Genome Sequence of the Polymyxin-Producing Plant-Probiotic Rhizobacterium Paenibacillus polymyxa E681

Paenibacillus polymyxa E681, a spore-forming, low-G+C, Gram-positive bacterium isolated from the rhizosphere of winter barley grown in South Korea, has great potential for agricultural applications due to its ability to promote plant growth and suppress plant diseases. Here we present the complete genome sequence of P. polymyxa E681. Its 5.4-Mb genome encodes functions specialized to the plant-associated lifestyle and characteristics that are beneficial to plants, such as the production of a plant growth hormone, antibiotics, and hydrolytic enzymes.Among the plant-associated microbes, some are beneficial to plants, as they antagonize various plant pathogens, induce immunity, or even promote growth (2, 21, 29). These “plant-probiotic” bacteria (15, 16, 19, 22, 23, 28) have been isolated and commercially developed for use in the biological control of plant diseases or biofertilization (7, 10). Spore-forming bacteria, in particular, members of the phylum Firmicutes and streptomycetes, are considered advantageous in product formulation and stable maintenance in soil (9).The genus Paenibacillus (1) has grown to encompass more than 110 species (http://www.bacterio.cict.fr/p/paenibacillus.html), but its genome information is severely underrepresented. Paenibacillus spp. are important members of soil- or plant-associated ecosystems (3, 8, 20), with Paenibacillus polymyxa as one of the most industrially significant bacteria (13, 17, 25, 31). P. polymyxa E681, an endospore former isolated from the rhizosphere of winter barley in South Korea (14, 27), suppresses plant diseases, produces antibiotics and a plant hormone, secretes a variety of hydrolytic enzymes, and has good root-colonizing ability (4, 26).We determined the genome sequence of a rifampin-resistant clone of E681. About 62,000 chromatograms (∼6.7-fold genome coverage) were produced from plasmid/fosmid/bacterial artificial chromosome libraries with an AB 3700/377 DNA analyzer. Base calling, fragment assembly, contig/scaffold editing, and finishing were performed with Phred/Phrap/Consed. Gaps were closed by primer walking. To improve the sequence quality, 2.4 Gb of 76-bp single-ended sequences were obtained from Illumina Genome Analyzer IIx. Errors were identified using Maq/MapView and rectified by confirmatory sequencing. Yacop-predicted coding sequences were translated and subjected to transitive annotation by searches against UniProt, COG, KEGG Genes, and TIGRFAMs.The genome is composed of one circular chromosome of 5,394,884 bp (45.8% G+C). It has as many as 12 rRNA operons. No plasmid was found. Three-quarters of the 4,805 genes were assigned putative functions. Protein-coding genes are distributed preferentially on the leading strand. Apparently to cope with an ever-changing environment in the rhizosphere, the genome hosts at least 13 extracytoplasmic function sigma factors (12). There are 19 complete/disrupted insertion sequence elements but few phage-related genes.Some antibiotic-biosynthetic genes have been characterized. Polymyxin, produced and transported by PmxA to -E (5), is a potent antimicrobial that recently attracted attention for the treatment of multidrug-resistant Gram-negative bacteria (11, 18, 30). Fusaricidin, an antifungal antibiotic consisting of six amino acids, is synthesized by a single-chain nonribosomal peptide synthetase (6). E681 may also synthesize a polyketide, a tridecaptin-like nonribosomal peptide, and a hybrid of polyketide and nonribosomal peptide. A gene cluster is responsible for the production of a novel lantibiotic.Based on sequence investigation and biochemical analysis, auxin biosynthesis via the indole-3-pyruvic acid pathway was proposed as the only possible mechanism (24). The bacterium also produces volatile compounds that may promote growth and induce resistance of plants and one or more N-acyl-l-homoserine lactonases. Genome analysis revealed a rich set of secreted enzymes that degrade various plant-derived polysaccharides. They include xylanases, pectic enzymes, cellulases, and amylases. Genes involved in nitrogen fixation were not identified.     

Application of antifungal CFB to increase the durability of cement mortar

Antifungal cement mortar or microbiological calcium carbonate precipitation on cement surface has been investigated as functional concrete research. However, these research concepts have never been fused with each other. In this study, we introduced the antifungal calciteforming bacteria (CFB) Bacillus aryabhattai KNUC205, isolated from an urban tunnel (Daegu, South Korea). The major fungal deteriogens in urban tunnel, Cladosporium sphaerospermum KNUC253, was used as a sensitive fungal strain. B. aryabhattai KNUC205 showed CaCO3 precipitation on B4 medium. Cracked cement mortar pastes were made and neutralized by modified methods. Subsequently, the mixture of B. aryabhattai KNUC205, conidiospore of C. sphaerospermum KNUC253, and B4 agar was applied to cement cracks and incubated at 18 degrees C for 16 days. B. aryabhattai KNUC205 showed fungal growth inhibition against C. sphaerospermum. Furthermore, B. aryabhattai KNUC205 showed crack remediation ability and water permeability reduction of cement mortar pastes. Taken together, these results suggest that the CaCO3 precipitation and antifungal properties of B. aryabhattai KNUC205 could be used as an effective sealing or coating material that can also prevent deteriorative fungal growth. This study is the first application and evaluation research that incorporates calcite formation with antifungal capabilities of microorganisms for an environment-friendly and more effective protection of cement materials. In this research, the conception of microbial construction materials was expanded.     

Fungal load in <Emphasis Type="Italic">Bradysia agrestis</Emphasis>, a phytopathogen-transmitting insect vector

Larvae of Bradysia agrestis, a phytopathogen-transmitting insect vector in East Asia, were sampled from geographically (ecologically) segregated regions to identify their intestinal fungal flora. A total of 24 fungal strains were isolated from the insect vectors and selected based on morphological differences. In addition, 38 fungal strains were isolated from the ulcerated parts of invaded host plants by the same method, revealing the impact of vector fungal flora on their host plants. For molecular identification of the fungi, internal transcribed spacer (ITS) regions were amplified and sequenced. Their sequences were compared with sequences of other fungal strains obtained from NCBI GenBank, and their phylogeny was determined. The dominant fungal genera in the insect vector were Penicillium (25%), Aspergillus (21%), and Cladosporium (13%). In plant scar lesions, most fungal isolates belonged to the genera Fusarium (31.6%), Phoma (7.8%), Didymella (7.8%), and Epicoccum (7.8%). Fungal genera in vectors or host plant lesions differed by study site. Furthermore, diversity indices by study site showed clear differences based on Margalef’s richness (2.06, 2.40, 3.04), and Menhinick’s (1.89, 2.12, 2.53), and Simpson’s indices (0.14, 0.07, 0.07). In addition, common fungal strains in insect vectors were found to be closely related to members of the genera Cladosporium, Penicillium, or Aspergillus. Among these strains, those showing the highest homology with Aspergillus terreus, which regarded as beneficial fungal genera could be considered ideal paratransgenesis candidates. Some other fungal strains from vectors or ulcerated plant parts from each study site after B. agrestis invasion may be harmful in terms of plant disease or agrifood safety. This study provides information on the fungal microbiota of B. agrestis, an emerging problem in East Asia, and proposes paratransgenesis candidates to control this insect vector. Furthermore, potential transferable pathogens or commensal fungi were revealed by comparing the fungal biota between the insect gut and the ulcerated parts of the invaded host plants.     

Application of alkaliphilic biofilm-forming bacteria to improve compressive strength of cement-sand mortar

The application of microorganisms in the field of construction material is rapidly increasing worldwide; however, almost all studies that were investigated were bacterial sources with mineral-producing activity and not with organic substances. The difference in the efficiency of using bacteria as an organic agent is that it could improve the durability of cement material. This study aimed to assess the use of biofilm-forming microorganisms as binding agents to increase the compressive strength of cement-sand material. We isolated 13 alkaliphilic biofilmforming bacteria (ABB) from a cement tetrapod block in the West Sea, Korea. Using 16S RNA sequence analysis, the ABB were partially identified as Bacillus algicola KNUC501 and Exiguobacterium marinum KNUC513. KNUC513 was selected for further study following analysis of pH and biofilm formation. Cement-sand mortar cubes containing KNUC513 exhibited greater compressive strength than mineral-forming bacteria (Sporosarcina pasteurii and Arthrobacter crystallopoietes KNUC403). To determine the biofilm effect, Dnase I was used to suppress the biofilm formation of KNUC513. Field emission scanning electron microscopy image revealed the direct involvement of organic-inorganic substance in cement-sand mortar.     

Enhancement of the activity and pH-performance of chitosanase from Bacilluscereus strains by DNA shuffling

DNA shuffling was carried out with two chitosanase genes belonging to glycoside hydrolase family eight from Bacillus cereus KNUC51 and B. cereus KNUC55. The shuffled products, YM18 and YM20, which showed higher activity than the parents at 40°C, were selected for further studies. The 50 kDa chitosanases were purified using affinity chromatography with glutathione-Sepharose 4B. In general, the specific activity of YM18 is enhanced 250% and that of YM20 is 350% compared to the parents. YM20 exhibits a shift of the optimal pH level from 5.5 to 6.5. DNA sequence analysis revealed that YM18 and YM20 contained 2 amino acid substitutions (I13T and A87V for YM18; K66R and N352S for YM20). We presumed that these amino acid substitutions increase the specific activity and change the property of the two variants. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Proteome analysis of Paenibacillus polymyxa E681 affected by barley

Paenibacillus polymyxa E681 is known to be able to suppress plant diseases by producing antimicrobial compounds and to promote plant growth by producing phytohormones, and secreting diverse degrading enzymes. In spite of these capabilities, little is known regarding the flow of information from the bacterial strain to the barley roots. In an attempt to determine the flow of information from the bacterial strain to barley roots, the train was grown in the presence and absence of barley, and two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) and MALDI-TOF mass spectrometry were used. 2D-PAGE detected approximately 1000 spots in the cell and 1100 spots in the supernatant at a pH 4-10 gradient. Interestingly, about 80 spots from each sample showed quantitative variations. Fifty-three spots from these were analyzed by MALDI-TOF mass spectrometry and 28 proteins were identified. Most of the cytosolic proteins expressed at higher levels were found in P. polymyxa E681 cells grown in the presence of barley rather than in the absence of barley. Proteins detected at a lower level in the surpernatant of P. polymyxa E681 cells grown in the presence of barley were lipoprotein, glucose-6-phosphate 1-dehydrogenase, heat-shock protein HtpG spermidine synthase, OrfZ, ribonuclease PH, and coenzyme PQQ synthesis protein, and flagellar hook-associated protein 2 whereas proteins detected at a higher level in the surpernatant of P. polymyxa E681 cells grown in the presence of barley included D-alanyl-D-alanine ligase A, isopentenyldiphosphate delta-isomerase, ABC transporter ATP-binding protein Uup, lipase. Many of the proteins belonging to plant-induced stimulons are associated with biosynthetic metabolism and metabolites of proteins and transport. Some of these proteins would be expected to be induced by environmental changes resulting from the accumulation of plant-secreted substances.     

Functional identification and expression of indole-3-pyruvate decarboxylase from Paenibacillus polymyxa E681

Indole-3-acetic acid (IAA) is produced commonly by plants and many bacteria, however, little is known about the genetic basis involving the key enzymes of IAA biosynthetic pathways from Bacillus spp. IAA intermediates from the Gram-positive spore-forming bacterium Paenibacillus polymyxa E681 were investigated, which showed the existence of only an indole-3-pyruvic acid (IPA) pathway for IAA biosynthesis from the bacterium. Four open reading frames (ORFs) encoding indole-3-pyruvate decarboxylaselike proteins and putative indole-3-pyruvate decarboxylase (IPDC), a key enzyme in the IPA synthetic pathway, were found on the genome sequence database of P. polymyxa and cloned in Escherichia coli DH5alpha. One of the ORFs, PP2_01257, was assigned as probable indole-3-pyruvate decarboxylase. The ORF consisted of 1,743 nucleotides encoding 581 amino acids with a deduced molecular mass of 63,380 Da. Alignment studies of the deduced amino acid sequence of the ORF with known IPDC sequences revealed conservation of several amino acids in PP2_01257, essential for substrate and cofactor binding. Recombinant protein, gene product of the ORF PP2_01257 from P. polymyxa E681, was expressed in E. coli BL21 (DE3) as a glutathione S-transferase (GST)-fusion protein and purified to homogeneity using affinity chromatography. The molecular mass of the purified enzyme showed about 63 kDa, corresponding closely to the expected molecular mass of IPDC. The indole-3-pyruvate decarboxylase activity of the recombinant protein, detected by HPLC, using IPA substrate in the enzyme reaction confirmed the identity and functionality of the enzyme IPDC from the E681 strain.     

The Effects of Paenibacillus polymyxa E681 on Antifungal and Crack Remediation of Cement Paste

This study investigated the antifungal effects of cement paste containing Paenibacillus polymyxa E681 against Aspergillus niger, a deleterious fungus commonly found in cement buildings and structures. To test the antifungal effects, cement paste containing P. polymyxa E681 was neutralized by CO₂ gas, and the fungal growth inhibition was examined according to the clear zone around the cement specimen. In addition to the antifungal effects of the cement paste added with bacteria, calcium crystal precipitation of P. polymyxa E681 was examined by qualitative and quantitative analyses. The cement paste containing P. polymyxa E681 showed strong antifungal effects but fusA mutant (deficient in fusaricidin synthesis) showed no antifungal activity. Crack sealing of the cement paste treated with P. polymyxa E681 was captured by light microscope showed fungal growth inhibition and crack repairing in cement paste.     

Sequence Analysis of the Bacillus subtilis 168 Chromosome Region between the sspC and odhA Loci (184{degrees}-180{degrees})

The nucleotide sequence of 45,389 bp in the 184°-;180°region of the Bacillus subtilis chromosome, containing the cgecluster, which is controlled by the sporulation regulatory proteinGerE, was determined. Fifty-four putative ORFs with putativeribosome-binding sites were recognized. Seven of them correspondto previously characterized genes: cgeB, cgeA, cgeC, cgeD, cgeE,ctpA, and odhA. The deduced products of 25 ORFs were found todisplay significant similarities to proteins in the data banks.We have identified genes involved in detoxification, cell walls,and in the metabolism of biotins, purines, fatty acids, carbohydratesand amino acids. The remaining 22 ORFs showed no similarityto known proteins. Both an attachment site of the SPßprophage and 2 new putative DNA replication terminators wereidentified in this region.