Acinetobacter baumannii is recognized as an emerging bacterial pathogen because of traits such as prolonged survival in a desiccated state, effective nosocomial transmission, and an inherent ability to acquire antibiotic resistance genes. A pressing need in the field of A. baumannii research is a suitable model strain that is representative of current clinical isolates, is highly virulent in established animal models, and can be genetically manipulated. To identify a suitable strain, a genetically diverse set of recent U.S. military clinical isolates was assessed. Pulsed-field gel electrophoresis and multiplex PCR determined the genetic diversity of 33 A. baumannii isolates. Subsequently, five representative isolates were tested in murine pulmonary and Galleria mellonella models of infection. Infections with one strain, AB5075, were considerably more severe in both animal models than those with other isolates, as there was a significant decrease in survival rates. AB5075 also caused osteomyelitis in a rat open fracture model, while another isolate did not. Additionally, a Tn5 transposon library was successfully generated in AB5075, and the insertion of exogenous genes into the AB5075 chromosome via Tn7 was completed, suggesting that this isolate may be genetically amenable for research purposes. Finally, proof-of-concept experiments with the antibiotic rifampin showed that this strain can be used in animal models to assess therapies under numerous parameters, including survival rates and lung bacterial burden. We propose that AB5075 can serve as a model strain for A. baumannii pathogenesis due to its relatively recent isolation, multidrug resistance, reproducible virulence in animal models, and genetic tractability.
Helicobacter pylori persistently colonizes the stomach of the majority of the world's population and is a tremendous medical burden due to its causal role in diverse gastric maladies. Since the stomach is a constantly changing environment, successful colonization of H. pylori within this niche requires regulation of bacterial gene expression to cope with the environmental fluctuations. In H. pylori, the ferric uptake regulator (Fur) has been shown to play an intricate role in adaptation of the bacterium to two conditions known to oscillate within the gastric mucosa: iron limitation and low pH. To extend our knowledge of the process of regulation and adaptation in H. pylori, we show that Fur is required for efficient colonization of the Mongolian gerbil: the mutant strain exhibits a 100-fold increase in the 50% infectious dose, as well as a 100-fold defect in competitive colonization, when coinfected with wild-type bacteria. Furthermore, we used DNA microarrays to identify genes whose expression was altered in a Fur-deficient strain. We show that the Fur regulon of H. pylori consists of approximately 30 genes, most of which have been previously annotated as acid stress associated. Finally, we investigate the role of Fur in acid-responsive modulation of gene expression and show that a large number of genes are aberrantly expressed in the Fur mutant specifically upon acid exposure. This fact likely explains the requirement for this regulator for growth and colonization in the stomach.
Cholera is a severe diarrheal disease caused by specific serogroups of Vibrio cholerae that are pathogenic to humans. The disease does not persist in a chronic state in humans or animals. The pathogen is naturally present as a free-living organism in the environment. Recently, it was suggested that egg masses of the nonbiting midge Chironomus sp. (Diptera) harbor and serve as a nutritive source for V. cholerae, thereby providing a natural reservoir for the organism. Here we report that V. cholerae O9, O1, and O139 supernatants lysed the gelatinous matrix of the chironomid egg mass and inhibited eggs from hatching. The extracellular factor responsible for the degradation of chironomid egg masses (egg mass degrading factor) was purified from V. cholerae O9 and O139 and was identified as the major secreted hemagglutinin/protease (HA/P) of V. cholerae. The substrate in the egg mass was characterized as a glycoprotein. These findings show that HA/P plays an important role in the interaction of V. cholerae and chironomid egg masses.Cholera is a severe diarrheal disease that causes the death of many thousands of people each year and affects the lives of millions. This disease is caused by specific serogoups of Vibrio cholerae that are pathogenic to humans (22). Since 1991, the world has witnessed extension of the seventh pandemic into South America and South Africa, as well as the appearance of a previously unknown pathogenic serogroup of V. cholerae (O139) (23). The disease is not found in a chronic state in humans or animals, indicating that its natural reservoir is environmental (11).Chironomids (Diptera; Chironomidae), the nonbiting midges, are the most widely distributed and frequently the most abundant insects in freshwater (1). Females lay egg masses on the water's edge, and each mass contains hundreds of eggs encased in a layer of gelatinous material. The presence of several thousand egg masses at one site is not unusual. In extreme cases, gelatinous layers several centimeters thick are formed (3,18).Recently, we suggested that chironomid egg masses are an intermediate host reservoir for V. cholerae. Chironomus egg masses collected from a waste stabilization pond settled out overnight as thousands of individual eggs, most of which did not hatch. V. cholerae O9 was isolated from the degraded egg masses. When new freshly collected egg masses were reinfected with V. cholerae O9, the egg masses were destroyed. V. cholerae grew on the chironomid egg masses as a nutritive source (4).Hemagglutinin/protease (HA/P) is one of the main secreted proteases of V. cholerae, and it is usually associated with the stationary phase and starvation (2). HA/P was purified from V. cholerae O1 (7) and O139 strains (17), as well as from non-O1 strains (10, 16). All HA/P purified enzymes showed both hemagglutination and proteolytic activities. Honda et al. (10) compared the purified HA/P from V. cholerae O1 and non-O1 strains. They found that the proteases (or hemagglutinins) derived from V. cholerae O1 and non-O1 strains were immunolog...
Vibrio cholerae is the etiological agent of cholera. Its natural reservoir is the aquatic environment. To date, practical typing of V. cholerae is mainly serological and requires about 200 antisera. Simple sequence repeats (SSR), also termed VNTR (for variable number of tandem repeats), provide a source of high genomic polymorphism used in bacterial typing. Here we describe an SSR-based typing method that combines the variation in highly mutable SSR loci, with that of shorter, relatively more stable mononucleotide repeat (MNR) loci, for accurate and rapid typing of V. cholerae. Vibrio cholerae, a gram-negative bacterium, is the causal agent of the severe diarrheal disease cholera. Its natural reservoir is the aquatic environment (49, 84). Cholera pandemics are caused by specific serogroups of V. cholerae that are pathogenic only to humans (35,84). Since 1817, V. cholerae has caused a number of pandemics. The first seven were presumed to be caused by O1 serogroup of V. cholerae (68). In October 1992, a new serogroup, defined O139, caused a severe outbreak of cholera in southeast India. Within 10 months, the O139 serogroup was disseminated all over the Indian subcontinent and soon thereafter spread to 11 neighboring countries, temporarily displacing the O1 serogroups (64). Since then both serogroups coexist and are responsible for large outbreaks. Genomic studies indicated that O139 epidemic strain arose by horizontal acquisition of unique DNA (15, 47).Traditionally, V. cholerae classification is serological and requires about 200 antisera based on the somatic O antigen (72). Isolates of V. cholerae are divided into three major subgroups: O1, O139, and non-O1/non-O139, of which only the O1 and O139 serogroups are associated with cholera pandemics and epidemics. Non-O1, non-O139 serogroups are recognized as causative agents of sporadic and localized outbreaks (73). Pathogenic V. cholerae isolates carry virulence genes, such as the toxins genes ctxAB (25,65,68). The environmental V. cholerae strains from non-O1, non-O139 serogroups are a possible natural reservoir of potentially new emerging epidemic strains (67,73). This assumption is supported by the finding that some of these environmental strains harbor virulence genes (23) and thus are likely to evolve into novel pathogenic strains by horizontal gene transfer (24,25). The emergence of new pathogenic V. cholerae strains requires not only an efficient, rapid, and accurate identification tool but also a means for determining genetic relationships among environmental and clinical isolates.Genome-based bacterial identification and typing is essential for several disciplines, including taxonomy, epidemiology, determining phylogenetic relationships, and the study of evolutionary mechanisms. It allows distinguishing among strains within a species to monitor epidemics and routes of contamination. Recent advances in biotechnology have resulted in the development of numerous methods for microorganism typing that differ in their sensitivity, rapidity, complexity, discrimin...
Helicobacter pylori is an important human pathogen. However, the study of this organism is often limited by a relative shortage of genetic tools. In an effort to expand the methods available for genetic study, an endogenous H. pylori plasmid was modified for use as a transcriptional reporter and as a complementation vector. This was accomplished by addition of an Escherichia coli origin of replication, a kanamycin resistance cassette, a promoterless gfpmut3 gene, and a functional multiple cloning site to form pTM117. The promoters of amiE and pfr, two well-characterized Fur-regulated promoters, were fused to the promoterless gfpmut3, and green fluorescent protein (GFP) expression of the fusions in wild-type and ⌬fur strains was analyzed by flow cytometry under iron-replete and iron-depleted conditions. GFP expression was altered as expected based on current knowledge of Fur regulation of these promoters. RNase protection assays were used to determine the ability of this plasmid to serve as a complementation vector by analyzing amiE, pfr, and fur expression in wild-type and ⌬fur strains carrying a wild-type copy of fur on the plasmid. Proper regulation of these genes was restored in the ⌬fur background under high-and low-iron conditions, signifying complementation of both iron-bound and apo Fur regulation. These studies show the potential of pTM117 as a molecular tool for genetic analysis of H. pylori.
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