- Research article
- Open Access
- Open Peer Review
Oral infection of mice with Salmonella entericaserovar Typhimurium causes meningitis and infection of the brain
© Wickham et al; licensee BioMed Central Ltd. 2007
- Received: 04 January 2007
- Accepted: 27 June 2007
- Published: 27 June 2007
Salmonella meningitis is a rare and serious infection of the central nervous system following acute Salmonella enterica sepsis. For this pathogen, no appropriate model has been reported in which to examine infection kinetics and natural dissemination to the brain.
Five mouse lines including C57BL/6, Balb/c, 129S6-Slc11a1tm1 Mcg , 129S1/SvImJ, B6.129-Inpp5dtm1 Rkh were used in the murine typhoid model to examine the dissemination of systemic Salmonella enterica serovar Typhimurium following oral infection.
We report data on spontaneous meningitis and brain infection following oral infection of mice with Salmonella enterica serovar Typhimurium.
This model may provide a system in which dissemination of bacteria through the central nervous system and the influence of host and bacterial genetics can be queried.
- Neurological Deficit
- Infected Mouse
- Bacterial Meningitis
- Bacterial Load
Salmonella species are Gram-negative, facultative intracellular bacteria that are distributed globally. Two recognized species of Salmonella include S. enterica and S. bongori, with S. enterica serovars Typhimurium, Typhi and Enteriditis causing the vast majority of human infections worldwide. Humans are infected with S. enterica though contaminated food and water and present with a range of acute symptoms including gastroenteritis, fever, and headache. Although systemic infections with S. Typhi are uncommon in developed countries, typhoid remains a significant public health problem in the developing world . Infections with non-typhoidal strains of Salmonella are a global burden, with an estimated 1.4 million cases in the United States alone .
Salmonella meningitis is an uncommon complication of salmonellosis, occurring more frequently in neonates and infants [3, 4], although adult cases are reported. While considered rare in the developed world, Salmonella is a common cause of enterobacterial meningitis in Africa, Brazil and Thailand [4, 5]. Cases in adults of Salmonella infection report colonization of the cerebrospinal fluid, fatal brain abscesses caused by intracranial colonization of S. enterica serotype Typhimurium , adult Salmonella meningitis  and CSF pleocytosis . Mortality rates are typically high, especially in infants where rates have been 60% . Other major issues concerning Salmonella meningitis is a high treatment failure rate, high relapse rate and considerable neurological sequelae in those that survive, including mental retardation, cerebral palsy, and visual and hearing impairment [3, 4, 8–11]. The treatment of such complicated cases is made more difficult by the lack of a priori knowledge of the pathogen involved, restrictions in pediatric use of certain antibiotics, the sharp and continued rise in antimicrobial resistance and the proliferation of multi-drug resistant organisms in community settings. The 1970's to early 1990's witnessed the emergence of Salmonella isolates resistant to the front-line antimicrobial chloramphenicol, as well as cotrimoxazole, ampicillin and amoxicillin . In more contemporary medicine, multi drug-resistant Salmonella such as S. Typhimurium strain DT104 is a constant reminder that new anti-infectives against novel targets are in demand. DT104 is commonly resistant to ampicillin, chloramphenicol, florfenicol, streptomycin, spectinomycin, sulfonamides and tetracycline  and infections with multi-drug resistant S. enterica isolates are associated with higher mortality rates than infection with susceptible strains . This apparent link between drug resistance and virulence is not well understood but deserves considerable attention.
The mechanisms of how Salmonella gains access to the CNS and brain are not known. Outstanding questions include (i) how does Salmonella disseminate from the intestinal mucosa to the CNS? (ii) how do bacteria gain access to the brain? (iii) what cell types are utilized for transport to the brain and intracellular replication within this compartment? (iv) what role does host genetics and immune repertoire play in this process? Lack of an appropriate animal model has made it difficult to address these questions. An animal model in rabbits of experimental S. enterica serotype Enteriditis meningitis has been reported , although this model involved direct inoculation of the cerebral spinal fluid using an intracisternally placed needle. Currently there is a dearth of reports that describe the natural progression of salmonellosis from the intestinal mucosa, though the CNS and to the brain. Here we report that the widely used oral infection model of salmonellosis fulfills the criteria of natural dissemination though a susceptible host animal from the intestinal mucosa to the brain. This is accompanied by meningitis and a reproducible behavioral manifestation of intracranial infection that occurs in at least five genetically distinct mouse lines and that correlates significantly with the bacterial load in the brain. The development of animal models of bacterial meningitis and intracranial infections will permit a better understanding of the mechanisms of bacterial dissemination, the kinetics of natural disease progression, and the influence of host genetics on this process. Such models will also be necessary for testing investigational antimicrobials and vaccines for therapeutic value against bacterial meningitis.
Bacteria and culture conditions
Salmonella enterica serovar Typhimurium strain SL1344  was used throughout this study. Bacteria were routinely cultured in LB broth and on solid LB agar plates containing streptomycin at 50 μg ml-1. Prior to animal infections, bacteria were cultured overnight in LB broth, washed in a buffer containing 0.1 M HEPES (pH 8.0) and 0.9% sodium chloride, and resuspended in the same buffer to ~107 – 109 colony forming units (cfu) per ml.
Experimental animals were female mice between 8 weeks to 12 weeks of age. Five different mouse strains were used in these experiments and include: C57BL/6 (Jackson Laboratories), Balb/c (Jackson Laboratories), 129S6-Slc11a1tm1 Mcg (formerly 129/sv Ity/Nramp -/-) , 129S1/SvImJ (Jackson Laboratories), B6.129-Inpp5dtm1 Rkh (formerly 129sv/SHIP-1 -/- F1) . Animals were obtained with full health reports, were deemed to be healthy and free of infection and were housed under specific pathogen free conditions.
Animal infections and tissue samples
All animal experiments were conducted as approved by the local Animal Ethics Board and pursuant to guidelines set out by the Canadian Council on Animal Care. Animal infections were carried out by inoculating mice per os using a gavage needle with approximately 106 to 108 wild type S. enterica serotype Typhimurium strain SL1344 in a 0.1 ml volume. Infected animals were examined twice daily for signs of terminal morbidity and animals that had become moribund or that exhibited a balance defect were euthanised by cervical dislocation. At necropsy the brain was removed, dissected into right and left hemispheres with one hemisphere processed for pathology and the other placed in 1 ml of sterile phosphate buffered saline. This latter sample was homogenized in a tissue homogenizer (Polytron, Kinematica) and the homogenate was diluted in sterile PBS and plated on solid LB agar containing streptomycin to enumerate S. Typhimurium cfu. Bacterial load was expressed as cfu/organ.
For pathologic scoring, brain tissues were fixed in 2% paraformaldehyde in routine fashion  and sectioned for histologic examination. Each brain was processed in one paraffin block and three sections were cut and stained with hematoxylin and eosin (H/E), Gram, and napthol esterase to identify mast cells. A neuropathologist examined all brain sections blindly. The degree of inflammation was scored on a 0 to 4+ scale, 0 representing no inflammation and 4+ representing involvement of the entire contour of the sub-arachnoid space of the section.
Observations on infected mice
Additional File 1: Supplementary video 1. Movie showing rolling behavior of a C57BL/6 mouse infected with Salmonella enterica serovar Typhimurium at day 9 post-infection. (MOV 3 MB)
Examination of bacterial load in infected mice
The observed neurological deficits following infection lead us to speculate that an intracranial infection with Salmonella was taking place in affected mice. To examine the dissemination of S. Typhimurium in mice exhibiting rolling behavior, bacterial load was examined in both rolling and non-rolling infected mice. Brains of mice exhibiting neurological deficit had significantly higher bacterial loads (mean, 2.66 ± 0.66 × 106 cfu/organ) than infected mice without overt signs of neurological deficit (mean, 4.21 ± 1.72 × 103 cfu/organ) (P = 0.0002, Mann Whitney) (Figure 1). Whereas some non-rolling mice had no detectable cfu in the brain (approximately 10–20% of animals), this was never the case for infected mice that had developed neurological deficits.
Pathologic examination of mouse brains
Clinical Features a
meningitis, thrombosis, ventriculitis
The occurrence of meningitis caused by serovars of Salmonella enterica is relatively rare in developed countries , but in countries such as Africa, Thailand, and Brazil [3, 5], it is a common cause of Gram-negative bacterial meningitis in infants with high mortality rates being reported. A study of infant Salmonella meningitis in Kuala Lumpur reported an 18% fatality rate with surviving infants experiencing considerable long-term neurological dysfunction (57%) and high relapse rates (38%) . Although Salmonella meningitis is a rare complication of adult salmonellosis, the increased incidence of Salmonella bacteremia in HIV-infected patients [21, 22], may expose such individuals to increased risk for more disseminated and protracted infections. Importantly, alarming increases in multi-drug resistance Salmonella enterica may be a harbinger for more virulent strains of Salmonella with increased invasive potential.
The ability of S. Typhimurium to infect the mouse brain was related to functional virulence loci including the type III secretion systems encoded in chromosomal genomic islands. In our studies over several years, infection of C57BL/6 mice with S. Typhimurium containing mutations in either of these secretion systems was never found to produce neurological deficits (over 1000 animals, data not shown) and mutant bacteria could not be recovered from the brains of representative infected mice (10 animals, data not shown). Neurological deficits were not unique to one particular strain of mouse, as we observed this behavior in five different mouse lines including wild type C57BL/6, wild type BALB/c, 129S1/SvImJ, 129S6-Slc11a1tm1 Mcg , and B6.129-Inpp5dtm1 Rkh . Much work has investigated the genetic factors in mice involved in resistance to S. Typhimurium infection . These efforts have revealed a critical role for the Slc11a1 gene (formally Nramp1) in early innate resistance to Salmonella infection . We note that 4 out of the 5 mouse strains used in our work carry a non-functional mutant allele of Slc11a1 (C57BL/6, BALB/c, 129S6-Slc11a1tm1 Mcg , and B6.129-Inpp5dtm1 Rkh ). While we did observe neurological deficits in a mouse line that normally resists lethal infection due to a wild type Slc11a1 allele (129S1/SvImJ), our current sample size does not permit detailed conclusions to be drawn regarding the impact of Slc11a1 status on meningitis development. Thus, it is possible that both bacterial and host genetic factors are involved in infection of the brain and the development of meningitis. Further work using larger sample sizes and controls could address these issues. We cannot exclude hemiparesis in mice with neurological deficits and the potential involvement in this behaviour of the vestibular system will require additional investigation.
The ability of Salmonella to disseminate naturally to the brain in several mouse lines allows the use of the vast array of transgenic and knockout mouse strains to address the host genetic factors influencing CNS dissemination including the mode of bacterial transport from intestinal sites to systemic sites of infection, the role of various immune cells in the trafficking of intracellular salmonellae to the CNS and brain, and the role of various immune cell migration factors in this process. We suggest that the mouse model of Salmonella typhoid could represent a useful tool in which to investigate basic mechanisms of CNS infiltration and brain infection following oral ingestion of Salmonella. This model could also be exploited to examine the efficacy of investigational medicines (vaccines, anti-infectives) to treat invasive and protracted Salmonella infections. Importantly, this model fills a gap in the literature to address meningitis caused by naturally disseminating salmonellae.
Oral infection of mice with Salmonella enterica serovar Typhimurium might represent a useful model in which to study the dissemination of a pathogen from the natural route of infection to the brain. Infection of the brain is followed by meningitis and a neurological deficit in a proportion of infected animals. Because more virulent strains of Salmonella are commonly associated with antibiotic resistance, the continued global epidemic spread of multi-drug resistant Salmonella isolates in human and animal medicine (such as S. Typhimurium DT104) presents a serious public health issue. Drug resistance in such isolates challenges our ability to treat life-threatening cases of salmonellosis, especially in infants and children. Oral infection of mice with S. Typhimurium is an accessible model in which to study the host and bacterial determinants that lead to dissemination and progression of infection from the gastrointestinal tract to the brain. We propose that this model has utility for testing new antibacterial chemotherapies to treat complicated, life-threatening Salmonella infections.
The authors wish to thank Jennifer Bishop, Guntram Grassl, Bryan Coburn and Yanet Valdez for contributing mice to this study. MEW was a CIHR and MSFHR postdoctoral fellow and NFB was a postdoctoral fellow of the MSFHR. This work was supported by grants to BBF from the Canadian Institutes of Health Research (CIHR) and to BKC from the Public Health Agency of Canada and the CIHR.
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