Role of iron in Yersinia pestis multiplication in normal mammalian blood sera

Y. pestis multiply in normal blood sera of susceptible and nonsusceptible animals at 28 degrees C, while at 37 degrees C bacteriostasis has been registered. Inhibition of the growth of Y. pestis at this temperature is due to the limited supply of iron to bacterial cells.     

Identification and cloning of a fur regulatory gene in Yersinia pestis.

Yersinia pestis is one of many microorganisms responding to environmental iron concentrations by regulating the synthesis of proteins and an iron transport system(s). In a number of bacteria, expression of iron uptake systems and other virulence determinants is controlled by the Fur regulatory protein. DNA hybridization analysis revealed that both pigmented and nonpigmented cells of Y. pestis possess a DNA locus homologous to the Escherichia coli fur gene. Introduction of a Fur-regulated beta-galactosidase reporter gene into Y. pestis KIM resulted in iron-responsive beta-galactosidase activity, indicating that Y. pestis KIM expresses a functional Fur regulatory protein. A cloned 1.9-kb ClaI fragment of Y. pestis chromosomal DNA hybridized specifically to the fur gene of E. coli. The coding region of the E. coli fur gene hybridized to a 1.1-kb region at one end of the cloned Y. pestis fragment. The failure of this clone to complement an E. coli fur mutant suggests that the 1.9-kb clone does not contain a functional promoter. Subcloning of this fragment into an inducible expression vector restored Fur regulation in an E. coli fur mutant. In addition, a larger 4.8-kb Y. pestis clone containing the putative promoter region complemented the Fur- phenotype. These results suggest that Y. pestis possesses a functional Fur regulatory protein capable of interacting with the E. coli Fur system. In Y. pestis Fur may regulate the expression of iron transport systems and other virulence factors in response to iron limitation in the environment. Possible candidates for Fur regulation in Y. pestis include genes involved in ferric iron transport as well as hemin, heme/hemopexin, heme/albumin, ferritin, hemoglobin, and hemoglobin/haptoglobin utilization.     

Pleiotropic effects of a Yersinia pestis fur mutation.

A Yersinia pestis fur mutation was constructed by insertionally disrupting the fur open reading frame. Analysis of a Fur-regulated beta-galactosidase reporter gene revealed a loss of iron regulation as a result of the fur mutation. trans complementation with the cloned Y. pestis fur gene restored iron regulation. The expression of most iron-regulated proteins was also deregulated by this mutation; however, a number of iron-repressible and two iron-inducible polypeptides retained normal regulation. Mutations in fur or hmsH, a gene encoding an 86-kDa surface protein required for hemin storage, increased the sensitivity of Y. pestis cells to the bacteriocin pesticin. Interestingly, the Y. pestis fur mutant lost temperature control of hemin storage; however, expression of the HmsH polypeptide was not deregulated. When grown with excess iron, a Y. pestis fur mutant possessing the 102-kb pigmentation locus exhibited severe growth inhibition and a dramatic increase in the number of spontaneous nonpigmented chromosomal deletion mutants present at late log phase. These results suggest that the Fur protein of Y. pestis is an important global regulator and that a separate Fur-independent iron regulatory system may exist.     

Characteristics of the process of transferrin iron utilization by Yersinia pestis at various incubation temperatures

The study has revealed that for the utilization of iron contained in transferrin the direct contact of Y. pestis with this metalloprotein is necessary. At 28 degrees C Y. pestis utilizes iron contained in transferrin. At 37 degrees C Y. pestis absorbs transferrin, but cannot utilize its iron, which is probably linked with disturbances in the system of the transfer of iron from the transferrin receptor complex into the bacterial cell.     

Changes in the oxygen-dependent metabolic activity of polymorphonuclear leukocytes from the peripheral blood and macrophages from the peritoneal exudate in the experimental infection of mice with the causative agent of plague

The subcutaneous infection of C57BL/6J mice and noninbred white mice with 40 LD100 of Y. pestis virulent strain has been found to produce synchronous changes in the oxygen-dependent metabolism (ODM) of peripheral blood neutrophils in the spontaneous or zymosan-, E. coli- and Y. pestis-stimulated variants of the NBT test. These changes can be divided into three phases: (I) the phase of a sharp drop in ODM activity; (II) the phase of the increase of this activity, occurring simultaneously with the penetration of Y. pestis cells into the blood stream; and (III) the phase of the terminal decrease of ODM activity as the cytotoxic lesion of phagocytic cells occurs. Peritoneal exudate macrophages show a more gradual decrease in ODM activity. The infection of the animals with 40,000 LD100 of Y. pestis has been found to produce an increase in the ODM activity of neutrophils, rapidly followed by its decrease to the zero level. Macrophages show phasic changes in their ODM activity, identical to changes in the ODM values of neutrophils in mice infected with 40 LD100 of Y. pestis.     

Accumulation of iron by yersiniae.

Escherichia coli, Bacillus megaterium, and three species of yersiniae grew rapidly without significant production of soluble siderophores in a defined iron-sufficient medium (20 microM Fe3+). In iron-deficient medium (0.1 to 0.3 microM Fe3+) all organisms showed reduced growth, and there was extensive production of siderophores by E. coli and B. megaterium. Release of soluble siderophores by Yersinia pestis, Y. pseudotuberculosis, or Y. enterocolitica in this medium was not detected. Citrate (1 mM) inhibited growth of yersiniae in iron-deficient medium, indicating that the organisms lack an inducible Fe3+-citrate transport mechanism. Uptake of 59Fe3+ by all yersiniae was an energy-dependent saturable process, showing increased accumulation after adaptation to iron-deficient medium. Growth of Y. pseudotuberculosis and Y. enterocolitica but not Y. pestis on iron-limited solid medium was enhanced to varying degrees by exogenous siderophores (desferal, schizokinen, aerobactin, and enterochelin). Only hemin (0.1 pmol) or a combination of inorganic iron plus protoporphyrin IX promoted growth of Y. pestis on agar rendered highly iron deficient with egg white conalbumin (10 microM). Growth of Y. pseudotuberculosis and Y. enterocolitica was stimulated on this medium by Fe3+ or hemin. These results indicate that hemin can serve as a sole source of iron for yersiniae and that the organisms possess an efficient cell-bound transport system for Fe3+.     

The Yfe system of Yersinia pestis transports iron and manganese and is required for full virulence of plague

Iron acquisition in Yersinia pestis is fundamental to the success of plague pathogenesis. We have previously identified an approximately 5.6 kb region (yfe) of Y. pestis genomic DNA, capable of restoring iron-deficient growth but not siderophore production to an Escherichia coli mutant (SAB11) incapable of synthesizing the siderophore, enterobactin. The yfe locus of Y. pestis, found in both pigmented (Pgm+) and nonpigmented (Pgm-) strains, comprises five genes arranged in two distinct operons (yfeA-D and yfeE ). The larger of these, yfeABCD, encodes an ABC transport system, whose expression is iron and Fur regulated and is repressed in cells grown in the presence of manganese. Cells from a Pgm-, Yfe- (DeltayfeAB ) mutant strain of Y. pestis exhibited reduced transport of both 55Fe and 54Mn. Furthermore, cells containing an intact yfe locus showed reduced 55Fe uptake when competing amounts of MnCl2 or ZnCl2 were present, whereas 54Mn uptake was inhibited by FeCl3 but not by ZnCl2. Similarly, yfe mutants of Y. pestis exhibited growth defects on media supplemented with the iron chelators 2,2'-dipyridyl or conalbumin. These growth defects were not relieved by supplementation with MnCl2. A ybt-, DeltayfeAB mutant of Y. pestis was completely avirulent in mice infected intravenously (LD50 > 1.7 x 107 cfu) compared with its parental ybt-, yfe+ strain, which had an LD50 of < 12. In addition, compared with its ybt+, yfe+ parent, a ybt+, DeltayfeAB mutant of Y. pestis had an approximately 100-fold increase in the LD50 from a subcutaneous route of infection. These data suggest that the Yfe and Ybt systems may function effectively to accumulate iron during different stages of the infectious process of bubonic plague.     

Use of protein microarray to identify gene expression changes of Yersinia pestis at different temperatures

Yersinia pestis is a bacterium that is transmitted between fleas, which have a body temperature of 26 °C, and mammalian hosts, which have a body temperature of 37 °C. To adapt to the temperature shift, phenotype variations, including virulence, occur. In this study, an antigen microarray including 218 proteins of Y. pestis was used to evaluate antibody responses in a pooled plague serum that was unadsorbed, adsorbed by Y. pestis cultivated at 26 °C, or adsorbed by Y. pestis cultivated at 26 and 37 °C to identify protein expression changes during the temperature shift. We identified 12 proteins as being expressed at 37 °C but not at 26 °C, or expressed at significantly higher levels at 37 °C than at 26 °C. The antibodies against 7 proteins in the serum adsorbed by Y. pestis cultivated at 26 and 37 °C remained positive, suggesting that they were not expressed on the surface of Y. pestis in LB broth in vitro or specifically expressed in vivo. This study proved that protein microarray and antibody profiling comprise a promising technique for monitoring gene expression at the protein level and for better understanding pathogenicity, to find new vaccine targets against plague.     

Role of the Yersinia pestis yersiniabactin iron acquisition system in the incidence of flea-borne plague

Plague is a flea-borne zoonosis caused by the bacterium Yersinia pestis. Y. pestis mutants lacking the yersiniabactin (Ybt) siderophore-based iron transport system are avirulent when inoculated intradermally but fully virulent when inoculated intravenously in mice. Presumably, Ybt is required to provide sufficient iron at the peripheral injection site, suggesting that Ybt would be an essential virulence factor for flea-borne plague. Here, using a flea-to-mouse transmission model, we show that a Y. pestis strain lacking the Ybt system causes fatal plague at low incidence when transmitted by fleas. Bacteriology and histology analyses revealed that a Ybt-negative strain caused only primary septicemic plague and atypical bubonic plague instead of the typical bubonic form of disease. The results provide new evidence that primary septicemic plague is a distinct clinical entity and suggest that unusual forms of plague may be caused by atypical Y. pestis strains.     

鼠疫溶菌疫苗免疫小鼠的体液免疫应答

为选择以F1抗原为主要有效成分的鼠疫溶菌疫苗(Whole cell lysate of Yersinia pestis vaccine,WCLY)的免疫程序,设计了这组试验。在37℃培养鼠疫EV菌,通过超声波裂解法制备鼠疫溶菌疫苗。设计(0,2周)、(0,4周)、(0,2,4周)三种免疫程序,以每剂总蛋白量7.9μg、31.5μg和126.0μg三个剂量皮下接种NIH小鼠。分别在第一针免疫后2、4、8、12周采集血清,通过间接ELISA检测抗鼠疫菌F1抗原和总抗原抗体。结果显示:免疫后血清抗体上升很快,2周内即可测出;无论哪种免疫程序,至12周时抗体滴度仍保持高水平;加强免疫后,抗体水平在4周或8周达到较高,可与活疫苗免疫者相比;溶菌疫苗的接种剂量为7.9μg时,动物只出现轻度不良反应。提示鼠疫溶菌疫苗需要两剂免疫,最短可间隔2周,接种剂量应不超过7.9μg,疫苗中应富含F1抗原。     

Effects of Y. pestis mouse toxin on carbohydrate metabolism in rats

Effects of intravenous Y. pestis mouse toxin (LD50) injection on glucose, lactate glucagon, insulin blood levels and cAMP liver content in dynamics of intoxication development were studied. Hypoglycemia, observed 2 hours after toxin administration seems not to be due to the enhanced glucose utilization in peripheral tissues because insulin blood level during this period was decreased and lactate concentration has not been changed. Glucagon content by 2-5 hour of shock was strong elevated. Proposal is made that Y. pestis mouse toxin might induce carbohydrate metabolism alterations via direct liver glucose synthesising enzymes inhibition rather than cAMP-dependent glycogenolysis and gluconeogenesis regulation disturbances in this organ.     

The high-pathogenicity island of Yersinia pseudotuberculosis can be inserted into any of the three chromosomal asn tRNA genes

Pathogenicity islands (PAIs) have been identified in several bacterial species. A PAI called high-pathogenicity island (HPI) and carrying genes involved in iron acquisition (yersiniabactin system) has been previously identified in Yersinia enterocolitica and Yersinia pestis . In this study, the HPI of the third species of Yersinia pathogenic for humans, Y. pseudotuberculosis , has been characterized. We demonstrate that the HPI of strain IP32637 has a physical and genetic map identical to that of Y. pestis . A gene homologous to the bacteriophage P4 integrase gene is located downstream of the asn tRNA locus that borders the HPI of strain IP32637. This int gene is at the same position on the HPI of all three pathogenic Yersinia species. However, in contrast to Y. pestis 6/69, the HPI of Y. pseudotuberculosis IP32637 is not invariably adjacent to the pigmentation segment and can be inserted at a distance ≥ 190 kb from this segment. Also, in contrast to Y. pestis and Y. enterocolitica , the HPI of Y. pseudotuberculosis IP32637 can precisely excise from the chromosome, and, strikingly, it can be found inserted in any of the three asn tRNA loci present on the chromosome of this species, one of which is adjacent to the pigmentation segment. The pigmentation segment, which is present in Y. pestis but not in Y. enterocolitica , is also present and well conserved in all strains of Y. pseudotuberculosis studied. In contrast, the presence and size of the HPIs vary depending on the serotype of the strain: an entire HPI is found in strains of serotypes I only, a HPI with a 9 kb truncation in its left-hand part that carries the IS 100 sequence and the psn and ybtE genes characterizes the strains of serotype III, and no HPI is found in strains of serotypes II, IV and V.     

The sensitivity of bacterial strains of Yersinia pestis isolated from voles to normal human serum]

The work deals with the results of the study of the viability of Y. pestis strains, isolated from voles in different natural foci of plague, in human normal serum (HNS) and its dependence on the assimilation of ions of exogenic iron. The cultures isolated at the Transcaucasian mountain focus of infection and having no small plasmid pYP were found highly sensitive to HNS. The introduction of the sources of iron, such as hemoglobin or ferritin, into the serum decreased its bactericidal effect.     

Exposure of small rodents to plague during epizootics in black-tailed prairie dogs

Plague, caused by the bacterium Yersinia pestis, causes die-offs of colonies of prairie dogs (Cynomys ludovicianus). It has been argued that other small rodents are reservoirs for plague, spreading disease during epizootics and maintaining the pathogen in the absence of prairie dogs; yet there is little empirical support for distinct enzootic and epizootic cycles. Between 2004 and 2006, we collected blood from small rodents captured in colonies in northern Colorado before, during, and for up to 2 yr after prairie dog epizootics. We screened 1,603 blood samples for antibodies to Y. pestis, using passive hemagglutination and inhibition tests, and for a subset of samples we cultured blood for the bacterium itself. Of the four species of rodents that were common in colonies, the northern grasshopper mouse (Onychomys leucogaster) was the only species with consistent evidence of plague infection during epizootics, with 11.1-23.1% of mice seropositive for antibody to Y. pestis during these events. Seropositive grasshopper mice, thirteen-lined ground squirrels (Spermophilus tridecemlineatus), and deer mice (Peromyscus maniculatus) were captured the year following epizootics. The appearance of antibodies to Y. pestis in grasshopper mice coincided with periods of high prairie dog mortality; subsequently, antibody prevalence rates declined, with no seropositive individuals captured 2 yr after epizootics. We did not detect plague in any rodents off of colonies, or on colonies prior to epizootics, and found no evidence of persistent Y. pestis infection in blood cultures. Our results suggest that grasshopper mice could be involved in epizootic spread of Y. pestis, and possibly, serve as a short-term reservoir for plague, but provide no evidence that the grasshopper mouse or any small rodent acts as a long-term, enzootic host for Y. pestis in prairie dog colonies.     

Development of a diagnostic test for Yersinia pestis by the polymerase chain reaction

A 501 bp caf1 gene fragment and a 443 bp of pla gene fragment carried by 100 kb (pFra) and 10 kb (pPst) species-specific extrachromosomal replicons, respectively, were used as targets to study the conditions under which DNA amplification by polymerase chain reaction (PCR) may be applied to detect and identify Yersinia pestis DNA in cell lysates of pure cultures and biological samples. The sensitivity limit of PCR with the crude cell lysates of Y. pestis EV was estimated as 10–50 cfu in reaction mixture. When target Y. pestis EV cells were mixed with fresh blood of white mice, which contained 0.4% potassium citrate, the PCR detection level varied from 400 to 100 cfu ml^-1 of blood depending on the method used for preparing the sample. In our tests PCR was effective for the detection of yersinia in the blood of white laboratory mice experimentally infected with virulent Y. pestis KM638 strain. This method can be considered convenient for routine detection and identification of Y. pestis.     

No evidence of persistent Yersina pestis infection at prairie dog colonies in north-central Montana

Sylvatic plague is a flea-borne zoonotic disease caused by the bacterium Yersinia pestis, which can cause extensive mortality among prairie dogs (Cynomys) in western North America. It is unclear whether the plague organism persists locally among resistant host species or elsewhere following epizootics. From June to August 2002 and 2003 we collected blood and flea samples from small mammals at prairie dog colonies with a history of plague, at prairie dog colonies with no history of plague, and from off-colony sites where plague history was unknown. Blood was screened for antibody to Y. pestis by means of enzyme-linked immunosorbent assay or passive hemagglutination assay and fleas were screened for Y. pestis DNA by polymerase chain reaction. All material was negative for Y. pestis including 156 blood samples and 553 fleas from colonies with a known history of plague. This and other studies provide evidence that Y. pestis may not persist at prairie dog colonies following an epizootic.     

The weak interaction of LcrV and TLR2 does not contribute to the virulence of Yersinia pestis

Yersinia pestis and the enteropathogenic Yersinia pseudotuberculosis and Yersinia enterocolitica share the virulence-antigen LcrV. Previously, using reverse genetics we have proven that LcrV contributes to the virulence of Y. enterocolitica serotype O:8 by inducing IL-10 via Toll-like receptor 2 (TLR2). However, both the ability of Y. pestis LcrV to activate TLR2 and a possible role of TLR2-dependent IL-10 induction by LcrV in Y. pestis are not yet known. To eliminate interference from additional protein sequences, we produced LcrVs without affinity tags from Y. pestis and from Y. enterocolitica O:8 (LcrVO:8). LcrVO:8 was much more potent in TLR2-activity than Y. pestis LcrV. To analyse the role of TLR2 in plague, we infected both wild-type and TLR2-/- mice subcutaneously with Y. pestis GB. While TLR2-/- mice exhibited lower blood levels of IL-10 (day 2 post-infection) and of the pro-inflammatory cytokines TNF-alpha, IFN-gamma and MCP-1 (day 4) than wild-type mice, there was no significant difference in survival. The low TLR2-activity of Y. pestis LcrV and associated cytokine expression might explain why - in contrast to Y. enterocolitica O:8 infection - TLR2-deficient mice are not more resistant than wild-type mice in a bubonic plague model.     

Genome-wide transcriptional response of Yersinia pestis to stressful conditions simulating phagolysosomal environments

Yersinia pestis is a Gram-negative coccobacillus causing the dangerous disease, plague. Survival of Y. pestis within host macrophages is important in the initial stages of infection. In our present work, DNA microarray was used to determine the expression profiles of Y. pestis strain 201 in response to in vitro simulating conditions of Mg(2+) limitation, polymyxin treatment and oxidative stress that could be found in phagolysosomal environment. It was demonstrated that Y. pestis made appropriate adaptive/protective responses to survive the stressful environments. There are the induced expression of antiphagocytic factors and Mg(2+) transporters under Mg(2+) limitation condition, the stimulation of drug/analogue sensitivity and glycerol assimilation after polymyxin treatment, and the differential expression in genes encoding stress-responsive proteins, components of cell envelope, iron assimilation and regulatory functions in response to both Mg(2+) limitation and polymyxin treatment. Under oxidative stress, Y. pestis uses several mechanisms, especially including the induced expression of detoxification enzymes and DNA repair proteins, to protect from or repair the oxidative cell damages. This microarray analysis would provide the candidates for identifying genes or pathways required for growth and proliferation of Y. pestis in macrophages.