Pseudomonas aeruginosa and a Proteomic Approach to Bacterial Pathogenesis

Pseudomonas aeruginosa is a Gram-negative bacterium that is ubiquitous in the environment and can cause a variety of diseases in compromised patients. The genome of P. aeruginosa strain PAO1 has been reported to contain 5570 potential proteins. The value of this genomic database is that new proteins can be recognized to use as diagnostic markers, novel drug targets, and to better understand the physiology of this organism. However, similar to what has been observed in other sequenced bacterial genomes, approximately one third of the potential proteins have no known function. This is somewhat surprising given the long-standing interest in P. aeruginosa as an opportunistic pathogen. Obviously new tools, in addition to sequence similarity analysis, are needed to determine the role of these proteins. Proteomics using two-dimensional gel electrophoresis followed by mass spectrometry to detect and identify P. aeruginosa proteins represents a novel approach to address this gap.     

High-Throughput Expression of C. elegans Proteins

Proteome-scale studies of protein three-dimensional structures should provide valuable information for both investigating basic biology and developing therapeutics. Critical for these endeavors is the expression of recombinant proteins. We selected Caenorhabditis elegans as our model organism in a structural proteomics initiative because of the high quality of its genome sequence and the availability of its ORFeome, protein-encoding open reading frames (ORFs), in a flexible recombinational cloning format. We developed a robotic pipeline for recombinant protein expression, applying the Gateway cloning/expression technology and utilizing a stepwise automation strategy on an integrated robotic platform. Using the pipeline, we have carried out heterologous protein expression experiments on 10,167 ORFs of C. elegans. With one expression vector and one Escherichia coli strain, protein expression was observed for 4854 ORFs, and 1536 were soluble. Bioinformatics analysis of the data indicates that protein hydrophobicity is a key determining factor for an ORF to yield a soluble expression product. This protein expression effort has investigated the largest number of genes in any organism to date. The pipeline described here is applicable to high-throughput expression of recombinant proteins for other species, both prokaryotic and eukaryotic, provided that ORFeome resources become available.     

Genomic and proteomic characterization of a thermophilic Geobacillus bacteriophage GBSV1

Phages are present wherever life is found, and play roles in many biogeochemical and ecological processes. The thermophilic bacteriophages, however, have not been well studied. In this study, phage GBSV1 was obtained from a thermophilic bacterium Geobacillus sp. 6k51 isolated from a hot spring. GBSV1 contains a double-stranded linear DNA of 34,683 bp, which encodes 54 putative open reading frames (ORFs). Thirty three of these 54 ORFs exhibit sequence similarities to genes from 7 species of Geobacillus or Bacillus bacteria, as well as of bacteriophages infecting these bacteria. Twenty-two ORFs have been functionally annotated based on both their sequence similarities to known genes and predicted Pfam protein domains. Five structural proteins of the purified GBSV1 virion have been identified by proteomic analyses. Surprisingly, 7 of the GBSV1 ORFs share sequence similarities with genes from bacteria relevant to human diseases. This is the first report that genes of human disease-inducing bacteria are found in a thermophilic phage. It is suggested that thermophilic phages may be the potential evolutionary link between thermophiles and human pathogens. The characterization of GBSV1 may possibly lead to new insights into virus–host interactions and to a better understanding of gene transfers and evolution of life on earth in general.     

High-throughput functional profiling of the human fungal pathogen Candida albicans genome

Candida albicans is a major fungal pathogen of humans. Although its genome has been sequenced more than two decades ago, there are still over 4300 uncharacterized C. albicans genes. We previously generated an ORFeome as well as a collection of destination vectors to facilitate overexpression of C. albicans ORFs. Here, we report the construction of ～2500 overexpression mutants and their evaluation by in vitro spotting on rich medium and in a liquid pool experiment in rich medium, allowing the identification of genes whose overexpression has a fitness cost. The candidates were further validated at the individual strain level. This new resource allows large-scale screens in different growth conditions to be performed routinely. Altogether, based on the concept of identifying functionally related genes by cluster analysis, the availability of this overexpression mutant collection will facilitate the characterization of gene functions in C. albicans.     

Identification of virulence genes of Helicobacter pylori by random insertion mutagenesis

The complete genome of the gram-negative bacterial pathogen Helicobacter pylori, an important etiological agent of gastroduodenal disease in humans, has recently been published. This sequence revealed that the putative products of roughly one-third of the open reading frames (ORFs) have no significant homology to any known proteins. To be able to analyze the functions of all ORFs, we constructed an integration plasmid for H. pylori and used it to generate a random mutant library in this organism. This integration plasmid, designated pBCalpha3, integrated randomly into the chromosome of H. pylori. To test the capacity of this library to identify virulence genes, subsets of this library were screened for urease-negative mutants and for nonmotile mutants. Three urease-negative mutants in a subset of 1,251 mutants (0.25%) and 5 nonmotile mutants in a subset of 180 mutants (2.7%) were identified. Analysis of the disrupted ORFs in the urease-negative mutants revealed that two had disruptions of genes of the urease locus, ureB and ureI, and the third had a disruption of a unrelated gene; a homologue of deaD, which encodes an RNA helicase. Analysis of the disrupted ORFs in the nonmotile mutants revealed one ORF encoding a homologue of the paralyzed flagellar protein, previously shown to be involved in motility in Campylobacter jejuni. The other four ORFs have not been implicated in motility before. Based on these data, we concluded that we have generated a random insertion library in H. pylori that allows for the functional identification of genes in H. pylori.     

Closing in on the C. elegans ORFeome by cloning TWINSCAN predictions

The genome of Caenorhabditis elegans was the first animal genome to be sequenced. Although considerable effort has been devoted to annotating it, the standard WormBase annotation contains thousands of predicted genes for which there is no cDNA or EST evidence. We hypothesized that a more complete experimental annotation could be obtained by creating a more accurate gene-prediction program and then amplifying and sequencing predicted genes. Our approach was to adapt the TWINSCAN gene prediction system to C. elegans and C. briggsae and to improve its splice site and intron-length models. The resulting system has 60% sensitivity and 58% specificity in exact prediction of open reading frames (ORFs), and hence, proteins-the best results we are aware of any multicellular organism. We then attempted to amplify, clone, and sequence 265 TWINSCAN-predicted ORFs that did not overlap WormBase gene annotations. The success rate was 55%, adding 146 genes that were completely absent from WormBase to the ORF clone collection (ORFeome). The same procedure had a 7% success rate on 90 Worm Base "predicted" genes that do not overlap TWINSCAN predictions. These results indicate that the accuracy of WormBase could be significantly increased by replacing its partially curated predicted genes with TWINSCAN predictions. The technology described in this study will continue to drive the C. elegans ORFeome toward completion and contribute to the annotation of the three Caenorhabditis species currently being sequenced. The results also suggest that this technology can significantly improve our knowledge of the "parts list" for even the best-studied model organisms.     

Characterization of a newly discovered Mu-like bacteriophage, RcapMu, in Rhodobacter capsulatus strain SB1003

The α-proteobacterium Rhodobacter capsulatus is a model organism for the study of bacterial photosynthesis and the bacteriophage-like gene transfer agent. Characterization of phages that infect Rhodobacter is extremely rare, and scarce for the α-proteobacteria in general. Here, we describe the discovery of the only functional Mu-like transposing phage to have been identified in the α-proteobacteria, RcapMu, resident in the genome-sequenced R. capsulatus SB1003 strain. RcapMu packages ~ 42 kb of total DNA, including < 3 kb of host DNA with no conserved motifs, indicative of replicative transposition with little insertion site preference. The phage genome contains 58 ORFs with comparable organization to known transposable phages. Shotgun proteomics of purified RcapMu particles detected all proteins with predicted structural functions as well as seven hypothetical proteins. Overall, comparison of RcapMu to enterobacteria phage Mu and other Mu-like phages revealed only regional homology to these phages, providing further evidence for the promiscuous, modular nature of bacteriophage evolution.     

Functional genomics of Escherichia coli in Japan

Completion of the genome sequence of the model bacterium Escherichia coli has produced nearly 2000 open reading frames (ORFs) that remain to be functionally characterized. To accomplish this goal, we have organized a working project team in Japan and have begun construction of clones containing each of the putative ORFs. The procedure has been conceived such that we shall be able to perform systematic analysis of the shut-off as well as forced expression in vivo of each ORF and purification of its protein product for further biochemical studies. In addition, we have started a collection of various genetic and biochemical data of E. coli published in the past, and analyses of the data from a bio-informatics point of view. Thus, we aim at reaching complete understanding of this model organism in the near future.     

MAKER: an easy-to-use annotation pipeline designed for emerging model organism genomes

We have developed a portable and easily configurable genome annotation pipeline called MAKER. Its purpose is to allow investigators to independently annotate eukaryotic genomes and create genome databases. MAKER identifies repeats, aligns ESTs and proteins to a genome, produces ab initio gene predictions, and automatically synthesizes these data into gene annotations having evidence-based quality indices. MAKER is also easily trainable: Outputs of preliminary runs are used to automatically retrain its gene-prediction algorithm, producing higher-quality gene-models on subsequent runs. MAKER's inputs are minimal, and its outputs can be used to create a GMOD database. Its outputs can also be viewed in the Apollo Genome browser; this feature of MAKER provides an easy means to annotate, view, and edit individual contigs and BACs without the overhead of a database. As proof of principle, we have used MAKER to annotate the genome of the planarian Schmidtea mediterranea and to create a new genome database, SmedGD. We have also compared MAKER's performance to other published annotation pipelines. Our results demonstrate that MAKER provides a simple and effective means to convert a genome sequence into a community-accessible genome database. MAKER should prove especially useful for emerging model organism genome projects for which extensive bioinformatics resources may not be readily available.     

Genomic analysis of bacteriophage PBECO4 infecting Escherichia coli O157:H7

Escherichia coli O157:H7 is a human pathogen. We isolated a novel bacteriophage infecting this bacterium from a sewage water treatment facility. Phage PBECO4 belongs to the family Myoviridae, having an isometric head and a contractile tail. It has a linear double-stranded DNA genome of 348,113 base pairs in length with a GC content of 34.09 %. Whole-genome sequencing revealed that PBECO4 is distantly related to enterobacteria phage vB_KleM_RaK2, with 10 % similarity, and Cronobacter phage vB_CsaM_GAP32 with 6 % similarity. Five hundred fifty-one putative open reading frames (ORFs) and six tRNA genes were found. Eight ORFs are related to genes encoding structural proteins, nine to DNA packaging, two to DNA lysis activity, and 42 to replication and regulation. Four hundred ninety ORFs have not been functionally annotated.     

Immunoproteomics to examine cystic fibrosis host interactions with extracellular Pseudomonas aeruginosa proteins

The lungs of patients with cystic fibrosis (CF) are typically chronically infected with Pseudomonas aeruginosa. We used an immunoproteomics approach to analyze the responses of patients to secreted P. aeruginosa proteins. Extracellular proteins from P. aeruginosa strain PAO1 that had been grown to stationary phase were separated by two-dimensional polyacrylamide gel electrophoresis and analyzed by Western blotting using sera from four chronically infected patients. Sera from all four patients detected multiple extracellular proteins. The identities of selected proteins recognized by antisera were determined. Production of at least four of these proteins (azurin and three proteases: elastase, PrpL, and PasP) is governed by quorum sensing, consistent with active bacterial quorum sensing in the lungs of CF patients. The CF lung is generally thought to be an iron-deficient environment for infecting bacteria, and growing the bacteria in the presence of an iron-chelating agent, ethylene-diamine-di(o-hydroxyphenylacetic acid), enabled detection of additional proteins that were recognized by patient sera. The sera also detected multiple proteins from cells in the logarithmic growth phase, and protein identification suggested that most of these were the result of cell lysis or secretion in membrane vesicles. Comparison with extracellular proteins from a second P. aeruginosa strain, strain Pa4, showed that many proteins recognized by patient sera are common to both strains, although there are also some strain-specific extracellular proteins. Our data show that while there are some differences in the responses of different patients to P. aeruginosa, there are also many similarities, and that an immunoproteomics approach enables the identification of proteins that are made by P. aeruginosa during infection.     

Complete nucleotide sequence of cherry necrotic rusty mottle virus

Summary.  A virus closely related to cherry green ring mottle virus (CGRMV) was isolated from a tree displaying typical symptoms of cherry necrotic rusty mottle disease. We have named this virus cherry necrotic rusty mottle virus (CNRMV) and report here its complete genomic sequence as determined from overlapping cloned cDNAs. CNRMV has a genome of 8,432 nucleotides excluding the 3′ poly(A) sequence and codes for 7 significant open reading frames (ORFs). Five of these ORFs are conserved among all fovea-, allexi-, potex- and carlaviruses and code for a methyltransferase/helicase/polymerase polypeptide, the triple gene block movement proteins and the coat protein. Two further ORFs, ORFs 2a and 5a, are nested completely within ORFs 2 and 5, respectively. The putative translation products from these ORFs display sequence similarity with putative translation products from two similarly nested ORFs present in the CGRMV genome. The function of these two ORFs is unknown, nor are they conserved among other related viruses. Received April 21, 2000 Accepted July 6, 2000     

Genetic analysis of tomato golden mosaic virus: ORF AL2 is required for coat protein accumulation while ORF AL3 is necessary for efficient DNA replication

Tomato golden mosaic virus (TGMV) is a geminivirus whose genome is divided between two DNA components, designated A and B. The TGMV genome contains six open reading frames (ORFs) which can encode proteins of greater than 10 kDa. We have used a protoplast transfection system to determine the effects of viral proteins, as defined by these ORFs, on the accumulation of viral DNA in infected cells. The accumulation of cost protein was also examined in leaf discs. Our results indicate that mutations in ORFs AR1 and AL2 do not affect viral double-stranded DNA (dsDNA) levels, although AR1 and AL2 mutants accumulate only small amounts of single-stranded viral DNA (ssDNA). In contrast, a large reduction in both ss- and dsDNA levels is observed when a mutation is introduced into ORF AL3. Mutations within either of the two DNA B ORFs do not affect DNA replication. The AL3, BR1, and BL1 mutants are capable of synthesizing coat protein; however, coat protein is not detected in leaf discs inoculated with AR1 or AL2 mutants. Testable models are proposed to explain the influence of AL2 protein on coat protein accumulation and to account for the stimulation of viral DNA synthesis mediated by the AL3 gene product.     

Genome exploration of six variants of the Ostreid Herpesvirus 1 and characterization of large deletion in OsHV-1μVar specimens

The genetic polymorphism of the Ostreid Herpesvirus 1 (OsHV-1) has generally been investigated in three areas: ORFs 4/5, ORFs 42/43, and ORFs 35 to 38. The present study, however, focuses on 40 ORFs, representing 30% of the OsHV-1 genome, encoding four categories of putative proteins: 4 ORFs encoding putative inhibitor of apoptosis proteins; 17 ORFs encoding membrane proteins; 10 ORFs encoding secreted proteins; and 9 ORFs encoding RING finger proteins. The potential role of these proteins in major steps of the life cycle of the OsHV-1 motivated their selection. Seven specimens have been selected in accordance with their nucleotide variations in the C region (area located between the end of the ORF4 and the beginning of ORF 5): 3 OsHV-1 μVar specimens, 2 OsHV-1 μVar Δ9, one specimen of OsHV-1 μVar Δ15, and one OsHV-1 specimen (reference control) close to the reference genome to validate PCRs. The OsHV-1 μVar is mainly characterized by a deletion of 12 consecutive nucleotides followed by a deletion of one adenine in a microsatellite area located in the C region. A representation of nucleotide modifications between the different specimens was performed by building evolutionary trees with respect to the category of ORFs. This phylogenetic analysis revealed two groups: the first one corresponded to the reference control and the reference genome AY509253, and the second one included the 6 OsHV-1 variants. These results suggest that the two main groups come from the same common ancestor, and that the divergence between the reference OsHV-1 and its variants occurred quite far back in time. Moreover, consequences of nucleotide variations in the amino acid sequences, especially the change of the N glycoslyation sites, were investigated. Herein is the first report of four important deletions in these OsHV-1 μVar variants: a deletion of 1385 bp in ORF 11; a deletion of 599 bp in ORF 48; a deletion of 3549 bp in ORFs 61 to 64; and a deletion of 712 bp in ORF 114. The size of the deletions differed between OsHV-1 μVar specimens, OsHV-1 μVar Δ9 specimens, and the OsHV-1 μVar Δ15 specimen. These zones seem to correspond to special points of gene rearrangements for producing new proteins. Further investigation necessary proves to link such nucleotide modifications with consequences of protein functions in the OsHV-1 life cycle.     

Herpesvirus ICP18.5 and DNA-binding protein genes are conserved in equine herpesvirus-1

The genome of equine herpesvirus-1 (EHV-1) contained three open reading frames (ORFs) in a 3.9 kbpBamHI-SmaI fragment at 0.38–0.41 map units in the long unique region. The most 5′ ORF encoded the carboxy terminus of a protein with 45–55 percent amino acid homology to the DNA-binding proteins (ICP8-DBP) of four other alphaherpesviruses. The middle ORF translated to a polypeptide of 775 residues with 43–55% homology to the ICP18.5 proteins. The most 3′ ORF encoded the EHV-1 glycoprotein B (gB) gene. Three mRNAs of 4.3, 4.4–4.8, and 3.5–3.9 kb (corresponding to the three sequenced ORFs) were all transcribed from the same strand. The gene order of this group was conserved in all herpesviruses examined.     

Role of Adherence in the Pathogenesis of Pseudomonas aeruginosa Lung Infection in Cystic Fibrosis Patients

A correlation has been demonstrated between the in vitro adherence of Pseudomonas aeruginosa to upper respiratory tract epithelium and colonization of the respiratory tract by this organism. Twenty patients with cystic fibrosis (CF) and 20 age-matched controls were examined in this study. All of the CF patients but none of the controls were colonized with P. aeruginosa at the time of study. P. aeruginosa adherence to isolated epithelial cells, as determined by an in vitro assay, was 19.1 ± 1.1 bacteria per buccal epithelial cell in the CF patients and 2.3 ± 0.3 bacteria per cell in the controls (P < 0.01). P. aeruginosa strains of the mucoid colony type adhered in significantly lower numbers to buccal epithelial cells than did strains of the rough colony type (1.8 + 0.1 versus 24.8 ± 0.9, P < 0.001). This difference might explain the common observation that the initial pseudomonas colonization of the respiratory tract of CF patients is due to organisms of the rough colony type. We have further demonstrated that increased P. aeruginosa adherence in vitro varies directly with the loss of a protease-sensitive glycoprotein, fibronectin, from the cell surface, as well as increased levels of salivary proteases in CF patients. When examined by a direct radioimmune binding assay, buccal cells from CF patients possessed only 17% of the total cell surface fibronectin present on similar cells obtained from controls. Salivary protease levels, as measured by ¹²⁵I release from an ¹²⁵I-labeled insoluble fibrin matrix, were increased about threefold in CF patients versus controls. Thus, colonization of the respiratory tract by P. aeruginosa in CF patients correlates well with buccal cell adherence of this organism; increased adherence is associated with decreased amounts of fibronectin on respiratory epithelial cell surfaces and increased levels of salivary proteases.     

Complete genome sequence of marine bacterium Pseudoalteromonas phenolica bacteriophage TW1

For molecular study of marine bacteria Pseudoalteromonas phenolica using bacteriophage, a novel bacteriophage, TW1, belonging to the family Siphoviridae, was isolated, and its genome was completely sequenced and analyzed. The phage TW1 genome consists of 39,940-bp-length double-stranded DNA with a GC content of 40.19 %, and it was predicted to have 62 open reading frames (ORFs), which were classified into functional groups, including phage structure, packaging, DNA metabolism, regulation, and additional function. The phage life style prediction using PHACTS showed that it may be a temperate phage. However, genes related to lysogeny and host lysis were not detected in the phage TW1 genome, indicating that annotation information about P. phenolica phages in the genome databases may not be sufficient for the functional prediction of their encoded proteins. This is the first report of a P. phenolica-infecting phage, and this phage genome study will provide useful information for further molecular research on P. phenolica and its phage, as well as their interactions.