Long-term Selenium Deficiency Increases the Pathogenicity of a Citrobacter rodentium Infection in Mice

Citrobacter rodentium is a mouse pathogen that causes infectious colitis and shares characteristics with human enteropathogenic (EPEC) and enterohemorrhagic (EHEC) Escherichia coli, including the ability to cause attaching and effacing lesions in the colon and serves as a useful model to study the pathogenicity of these bacteria. In this study, mice were fed a selenium-deficient diet for 5 or 20?weeks and then infected with C. rodentium. Colonization of the colon by C. rodentium was similar in mice fed adequate or selenium-deficient diets, but total bacterial colonization of the spleen was elevated in mice fed selenium-deficient diet for 20?weeks. Infection-induced changes to the colon included inflammatory cell infiltration, gross changes in crypt architecture, and ulceration and denuding of the epithelial layer that were greatest in mice fed a selenium-deficient diet for 20?weeks. Expression of pro-inflammatory genes was significantly higher 12-days post-infection in mice fed the selenium-deficient diet for 20?weeks compared to mice fed a selenium-adequate diet or selenium-deficient diet for 5?weeks. Diarrhea was prevalent in mice fed the selenium-deficient diet for 20?weeks but not 5?weeks, and this was associated with decreased expression of solute carrier family 26a3 and carbonic anhydrase IV, genes involved in ion transport. These results indicated that selenium played an important role in resistance to the pathological effects of a C. rodentium infection, and therefore, selenium status may be important in the expression of human disease caused by common food-borne bacteria.     

恒河猴感染SARS病毒致病模型的建立

为建立恒河猴严重急性呼吸道综合征(SARS)的模型并对其致病特点进行观察,采用病毒分离、免疫荧光、光镜及RT-PCR方法对病毒感染组和非感染组恒河猴不同时间、不同组织或分泌物进行检测.结果显示从恒河猴不同组织中分离到病毒,而且在病毒感染后第2d和第5d的血液、第7、9d的鼻咽分泌物、第3d的粪、第5d的粪尿中均检测到SARS-CoV RNA.光镜观察到病毒感染组肺组织肺泡间隔增宽,有大量淋巴细胞、单核细胞浸润,肺泡腔有渗出,甚至形成透明膜样物;多个肺泡形成机化性肺炎的表现.感染组肝组织可见较大的坏死灶,并伴有大量炎性细胞浸润.结论认为已成功建立了恒河猴SARS模型,可用于评价抗SARS药物和疫苗的研究.     

恒河猴感染SARS病毒致病模型的建立

为建立恒河猴严重急性呼吸道综合征(SARS)的模型并对其致病特点进行观察,采用病毒分离、免疫荧光、光镜及RT-PCR方法对病毒感染组和非感染组恒河猴不同时间、不同组织或分泌物进行检测。结果显示从恒河猴不同组织中分离到病毒,而且在病毒感染后第2d和第5d的血液、第7、9d的鼻咽分泌物、第3d的粪、第5d的粪尿中均检测到SARS-CoV RNA。光镜观察到病毒感染组肺组织肺泡问隔增宽,有大量淋巴细胞、单核细胞浸润,肺泡腔有渗出,甚至形成透明膜样物;多个肺泡形成机化性肺炎的表现。感染组肝组织可见较大的坏死灶,并伴有大量炎性细胞浸润。结论认为已成功建立了恒河猴SARS模型,可用于评价抗SARS药物和疫苗的研究。     

金黄色葡萄球菌亚致死量的小鼠感染中L型致病性的实验研究

用亚致死量金黄色葡萄球菌静脉内注入感柒小鼠建立了动物模型,结果感染后1周内大部分(8/10)的小鼠肺脏中可分离出金葡菌 L 型;感染第2周时,肺中 L 型菌消失,肝、肾中出现 L型菌分别为5/10与8/10,在感染第4周金葡菌 L 型从肝脏中也消失,而在肾中从4周持续至12周仍有L 型菌(18/20),普通细菌型占2/10,说明 L 型菌在此处保存时间较长,在第12周时,L 型仍有15/20,从感染后4周时起至第12周组织学检查时,在4/5～1/2的肺、1/5～1/3的肝、3/4～5/5的肾脏器中表现有间质性炎症,提示金黄色葡萄球菌在机体内可转变为“L”型,并在肾内的高渗环境中长期存活,它能在小鼠中引起间质性炎症,这一病变,看来与无细胞壁的其它微生物(包括病毒、支原体等在内)具共同的致病特性有关。     

Pathogenicity of Helicobacter ganmani in Mice Susceptible and Resistant to Infection with H. hepaticus

Helicobacter spp. are some of the most prevalent bacterial contaminants of laboratory mice. Although abundant data regarding the diseases associated with H. hepaticus infection are available, little is known about the pathogenicity of H. ganmani, which was first isolated in 2001 from the intestines of laboratory mice. The objective of this study was to evaluate the host response to H. ganmani colonization in H. hepaticus disease-resistant C57BL/6 and disease-susceptible A/J and IL10-deficient mice. Mice were inoculated with H. ganmani, H. hepaticus, or Brucella broth. Cecal lesion scores, cecal gene expression, and Helicobacter load were measured at 4 and 90 d after inoculation. At both time points, mice inoculated with H. ganmani had similar or significantly more copies of cecum-associated Helicobacter DNA than did mice inoculated with H. hepaticus. When compared with those of sham-inoculated control mice, cecal lesion scores at 4 and 90 d after inoculation were not significantly greater in H. ganmani-inoculated A/J, C57BL/6, or IL10-deficient mice. Analysis of cecal gene expression demonstrated that H. ganmani infection failed to cause significant elevations of IFNγ in A/J, C57BL/6, or IL10-deficient mice. However, in IL10-deficient mice, H. ganmani infection was associated with a significant increase in the expression of the proinflammatory cytokine IL12/23p40. Although H. ganmani infection in this study failed to induce the typhlitis that is the hallmark of H. hepaticus infection, infection with H. ganmani was associated with alterations in inflammatory cytokines in IL10-deficient mice.Abbreviations: B6, C57BL/6NCr; HPRT, hypoxanthine guanine phosphoribosyl transferase; IL10 KO, B6129P2-IL10^tm1Cgn/JSince the discovery of the link between Helicobacter pylori and chronic gastritis in 1982,¹⁷ Helicobacter spp. in humans and animals have become a field of extensive study. Due to improved detection methods, there has been a rapid expansion in our understanding and ability to detect native Helicobacter spp. in mouse models. Several reports investigating their prevalence in mice housed in research institutions have found Helicobacter spp. to be some of the most common bacterial contaminants of laboratory rodents.^2,3,12,16,23 Helicobacter hepaticus is perhaps the most notorious of the murine helicobacters, by virtue of the early realization of its pathogenicity in adult mice.^8,24 The hallmarks of infection by H. hepaticus are typhlitis, colitis, and hepatitis.¹⁰ In addition, H. hepaticus is commonly used as a microbial trigger in susceptible mouse strains used as models of inflammatory bowel disease.^5,9,19,21,28 In 2001, less than 10 y after H. hepaticus was discovered, H. ganmani was isolated from the intestines of laboratory mice.²⁶ During its initial characterization, 16S rDNA sequence analysis placed H. ganmani phylogenetically closest to H. rodentium, a urease-negative helicobacter that had been previously isolated from mouse intestines.²⁶Despite the reported endemic presence of H. ganmani in many research colonies,^2,3,12 only a few reports to date have attempted to address H. ganmani’s potential pathogenicity.^22,30 One report describes an outbreak of inflammatory bowel-like disease associated with H. ganmani infection in an otherwise Helicobacter-free conventional colony of IL10-deficient mice.²² The findings from another report describe the effect of natural colonization of IL10-deficient mice with H. ganmani, H. hepaticus, or both.³⁰ In that study, 8- to 20-wk-old mice monoinfected with H. ganmani had significantly lower lesion scores than did mice monoinfected with H. hepaticus, suggesting that infection with H. ganmani alone was not sufficient to cause severe typhlocolitis.³⁰ However, by 34 wk of age, clinical typhlocolitis (diarrhea) and grossly enlarged ceca were observed at necropsy in 2 of the 6 mice monoinfected with H. ganmani.³⁰Although these reports of naturally occurring infections have provided a glimpse into H. ganmani’s potential to produce intestinal disease in immunodeficient mice, a controlled study in immunocompetent and immunodeficient mice had not been conducted previously. The objectives of the current study were to evaluate the effect of H. ganmani infection on intestinal disease and to characterize alterations of inflammatory gene expression associated with infection. To this end, we selected A/J and IL10-deficient mice for this study because of their known susceptibility to H. hepaticus-induced typhlocolitis.^{9,13,14,19,21,28} In contrast, although C57BL/6 mice show an initial spike in inflammatory cytokines after H. hepaticus infection, they do not typically develop chronic disease.¹⁹ We did not expect C57BL/6 mice to develop H. hepaticus-induced disease, but we deemed it prudent to characterize the possible effects—through unknown mechanisms—of H. ganmani on this common strain.Previous studies characterizing cecal gene expression during H. hepaticus induced typhlocolitis demonstrated that IFNγ and IL12/23p40 (IL12/23) are key proinflammatory cytokines that drive typhlitis.¹⁹ Expression of these cytokines was increased in H. hepaticus-inoculated A/J mice but not in H. hepaticus-inoculated C57BL/6 mice.¹⁹ In addition, treatment with neutralizing monoclonal antibodies against these cytokines significantly decreased cecal lesion severity, implicating the roles of IFNγ and IL12/23 in modulating the pathogenesis of typhlitis.¹⁹ We hypothesized that characterizing the effect of H. ganmani infection on expression of IFNγ and IL12/23 would uncover aspects of the host response that are not readily apparent by histologic evaluation of cecal tissue alone.To date, our understanding of the potential for H. ganmani to cause intestinal disease has been limited to reports that focused on the evaluation of histologic disease in naturally infected IL10-deficient mice. Despite the reported endemic presence of H. ganmani in many research colonies,^2,3,12 there are no published reports of disease associated with H. ganmani infection in immunocompetent mice. In addition, H. ganmani shares close sequence homology with H. rodentium, which has been found to be nonpathogenic in monoinfected immunodeficient and immunocompetent mice.²⁰ Therefore, we hypothesized that experimental infection with H. ganmani would not produce disease in H. hepaticus-susceptible or -resistant mice.     

Expression of a Peroral Infection Factor Determines Pathogenicity and Population Structure in an Insect Virus

A Nicaraguan isolate of Spodoptera frugiperda multiple nucleopolyhedrovirus is being studied as a possible biological insecticide. This virus exists as a mixture of complete and deletion genotypes; the latter depend on the former for the production of an essential per os transmission factor (pif1) in coinfected cells. We hypothesized that the virus population was structured to account for the prevalence of pif1 defector genotypes, so that increasing the abundance of pif1 produced by a cooperator genotype in infected cells would favor an increased prevalence of the defector genotype. We tested this hypothesis using recombinant viruses with pif1 expression reprogrammed at its native locus using two exogenous promoters (egt, p10) in the pif2/pif1 intergenic region. Reprogrammed viruses killed their hosts markedly faster than the wild-type and rescue viruses, possibly due to an earlier onset of systemic infection. Group success (transmission) depended on expression of pif1, but overexpression was prejudicial to group-specific transmissibility, both in terms of reduced pathogenicity and reduced production of virus progeny from each infected insect. The presence of pif1-overproducing genotypes in the population was predicted to favor a shift in the prevalence of defector genotypes lacking pif1-expressing capabilities, to compensate for the modification in pif1 availability at the population level. As a result, defectors increased the overall pathogenicity of the virus population by diluting pif1 produced by overexpressing genotypes. These results offer a new and unexpected perspective on cooperative behavior between viral genomes in response to the abundance of an essential public good that is detrimental in excess.     

Affecting Pseudomonas aeruginosa Phenotypic Plasticity by Quorum Sensing Dysregulation Hampers Pathogenicity in Murine Chronic Lung Infection

In Pseudomonas aeruginosa quorum sensing (QS) activates the production of virulence factors, playing a critical role in pathogenesis. Multiple negative regulators modulate the timing and the extent of the QS response either in the pre-quorum or post-quorum phases of growth. This regulation likely increases P. aeruginosa phenotypic plasticity and population fitness, facilitating colonization of challenging environments such as higher organisms. Accordingly, in addition to the factors required for QS signals synthesis and response, also QS regulators have been proposed as targets for anti-virulence therapies. However, while it is known that P. aeruginosa mutants impaired in QS are attenuated in their pathogenic potential, the effect of mutations causing a dysregulated timing and/or magnitude of the QS response has been poorly investigated so far in animal models of infection. In order to investigate the impact of QS dysregulation on P. aeruginosa pathogenesis in a murine model of lung infection, the QteE and RsaL proteins have been selected as representatives of negative regulators controlling P. aeruginosa QS in the pre- and post-quorum periods, respectively. Results showed that the qteE mutation does not affect P. aeruginosa lethality and ability to establish chronic infection in mice, despite causing a premature QS response and enhanced virulence factors production in test tube cultures compared to the wild type. Conversely, the post-quorum dysregulation caused by the rsaL mutation hampers the establishment of P. aeruginosa chronic lung infection in mice without affecting the mortality rate. On the whole, this study contributes to a better understanding of the impact of QS regulation on P. aeruginosa phenotypic plasticity during the infection process. Possible fallouts of these findings in the anti-virulence therapy field are also discussed.     

Pathogenicity of Francisella

The data of literature and the results of the author's research on the pathogenicity of the causative agent of tularemia and other Francisella organisms are reviewed. The solution of the problem of their pathogenicity is based, as stated by the author, on the level of our knowledge of the genetics of Francisella. The conclusion has been made that scientific achievements in the field of the genetics of Francisella, obtained during the last 15 years, make it possible to find out the pathogenicity factors of the causative agent of tularemia, as well as other microbes of the family Francisella.     

青枯菌致病性与基因组之间的关系

青枯菌是引起植物毁灭性青枯病的病原菌。青枯菌基因组约5.8Mb,具有高(G C)含量和约5120个可能的编码基因。该菌基因组由3.7Mb的染色体和2.1Mb的大质粒所组成,其独特的基因组构成与Ⅲ型分泌系统等主要的致病因子密切相关。综述了青枯菌的致病性与其基因组之间关系的新近研究进展。     

嗜肺军团菌毒力岛分子分型及其致病性研究进展

嗜肺军团菌是引起社区获得性和医院内感染性肺炎的重要病原体,中央空调冷凝塔水系统是引发军团菌病的重要传染源,在国内外时有暴发流行,病死率较高。嗜肺军团菌的致病性与其毒力岛基因组密切相关。简要概述了嗜肺军团菌毒力岛、分子分型及其致病性。     

Pathogenicity and virulence

Invertebrate pathologists have multiple definitions for the terms pathogenicity and virulence, and these definitions vary across disciplines that focus on host-pathogen interactions. We surveyed various literatures, including plant pathology, invertebrate pathology, evolutionary biology, and medicine, and found most define pathogenicity as the broader term, which incorporates virulence. Virulence is seen as the severity of disease manifestation that can only be measured in infected individuals. These definitions readily apply to both lethal and non-lethal diseases. Invertebrate pathologists commonly use dose-response bioassays to estimate LD(50) or LC(50) (dose or concentration needed to kill 50% of hosts exposed). These bioassays measure pathogenicity if the bioassay includes a transmission component, and measure virulence if the bioassay is measured in infected individuals only. Another common bioassay estimate is LT(50) (median time to death of infected hosts), which is a measure of virulence as long as survivors are not included in its calculation.