Transmission of Helicobacter pylori from challenged to nonchallenged nude mice kept in a single cage

Vertical Helicobacter pylori transmission from Mongolian gerbil mothers to pups

To identify the time frame and route of mother-to-child Helicobacter pylori infection, a Mongolian gerbil model was used. Four-week-old female Mongolian gerbils were infected with H. pylori, and then mated with uninfected males 2 months after infection. The offspring were sacrificed weekly after birth, and then serum, mother's milk from the stomach and gastric tissues were obtained from pups. Anti-H. pylori antibody titres were measured in sera and maternal milk using an ELISA. The stomach was cut in two in the sagittal plane, and then H. pylori colonization in mucosa was confirmed by culture and real-time RT-PCR in one specimen and by immunochemical staining in the other. Faeces and oral swabs were obtained from infected mothers, and H. pylori 16S rRNA was measured using real-time RT-PCR. H. pylori was not identified in cultures from the gastric mucosa of pups delivered by infected mothers, but H. pylori 16S rRNA was detected from 4 weeks after birth, suggesting that Mongolian gerbil pups become infected via maternal H. pylori transmission from 4 weeks of age. The anti-H. pylori antibody titre in sera of pups from infected mothers was maximum at 3 weeks of age and then rapidly decreased from 4 weeks of age. High antibody titres in mother's milk were detected during the suckling period, and GlcNAcα was detectable at 2–4 weeks of age, but disappeared as the offspring aged. Thus H. pylori seems to infect Mongolian gerbil pups from 4 weeks of age, in parallel with decreasing GlcNAcα expression in the gastric mucosa. These results suggested that H. pylori infection of Mongolian gerbil pups occurs via faecal–oral transmission from an infected mother.

Use of animal models in the development of human vaccines

Over the past 100 years, animal infectious disease research has played a crucial role in the development of human vaccines. In fact, many of today's vaccines are based on utilizing animal pathogens, either in the form of an attenuated vaccine or as a vaccine vector. Vaccine development has become increasingly complex with chronic and newly emerging diseases, a demand for therapeutic vaccines for noninfectious diseases, extended vaccine in the neonate and the elderly, and increasing concerns regarding vaccine safety. Furthermore, the evaluation of quantity and quality of immune responses and the ability to efficiently translate the results of basic research into the clinic are critical to ensure that vaccines meet their therapeutic potential. Here, we review the importance of animal models for developing and testing novel human vaccines, discuss the limitations of existing animal models in knowledge translation, and summarize the needs and criteria for future animal models. We argue that efficient translation of basic vaccine research to clinical therapies will depend upon the availability of appropriate animal models to address each of the questions which arise during vaccine development.

Association between Helicobacter pylori infection in mothers and birth weight

Helicobacter pylori infection may cause intrauterine growth restriction (IUGR). However, it is unknown whether the growth of children from H. pylori-infected mothers is also affected or whether transmission of infection from mother to child occurs. This study aimed to determine if maternal H. pylori infection was associated with IUGR and low birth weight in a mouse model, and whether transmission of infection from mother to infant occurs. Female C57BL/6 mice were inoculated with H. pylori (n = 18) or water (control; n = 18) via gavage. Mice were mated at 6 weeks postinfection, with half of the mice sacrificed after 2 weeks of gestation. The remaining mice gave birth and a third of the litter was weighed and sacrificed at birth, during milk feeding (1.5 weeks), and during solid feeding (4 weeks). Stomachs of all mice and whole foetuses were cultured for the presence of H. pylori. There were no differences in litter size or foetus weight between control and H. pylori-infected mice. Pups from infected mothers had a lower weight during milk feeding (control, 5.91 +/- 0.23 g; H. pylori, 4.59 +/- 0.16 g; p < 0.05) and solid feeding (control, 12.73 +/- 0.58 g; H. pylori, 10.01 +/- 1.02 g; p < 0.05). H. pylori was not detected by culture in the pups at any age. H. pylori infection in mothers was associated with a decrease in infant weight during milk feeding and after weaning. Transmission of infection from mother to infant was not detected by culture, suggesting that decreased baby weight may be due to decreased milk supply or altered nutrition from the mother.

Modelling infectious disease — time to think outside the box?

Models occupy an essential position in the study of infectious disease as a result of the ethical problems of exposing humans to potentially lethal agents. Deliberately induced infections in well-defined animal models provide much useful information about disease processes in an approximation of their natural context. Despite this, animal models are not the natural disease process, and recent experimental advances show, perhaps not unsurprisingly, that there are large differences between natural infections and animal models. Focusing on mouse models of bacterial pathogens, we discuss some of these discrepancies and suggest ways of improving model systems in the future.

Emergence of a 'hyperinfectious' bacterial state after passage of Citrobacter rodentium through the host gastrointestinal tract

Citrobacter rodentium belongs to a family of human and animal enteric pathogens that includes the clinically significant enterohaemorrhagic Escherichia coli (EHEC) and enteropathogenic E. coli (EPEC). These pathogens exploit attaching and effacing (A/E) lesions to colonize the host gastrointestinal tract. However, both EHEC and EPEC are poorly pathogenic in mice. In contrast, C. rodentium, which is genetically highly related to E. coli, relies on A/E lesion formation as an essential step in both colonization and infection of the murine mucosa, providing an excellent in vivo model. In this study we have used bioluminescence imaging (BLI) to investigate the organ specificity and dynamics of colonization of mice by LB-grown and mouse-passaged C. rodentium in situ and in real time. We have demonstrated the appearance of a 'hyperinfectious' state after passage of C. rodentium through the murine gastrointestinal tract. The 'hyperinfectious' state was found to dramatically reduce the dose required to infect secondary individuals, and also influenced the tissue distribution of colonizing bacteria, removing the requirement for primary colonization of the caecal patch. In addition, the 'hyperinfectious' phenotype was found to be transient with one overnight passage in rich medium sufficient to return C. rodentium to 'culture' infectivity.

Direct transmission of H. pylori from challenged to nonchallenged mice in a single cage

To understand whether direct transmission of H. pylori occurs from infected mouse to noninfected mouse, the system using a mouse model we developed previously was tested. Six nude mice were challenged with H. pylori inocula; one group consisted of one challenged nude mouse 1 week after inoculation raised with four nonchallenged nude mice in a single cage. For the single cage, a polycarbonate cage or a mesh-floor cage was used. Then three groups were kept in a polycarbonate cage and the other three groups kept in a mesh-floor cage to avoid H. pylori transmission through stool. After coraising for 1, 2, or 3 weeks, all mice were sacrificed to determine the existence of H. pylori in the stomach, saliva, and stool by culture or PCR and H. pylori-associated gastritis. RAPD fingerprinting patterns using different primers of isolated strains from challenged and nonchallenged mice were compared to understand the origin of transmitted strains. During 3 weeks after coraising of H. pylori challenged and nonchallenged mice, H. pylori was detected in the stomachs in 3 of 12 nonchallenged mice in the polycarbonate cage and in 2 of 12 nonchallenged mice in the cage with a steel mesh floor. H. pylori was detected from saliva or stool in two nonchallenged, infected mice in the polycarbonate cage. Moreover, RAPD fingerprinting using different primers of the total five strains isolated from five nonchallenged, infected mice in both cages showed the same pattern and concordance with that of the challenged strain and the strains isolated from challenged mice. It is demonstrated that intimate interaction is the cause of H. pylori transmission via saliva and stool.

Gnotobiotic transgenic mice reveal that transmission of Helicobacter pylori is facilitated by loss of acid-producing parietal cells in donors and recipients

Helicobacter pylori is acquired during childhood, but its mode of transmission remains unclear. A genotyped H. pylori isolate (Hp1) that expresses two classes of adhesins was introduced into the stomachs of three types of germ-free FVB/N mice to model factors that may affect spread of H. pylori in humans. Normal mice represented human hosts with normal gastric acid production. Transgenic animals expressing human alpha-1,3/4-fucosyltransferase in their gastric pit cells represented humans with normal acid production and the commonly encountered Lewis(b) histo-blood group receptor for the bacterium's BabA adhesin. tox176 transgenic mice have a genetically engineered ablation of their acid-producing parietal cells and increased proliferation of gastric epithelial lineage progenitors that express sialylated glycan receptors for the bacterium's SabA adhesin. These mice mimic features encountered in humans with H. pylori-associated chronic atrophic gastritis (CAG). Different combinations and numbers of 6-week-old germ-free normal and transgenic mice were housed together. At least one donor mouse per cage was infected with a single gavage of 10(7) colony-forming units of Hp1. All cagemates were sacrificed 8 weeks later. Cultures of gastric and cecal contents, plus quantitative PCR assays of cecal contents harvested from donors and potential recipients, revealed that transmission only occurred between tox176 donors and tox176 recipients, and that the distribution of Hp1 along the gastrointestinal tract was significantly broader in mice without parietal cells (P < 0.001). Transmission between tox176 mice was not attributable to any significant difference in the density of Hp1 colonization of the stomachs of tox176 versus normal donors. Our findings lead to the testable hypothesis that the relative hypochlorhydria of young children, and conditions that promote reduced acid production in infected adults (e.g. CAG), represent risk factors for spread of H. pylori.

Childhood Helicobacter pylori infection in a murine model: maternal transmission and eradication by systemic immunization using bacterial antigen-aluminium hydroxide

In humans, transmission of Helicobacter pylori is thought to occur largely during childhood. Infected mothers are generally considered to be the main source of the pathogen. However, little is known about when and how often maternal transmission of H. pylori occurs during childhood. In the present study, we examined these issues in an experimental murine model. Pregnant C57BL/6 mice, infected experimentally with H. pylori, delivered and nursed their litters. The stomachs of the infants were isolated and assessed for transmission of H. pylori. We also investigated the effect of systemic immunization using H. pylori antigen-aluminium hydroxide (AlOH) with regard to providing anti-H. pylori immunity and eradicating the maternally transmitted bacteria in infants. Polymerase chain reaction (PCR) was used to examine the presence of transmitted bacteria and their eradication. Maternal transmission of H. pylori varied widely during the nursing period, but almost all litters showed bacterial transmission at 2 weeks postpartum. Systemic immunization with bacterial antigen-AlOH eradicated the bacteria in most litters; this immunization induced a local decrease of Th2 cytokines and a local increase of Th1 cytokines in the gastric tissue, as determined by ELISA. Our results indicate that our H. pylori vaccine provides not only protection, but also eradication of the already transmitted H. pylori.

Virulence of water-induced coccoid Helicobacter pylori and its experimental infection in mice

AIM: To explore the virulence and the infectivity of coccoid Helicobacter pylori (H. pylori) transformed from spiral form by exposure to sterile tap water.

METHODS: Three strains of H. pylori, isolated from gastric biopsy specimens of confirmed peptic ulcer, were converted from spiral into coccoid form by exposure to sterile tap water. Both spiral and coccoid forms of H. pylori were tested for the urease activity, and the adherence to Hep-2 cells. The presence of flagella was examined under electron microscopy. In the experimental animal infection, the spiral and coccoid forms of H. pylori originated from the same strain F49 were inoculated intragastrically into BALB/c mice respectively four times at a 3-day interval. Half of the mice from each group were sacrificed at Day 21 and Day 28 after the last inoculation. Histology and H.pylori colonization were detected by urease test of gastric mucosa, cultures of H.pylori, and electron microscopy and so on.

RESULTS: The urease activity and the ability of adherence to Hep-2 cells were found to be lower in coccoid H.pylori than that in its spiral form. For example, the transformation in strain F₄₄ led to a significant decrease of the adherence rate and adherence index from 70.0% ± 5.3% to 30.2% ± 3.5% (P < 0.01), and from 2.6 ± 0.4 to 0.86 ± 0.3 (P < 0.01), respectively. The flagella of coccoid H. pylori were observed under electron microscope. In the experimental infection in mice, the positive rate of gastric mucosa urease test was 93.8% (15/16) in the group infected by spiral H.pylori and 50% (8/16) in the group infected by coccoid H.pylori, and the estimated coccoid H.pylori colony number was 1.75 vs 0.56. The positive rates of H.pylori culture were 87.5% (14/16) in spiral H. pylori group and 68.8% (11/16) in coccoid H. pylori group. There was no significant difference in either urease test or bacterial culture rate between the groups examined at Day 21 and Day 28 after inoculation. Electron microscopic examination of the samples taken from both groups showed the adherence of H.pylori in spiral, bacillary and coccoid shapes to the epithelial cells of gastric wall. Histological examination showed the occurrence of gastric mucosal injury as indicated by various degrees of erosion, ulcer, and inflammatory cell infiltration. Mucosal injury was slighter in the mice infected by coccoid H.pylori. No positive result was obtained in the control group that received intragastrical administration of sterile tap water.

CONCLUSION: Although the virulence of coccoid H.pylori induced by water decrease, coccoid H.pylori still remains a considerable urease activity and the adhering ability to epithelial cells. Furthermore, the flagella, an important component responsible for bacterial movement and infection, were still observed as a cellular structure of coccoid H.pylori under electron microscope. The coccoid H.pylori induced by water is capable of colonizing in gastric mucosa and causing gastrititis in mice.