Development of a detection system for ferric pseudobactin using monoclonal antibodies

Certain root-colonizing fluorescent pseudomonads have been shown to promote plant growth and prevent plant disease in part through the production of siderophores. However, these favorable results have not been reproduced consistently from the laboratory to the greenhouse or from the greenhouse to the field. In some circumstances siderophores appear to play no role in disease prevention. In order to understand the dynamics of competition for iron in the rhizosphere it is essential that the localization and concentration of siderophores produced by both biocontrol agents and plant pathogens be determined. We have produced monoclonal antibodies (MAbs) to ferric pseudobactin, the siderophore of plant growth-promoting Pseudomonas B10. Three IgG1 MAbs cross-react with certain ferric pseudobactins but not with others. A competitive ELISA has been developed to detect and quantify ferric pseudobactin.     

Tn5 insertion mutants of Pseudomonas sp. 267 defective in siderophore production and their effect on clover (Trifolium pratense) nodulated with Rhizobium leguminosarum bv. trifolii

Pseudomonas sp. strain 267 isolated from soil promoted growth of different plants under field conditions and enhanced symbiotic nitrogen fixation in clover under gnotobiotic conditions. This strain produced pyoverdine-like compound under low-iron conditions and secreted vitamins of the B group. The role of fluorescent siderophore production in the beneficial effect of strain 267 on nodulated clover plants was investigated. Several non-fluorescent (Pvd^-) Tn5 insertion mutants of Pseudomonas sp. strain 267 were isolated and characterized. The presence of Tn5 insertions was confirmed by Southern analysis of EcoRI digested genomic DNA of each derivative strain. The siderophore-negative mutants were compared to the parental strain with respect to their growth promotion of nodulated clover infected with Rhizobium leguminosarum bv. trifolii 24.1. We found that all isolated Pvd^- mutants stimulated growth of nodulated clover plants in a similar manner to the parental strain. No consistent differences were observed between strain 267 and Pvd^- derivatives strains with respect to their plant growth promotion activity under gnotobiotic conditions.Dr Deryto died in august 1994     

Diversity of siderophore genes encoding biosynthesis of 2,3-dihydroxybenzoic acid in Aeromonas spp.

Most species of the genus Aeromonas produce the siderophore amonabactin, although two species produce enterobactin, the siderophore of many enteric bacteria. Both siderophores contain 2,3-dihydroxybenzoic acid (2,3-DHB). Siderophore genes (designated aebC, -E, -B and -A, for aeromonad enterobactin biosynthesis) that complemented mutations in the enterobactin genes of the Escherichia coli 2,3-DHB operon, entCEBA(P15), were cloned from an enterobactin-producing isolate of the Aeromonas spp. Mapping of the aeromonad genes suggested a gene order of aebCEBA, identical to that of the E. coli 2,3-DHB operon. Gene probes for the aeromonad aebCE genes and for amoA (the entC-equivalent gene previously cloned from an amonabactin-producing Aeromonas spp.) did not cross-hybridize. Gene probes for the E. coli 2,3-DHB genes entCEBA did not hybridize with Aeromonas spp. DNA. Therefore, in the genus Aeromonas, 2,3-DHB synthesis is encoded by two distinct gene groups; one (amo) is present in the amonabactin-producers, while the other (aeb) occurs in the enterobactin-producers. Each of these systems differs from (but is functionally related to) the E. coli 2,3-DHB operon. These genes may have diverged from an ancestral group of 2,3-DHB genes.     

Detection and identification of ferricrocin produced by ectendomycorrhizal fungi in the genusWilcoxina

The ectendomycorrhizal fungiWilcoxina mikolae isolates CSY-14 and RMD-947 andW. rehmii isolate CSY-85 were grown in pure culture under iron-limiting conditions. All three isolates tested positive for siderophore formation using both the ferric perchlorate assay and a sensitive HPLC iron-binding assay. A peptide siderophore was isolated from the culture medium by HPLC and shown to contain the amino acids serine, glycine and ornithine in a 1:2:3 ratio. This siderophore was identified as ferricrocin on the basis of electrospray mass spectroscopy and its co-chromatography in two different HPLC systems with ferricrocin isolated fromAspergillus fumigatus. Ferricrocin was the only siderophore isolated from theseWilcoxina cultures. This is the first report of siderophore formation by ectendomycorrhizal fungi.     

基于生物信息学分析从Streptomyces albofaciens JCM 4342中发现2,3-二羟基苯甲酸酯-L-丝氨酸脱水三聚体和二聚体天然产物

[背景] 铁是细菌生长的基本元素,而三价铁在自然水环境中几乎无法溶解。细菌已经进化出产生各种铁载体的能力,以促进铁的吸收。对于链霉菌,其特有的铁载体是去铁胺,同时它们也可以产生其他结构的铁载体,如ceolichelin、白霉素、肠杆菌素（enterobactin）和griseobactin。[目的] 揭示链霉菌中铁载体生物合成基因簇（Biosynthetic Gene Clusters,BGCs）的分布特点和基因簇特征,并探索其所合成铁载体的化合物结构。[方法] 利用生物信息学工具系统地分析308个具有全基因组序列信息的链霉菌中的铁载体生物合成基因簇,并用色谱和波谱方法分离和表征肠杆菌素相关天然产物。[结果] 发现Streptomyces albofaciens JCM 4342和其他少数菌株同时含有一个缺少2,3-二羟基苯甲酸（2,3-DHB）生物合成基因的孤立的肠杆菌素生物合成基因簇和另外一个推测可合成griseobactin的基因簇。从S.albofaciens JCM 4342发酵液中鉴定出4个肠杆菌素衍生的天然产物,包括链状2,3-二羟基苯甲酸酯-l-丝氨酸（2,3-DHBS）的三聚体和二聚体以及它们的脱水产物。[结论] 2个基因簇间存在一种特别的协同生物合成机制。推测是griseobactin基因簇负责合成2,3-DHB,而孤立的肠杆菌素基因簇编码的生物合成酶可夺取该底物,进而完成上述4种肠杆菌素衍生天然产物的生物合成。     

四株儿茶酚类铁载体高产菌株产消化酶活性及其益生特性

【背景】儿茶酚类铁载体对胃肠道菌群的生长代谢具有重要作用,研究儿茶酚类铁载体高产菌株的消化酶活性,挖掘其潜在益生特性具有重要意义。【目的】分析4株分离自健康成人粪样的儿茶酚类铁载体高产菌的产酶特性,通过分析菌株耐酸耐胆盐能力、粘附定殖能力、抗生素耐受性和急性毒性研究其益生特性。【方法】测定4株菌的蛋白酶、淀粉酶、脂肪酶、纤维素酶、植酸酶、乳糖酶和β-葡萄糖苷酶的酶活性。4株菌经人工模拟胃、肠液连续培养后分别计算其活菌数;分析4株菌的自凝集率、黏蛋白粘附率和表面疏水率;对小鼠连续7 d灌胃不同剂量的4株高产菌,观察并记录小鼠的一般体征,计算小鼠脏器指数,进行阳性细菌移位试验。【结果】在试验所测的7种消化酶中,E. coli Gut 07、E. coli Gut 12无蛋白酶和脂肪酶活性,B. cereus Gut 16无乳糖酶活性,E. coli Gut 20无蛋白酶活性,其余均具有。4株菌经人工模拟胃液培养6h后存活率均大于60%,转移到人工模拟肠液培养24 h后活菌数均大于初始菌落数;该4株菌具备在胃肠道中粘附定殖的能力,对大多数抗生素敏感,在浓度低于4.5×10~(11)CFU/m L、灌胃剂量为20m L/kg-bw时对小鼠无急性毒性,无阳性菌株移位现象。【结论】4株儿茶酚类铁载体高产菌株可作为潜在益生菌进行进一步的安全性和功能性研究。     

Switching between apparently redundant iron-uptake mechanisms benefits bacteria in changeable environments

Bacteria often possess multiple siderophore-based iron uptake systems for scavenging this vital resource from their environment. However, some siderophores seem redundant, because they have limited iron-binding efficiency and are seldom expressed under iron limitation. Here, we investigate the conundrum of why selection does not eliminate this apparent redundancy. We focus on Pseudomonas aeruginosa, a bacterium that can produce two siderophores—the highly efficient but metabolically expensive pyoverdine, and the inefficient but metabolically cheap pyochelin. We found that the bacteria possess molecular mechanisms to phenotypically switch from mainly producing pyoverdine under severe iron limitation to mainly producing pyochelin when iron is only moderately limited. We further show that strains exclusively producing pyochelin grew significantly better than strains exclusively producing pyoverdine under moderate iron limitation, whereas the inverse was seen under severe iron limitation. This suggests that pyochelin is not redundant, but that switching between siderophore strategies might be beneficial to trade off efficiencies versus costs of siderophores. Indeed, simulations parameterized from our data confirmed that strains retaining the capacity to switch between siderophores significantly outcompeted strains defective for one or the other siderophore under fluctuating iron availabilities. Finally, we discuss how siderophore switching can be viewed as a form of collective decision-making, whereby a coordinated shift in behaviour at the group level emerges as a result of positive and negative feedback loops operating among individuals at the local scale.     

Improved heterologous production of the nonribosomal peptide‐polyketide siderophore yersiniabactin through metabolic engineering and induction optimization

Biosynthesis of complex natural products like polyketides and nonribosomal peptides using Escherichia coli as a heterologous host provides an opportunity to access these molecules. The value in doing so stems from the fact that many compounds hold some therapeutic or other beneficial property and their original production hosts are intractable for a variety of reasons. In this work, metabolic engineering and induction variable optimization were used to increase production of the polyketide‐nonribosomal peptide compound yersiniabactin, a siderophore that has been utilized to selectively remove metals from various solid and aqueous samples. Specifically, several precursor substrate support pathways were altered through gene expression and exogenous supplementation in order to boost production of the final compound. The gene expression induction process was also analyzed to identify the temperatures and inducer concentrations resulting in highest final production levels. When combined, yersiniabactin production was extended to ～175 mg L^?1. © 2016 American Institute of Chemical Engineers Biotechnol. Prog., 32:1412–1417, 2016     

The Yersinia HPI is present in Serratia liquefaciens isolated from meat

AIMS: The aim of the study was to screen the Enterobacteriaceae flora of meat for the presence of bacteria harbouring the Yersinia high-pathogenicity island (HPI). METHODS AND RESULTS: Bacteria from 29 meat and 29 liver samples were isolated on violet-red bile glucose agar. A total of 197 isolates were screened for the presence of the irp2 gene, encoded within the HPI, by PCR. One isolate that was positive for irp2 gene was also positive for the fyuA, irp1, ybtP/ybtQ, ybtX/ybtS and int/asn tRNA genes by PCR. The presence of fyuA, irp1 and irp2 genes was confirmed by Southern hybridization. CONCLUSIONS: The isolate was identified as Serratia liquefaciens by sequencing of the 16S rRNA gene and by ribotyping. SIGNIFICANCE AND IMPACT OF THE STUDY: This is the first report of a Serratia harbouring the Yersinia HPI. Serratia is a frequently occurring Enterobacteriaceae genus in chill-stored meat.