting rhizobacteria (PGPR) due to their ability to repress soil borne pathogens, fix atmospheric nitrogen, induce plant resistance to diseases and/or produce plant growth-regulating substances such as auxins. Although it is known that indole-3-acetic acid (IAA) is the primary naturally occurring auxin excreted by Paenibacillus species, its transport mechanisms (auxin efflux carriers) have not yet been characterized. In this study, the auxin production of P. polymyxa and P. graminis, which are prevalent in the rhizospheres of maize and sorghum sown in Brazil, was evaluated. In addition, the gene encoding the Auxin Efflux Carrier (AEC) protein from P. polymyxa DSM36(T) was sequenced and used to determine if various strains of P. polymyxa and P. graminis possessed this gene. Each of the 68 P. polymyxa strains evaluated in this study was able to produce IAA, which was produced at concentrations varying from 1 to 17 microg/ml. However, auxin production was not detected in any of the 13 P. graminis strains tested in this study. Different primers were designed for the PCR amplification of the gene coding for the AEC in P. polymyxa, and the predicted protein of 319 aa was homologous to AEC from Bacillus amyloliquefaciens, B. licheniformis, and B. subtilis. However, no product was observed when these primers were used to amplify the genomic DNA of seven strains of P. graminis, which suggests that this gene is not present in this species. Moreover, none of the P. graminis genomes tested were homologous to the gene coding for AEC, whereas all of the P. polymyxa genomes evaluated were. This is the first study to demonstrate that the AEC protein is present in P. polymyxa genome.     

黑曲霉pepB基因缺失菌株的构建及其功能分析

以黑曲霉(Aspergillus niger)GICC2773基因组DNA为模板,用PCR方法分别扩增pepB基因中的上游约1．4kb和下游约1．3kb两段DNA序列,将此两段序列按同一方向分别插入质粒pMW1中潮霉素抗性基因(hph)表达单元的5′和3′端,构建成重组质粒pMW1-pepB,用于通过同源重组靶向破坏基因组中的pepB基因。同源重组则采用原生质体-PEG方法,将酶切pMW1-pepB得到的线性片段转化A．niger GICC2773菌株,通过潮霉素选择平板得到62个Hgy抗性转化子,然后采用PCR方法从这些抗性转化子中筛选到1个由于同源重组产生的pepB基因缺失突变菌株pepB29。功能分析显示该突变株的酸性蛋白酶活性有明显下降,外源蛋白漆酶的分泌表达有所提高。     

Agrobacterium-mediated disruption of a nonribosomal peptide synthetase gene in the invertebrate pathogen Metarhizium anisopliae reveals a peptide spore factor

Numerous secondary metabolites have been isolated from the insect pathogenic fungus Metarhizium anisopliae, but the roles of these compounds as virulence factors in disease development are poorly understood. We targeted for disruption by Agrobacterium tumefaciens-mediated transformation a putative nonribosomal peptide synthetase (NPS) gene, MaNPS1. Four of six gene disruption mutants identified were examined further. Chemical analyses showed the presence of serinocyclins, cyclic heptapeptides, in the extracts of conidia of control strains, whereas the compounds were undetectable in DeltaManps1 mutants treated identically or in other developmental stages, suggesting that MaNPS1 encodes a serinocyclin synthetase. Production of the cyclic depsipeptide destruxins, M. anisopliae metabolites also predicted to be synthesized by an NPS, was similar in DeltaManps1 mutant and control strains, indicating that MaNPS1 does not contribute to destruxin biosynthesis. Surprisingly, a MaNPS1 fragment detected DNA polymorphisms that correlated with relative destruxin levels produced in vitro, and MaNPS1 was expressed concurrently with in vitro destruxin production. DeltaManps1 mutants exhibited in vitro development and responses to external stresses comparable to control strains. No detectable differences in pathogenicity of the DeltaManps1 mutants were observed in bioassays against beet armyworm and Colorado potato beetle in comparison to control strains. This is the first report of targeted disruption of a secondary metabolite gene in M. anisopliae, which revealed a novel cyclic peptide spore factor.     

Transduction by phiBB-1, a bacteriophage of Borrelia burgdorferi

We previously described a bacteriophage of the Lyme disease agent Borrelia burgdorferi designated phiBB-1. This phage packages the host complement of the 32-kb circular plasmids (cp32s), a group of homologous molecules found throughout the genus Borrelia. To demonstrate the ability of phiBB-1 to package and transduce DNA, a kanamycin resistance cassette was inserted into a cloned fragment of phage DNA, and the resulting construct was transformed into B. burgdorferi CA-11.2A cells. The kan cassette recombined into a resident cp32 and was stably maintained. The cp32 containing the kan cassette was packaged by phiBB-1 released from this B. burgdorferi strain. phiBB-1 has been used to transduce this antibiotic resistance marker into naive CA-11.2A cells, as well as two other strains of B. burgdorferi. This is the first direct evidence of a mechanism for lateral gene transfer in B. burgdorferi.     

Correlation Between Antifungal Agent Phenazine-1-Carboxylic Acid and Pyoluteorin Biosynthesis in <Emphasis Type="Italic">Pseudomonas</Emphasis> sp. M18

Biosynthesis and secretion of two different types of antifungal compound [phenazine-1-carboxylic acid (PCA) and pyoluteorin (Plt) in Pseudomonas sp. M18] contribute to its suppression of soil-borne root pathogens. To better understand the correlation between two antifungal agents in secondary metabolism, a DNA fragment covering partial pltC and pltD coding sequences was obtained by screening the genomic library of Pseudomonas sp. M18. A mutant, M18T, was then constructed by insertion of the aacC1 gene cassette (encoding gentamycin resistance). With the same methods, one PCA biosynthetic gene cluster was insertionally inactivated and a mutant M18Z1 was created. The mutant strain M18T produces no Plt and the same amount of PCA in comparison with the wild-type strain M18. The mutant M18Z1, however, produces less PCA but more Plt than the wild-type strain M18. According to the documented data on strain M18, it is suggested that production of PCA is not influenced by Plt yield, but Plt biosynthesis is influenced by an alteration of PCA production.     

Rapid generation of gene disruption constructs by in vitro transposition and identification of a Dictyostelium protein kinase that regulates its rate of growth and development

We describe a rapid method for creating Dictyo stelium gene disruption constructs, whereby the target gene is interrupted by a drug resistance cassette using in vitro transposition. A fragment of genomic DNA containing the gene to be disrupted is amplified by PCR, cloned into a plasmid vector using topoisomerase and then employed as the substrate in an in vitro Tn5 transposition reaction. The transposing species is a fragment of DNA containing a Dictyostelium blasticidin S resistance (bs^r) cassette linked to a bacterial tetracycline resistance (tet^r) cassette. After transposition the plasmid DNA is transformed into Escherichia coli and clones in which the bs^r-tet^r cassette is inserted into the Dictyostelium target DNA are identified. To demonstrate its utility we have employed the method to disrupt the gene encoding QkgA, a novel protein kinase identified from the Dictyostelium genome sequencing project. QkgA is structurally homologous to two previously identified Dictyostelium kinases, GbpC and pats1. Like them it contains a leucine-rich repeat domain, a small GTP-binding (ras) domain and a MEKK domain. Disruption of the qkgA gene causes a marked increase in growth rate and, during development, aggregation occurs relatively slowly to form abnormally large multicellular structures.     

Analysis of loss of pathogenicity mutants reveals that repeat-induced point mutations can occur in the Dothideomycete Leptosphaeria maculans

Restriction enzyme mediated insertional mutagenesis using a plasmid, pUCATPH, that confers hygromycin resistance, generated loss-of-pathogenicity mutants of Leptosphaeria maculans, the fungus that causes blackleg disease of Brassica napus. Of 516 L. maculans transformants analysed, 12 were pathogenicity mutants. When eight of these mutants were crossed to an isolate that attacks B. napus, cosegregation of pUCATPH sequences and loss of pathogenicity was not observed, suggesting that these mutations were not linked to plasmid sequences. In seven of eight crosses analysed, progeny with the hygromycin resistance gene were hygromycin-sensitive. Sequence analysis of an amplified fragment of pUCATPH in six clones derived from one 'silenced' progeny showed mutation of GC to AT on one DNA strand, reminiscent of repeat-induced point mutation (RIP) in Neurospora crassa. One loss-of-pathogenicity mutant had pUCATPH inserted in the promoter of a gene with an open reading frame of 529 amino acids that had no database match. Reintroduction of a wild-type copy of the gene to this mutant restored the ability to form lesions on cotyledons of B. napus.