Klaus Geider

Classification and identification of bacteria by mass spectrometry and computational analysis

Background In general, the definite determination of bacterial species is a tedious process and requires extensive manual labour. Novel technologies for bacterial detection and analysis can therefore help microbiologists in minimising their efforts in developing a number of microbiological applications. Methodology We present a robust, standardized procedure for automated bacterial analysis that is based on the detection of patterns of protein masses by MALDI mass spectrometry. We particularly applied the approach for classifying and identifying strains in species of the genus Erwinia. Many species of this genus are associated with disastrous plant diseases such as fire blight. Using our experimental procedure, we created a general bacterial mass spectra database that currently contains 2800 entries of bacteria of different genera. This database will be steadily expanded. To support users with a feasible analytical method, we developed and tested comprehensive software tools that are demonstrated herein. Furthermore, to gain additional analytical accuracy and reliability in the analysis we used genotyping of single nucleotide polymorphisms by mass spectrometry to unambiguously determine closely related strains that are difficult to distinguish by only relying on protein mass pattern detection. Conclusions With the method for bacterial analysis, we could identify fire blight pathogens from a variety of biological sources. The method can be used for a number of additional bacterial genera. Moreover, the mass spectrometry approach presented allows the integration of data from different biological levels such as the genome and the proteome.

Gene-for-gene relationship in the host–pathogen system Malus × robusta 5–Erwinia amylovora

Fire blight is a destructive bacterial disease caused by Erwinia amylovora affecting plants in the family Rosaceae, including apple. Host resistance to fire blight is present mainly in accessions of Malus spp. and is thought to be quantitative in this pathosystem. In this study we analyzed the importance of the E. amylovora effector avrRpt2(EA) , a homolog of Pseudomonas syringae avrRpt2, for resistance of Malus × robusta 5 (Mr5). The deletion mutant E. amylovora Ea1189ΔavrRpt2(EA) was able to overcome the fire blight resistance of Mr5. One single nucleotide polymorphism (SNP), resulting in an exchange of cysteine to serine in the encoded protein, was detected in avrRpt2(EA) of several Erwinia strains differing in virulence to Mr5. E. amylovora strains encoding serine (S-allele) were able to overcome resistance of Mr5, whereas strains encoding cysteine (C-allele) were not. Allele specificity was also observed in a coexpression assay with Arabidopsis thaliana RIN4 in Nicotiana benthamiana. A homolog of RIN4 has been detected and isolated in Mr5. These results suggest a system similar to the interaction of RPS2 from A. thaliana and AvrRpt2 from P. syringae with RIN4 as guard. Our data are suggestive of a gene-for-gene relationship for the host-pathogen system Mr5 and E. amylovora.

Complete Genome Sequences of Three Erwinia amylovora Phages Isolated in North America and a Bacteriophage Induced from an Erwinia tasmaniensis Strain

Fire blight, a plant disease of economic importance caused by Erwinia amylovora, may be controlled by the application of bacteriophages. Here, we provide the complete genome sequences and the annotation of three E. amylovora-specific phages isolated in North America and genomic information about a bacteriophage induced by mitomycin C treatment of an Erwinia tasmaniensis strain that is antagonistic for E. amylovora. The American phages resemble two already-described viral genomes, whereas the E. tasmaniensis phage displays a singular genomic sequence in BLAST searches.

Detection of Erwinia species from the apple and pear flora by mass spectroscopy of whole cells and with novel PCR primers

Aims:u2002 To detect the apple and pear pathogens Erwinia amylovora and Erwinia pyrifoliae as well as the related epiphytes Erwinia tasmaniensis and Erwinia billingiae, we created novel PCR primers and also applied them to a series of other plant‐associated bacteria as control. To facilitate fast diagnosis, we used matrix‐assisted laser desorption ionization–time‐of‐flight mass spectrometry (MALDI–TOF MS).

Molecular and physiological properties of bacteriophages from North America and Germany affecting the fire blight pathogen Erwinia amylovora.

For possible control of fire blight affecting apple and pear trees, we characterized Erwinia amylovora phages from North America and Germany. The genome size determined by electron microscopy (EM) was confirmed by sequence data and major coat proteins were identified from gel bands by mass spectroscopy. By their morphology from EM data, φEa1h and φEa100 were assigned to the Podoviridae and φEa104 and φEa116 to the Myoviridae. Host ranges were essentially confined to E. amylovora, strains of the species Erwinia pyrifoliae, E. billingiae and even Pantoea stewartii were partially sensitive. The phages φEa1h and φEa100 were dependent on the amylovoran capsule of E. amylovora, φEa104 and φEa116 were not. The Myoviridae efficiently lysed their hosts and protected apple flowers significantly better than the Podoviridae against E. amylovora and should be preferred in biocontrol experiments. We have also isolated and partially characterized E. amylovora phages from apple orchards in Germany. They belong to the Podoviridae or Myoviridae with a host range similar to the phages isolated in North America. In EM measurements, the genome sizes of the Podoviridae were smaller than the genomes of the Myoviridae from North America and from Germany, which differed from each other in corresponding nucleotide sequences.

Transgenic Apple Plants Expressing Viral EPS-Depolymerase: Evaluation of Resistance to the Phytopathogenic Bacterium Erwinia amylovora

The cultivated apple is the most important fruit crop in Europe. In various countries, large breeding programmes were established for apple to select new stable cropping, disease resistant varieties with an excellent fruit quality. Apple has been also one of the prime targets for genetic manipulation in fruit tree species since in 1989 James et al. reported on transgenic apple plants of the non-commercial cultivar ‘Greensleeves’. Subsequently, transgenic plants were produced using Agrobacterium infection of leaf explants obtained from proliferating shoot cultures (Maheswaran et al., 1992; Sriskandarajah et al., 1994, Yao et al., 1995; De Bondt et al., 1996; Puite and Schaart, 1996). Most studies on apple transformation have focused on the transmission of agronomically important genes to utilize improved genotypes of cultivars commercially established in fruit production. The improvement is mainly focused on apple storage ability (Yao et al., 2000) and on resistance to main diseases (Ko et al., 1999) and insects (James et al., 1993).

Differentiation of Erwinia amylovora and Erwinia pyrifoliae Strains with Single Nucleotide Polymorphisms and by Synthesis of Dihydrophenylalanine

Fire blight has spread from North America to New Zealand, Europe, and the Mediterranean region. We were able to differentiate strains from various origins with a novel PCR method. Three Single Nucleotide Polymorphisms (SNPs) in the Erwinia amylovora genome were characteristic of isolates from North America and could distinguish them from isolates from other parts of the world. They were derived from the galE, acrB, and hrpA genes of strains Ea273 and Ea1/79. These genes were analyzed by conventional PCR (cPCR) and quantitative PCR (qPCR) with differential primer annealing temperatures. North-American E. amylovora strains were further differentiated according to their production of l-2,5-dihydrophenylalanine (DHP) as tested by growth inhibition of the yeast Rhodotorula glutinis. E. amylovora fruit tree (Maloideae) and raspberry (rubus) strains were also differentiated by Single Strand Conformational Polymorphism analysis. Strains from the related species Erwinia pyrifoliae isolated in Korea and Japan were all DHP positive, but were differentiated from each other by SNPs in the galE gene. Differential PCR is a rapid and simple method to distinguish E. amylovora as well as E. pyrifoliae strains according to their geographical origin.

Tasmancin and lysogenic bacteriophages induced from Erwinia tasmaniensis strains.

Mitomycin C treatment of Erwinia tasmaniensis strains from Australia induced prophages and the expression of bacteriocins. The bacteriocin named tasmancin inhibited E. tasmaniensis strains from South Africa and Germany. A gene cluster with a klebicin-related operon and an immunity protein was detected on plasmid pET46 from E. tasmaniensis strain Et1/99. PCR reactions using primers directed to this region produced signals for several strains originating from Australia, but not for strains isolated in South Africa and Germany. The latter isolates lacked plasmid pET46. Bacteriophages were induced from E. tasmaniensis strains Et88 and Et14/99, both isolates from South-Eastern Australia. These phages formed plaques on several other strains from this region, as well as on E. tasmaniensis strains from South Africa and Germany. Sequencing revealed similarity of phages ϕEt88 and ϕEt14, which shared the host range on E. tasmaniensis strains. Bacteriophages and tasmancin may interfere with the viability of several related E. tasmaniensis strains in the environment of carrier strains.

Unifying bacteria from decaying wood with various ubiquitous Gibbsiella species as G. acetica sp. nov. based on nucleotide sequence similarities and their acetic acid secretion

Bacteria were isolated from necrotic apple and pear tree tissue and from dead wood in Germany and Austria as well as from pear tree exudate in China. They were selected for growth at 37 °C, screened for levan production and then characterized as Gram-negative, facultatively anaerobic rods. Nucleotide sequences from 16S rRNA genes, the housekeeping genes dnaJ, gyrB, recA and rpoB alignments, BLAST searches and phenotypic data confirmed by MALDI-TOF analysis showed that these bacteria belong to the genus Gibbsiella and resembled strains isolated from diseased oaks in Britain and Spain. Gibbsiella-specific PCR primers were designed from the proline isomerase and the levansucrase genes. Acid secretion was investigated by screening for halo formation on calcium carbonate agar and the compound identified by NMR as acetic acid. Its production by Gibbsiella spp. strains was also determined in culture supernatants by GC/MS analysis after derivatization with pentafluorobenzyl bromide. Some strains were differentiated by the PFGE patterns of SpeI digests and by sequence analyses of the lsc and the ppiD genes, and the Chinese Gibbsiella strain was most divergent. The newly investigated bacteria as well as Gibbsiella querinecans, Gibbsiella dentisursi and Gibbsiella papilionis, isolated in Britain, Spain, Korea and Japan, are taxonomically related Enterobacteriaceae, tolerate and secrete acetic acid. We therefore propose to unify them in the species Gibbsiella acetica sp. nov.

Identification and genetics of 6-thioguanine secreted by Erwinia species and its interference with the growth of other bacteria

We identified a compound in culture supernatants of Erwinia species, such as Erwinia amylovora, E. pyrifoliae, E. billingiae, E. tasmaniensis, E. persicina and E. rhapontici absorbing at 340xa0nm, which was associated before with the yellow pigment produced by E. amylovora on media containing copper ions. The compound was purified from E. tasmaniensis strain Et1/99 supernatants by chromatography on Dowex-1 and Dowex-50 columns and identified by HPLC/MS and NMR analysis as 6-thioguanine (6TG). Its signal at 167xa0Da matched with the expected molecular mass. By random mutagenesis with miniTn5, we obtained mutants defective in the genes for pyrimidine and purine metabolism. A specific gene cluster with ycf genes described by us before, absent in the corresponding region of Escherichia coli, was identified in the genome sequence of three Erwinia species and named tgs region for thioguanine synthesis. Clones of the tgs gene cluster promoted 6TG synthesis and secretion in E. coli, when the bacteria were grown in minimal medium supplemented with amino acids. 6TG was bacteriostatic for E. coli and Salmonella typhimurium strains, with cell growth resumed after prolonged incubation. Similar results were obtained with P. agglomerans strains. Bacteria from the genus Pectobacterium were barely and Rahnella or Gibbsiella species were not inhibited by 6TG. Adenine and guanine relieved the toxic effect of 6TG on E. coli. Non-producing strains were fully virulent on host plants. 6TG synthesis may help erwinias to interfere with growth of some microorganisms in the environment.