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SBM 2044: Lecture 11 AIMS: • Introduce invasive Shigella sp • Outline vir genes & mechanisms involved in invasion of host cells by Shigella • Outline other virulence mechanisms - apoptosis in macrophages Shigellosis Dysentery (bloody stools + pus + mucus; scant volume) • invasion & multiplication in colonic epithelial cells Transmitted by faecal-oral route • Direct transmission common - low I.D.50 (< 100 cells) Shigella acid tolerant Estimated 165 million cases/year > 600,000 deaths • 99% in developing countries; 69% < 5 years old Complications • Haemolytic uraemic syndrome (HUS; see lecture EHEC) • Reiter’s syndrome: autoimmune reaction - reactive arthritis, conjunctivitis, urethritis Shigella sp. Gram-negative, non-spore- forming rods Facultative aerobes Non-motile Natural habitat: Humans? • Environment? - faeces, contaminated water, etc) Four species cause shigellosis - symptoms can range from mild watery diarrhoea to severe dysentery Shigella dysenteriae Shigella flexneri Shigella boydii Shigella sonnei Produces much more Shiga toxin 1000 – 10,000 fold less toxin, in vitro – but in vivo?? Shigella sp. – virulence mechanisms Production of Shiga toxin • Toxin structure & action – see lecture EHEC • Role in shigellosis - unclear Animal models: monkeys only S. dysenteriae Stx mutant still caused dysentery, but less severe & less haemorrhaging HUS – see lecture 10 E.coli Invasion & multiplication in colonic epithelial cells • Studied mainly in S. flexneri & tissue cultured cells • Overall similar to Listeria, but details differ Shigella & EIEC invasion mechanisms 33 genes required for invasion, including: • ipaA-D: ‘ invasion plasmid antigens’ so-called because proteins originally detected by patients antisera • ipgA-F: identified by mutagenesis & sequencing, (‘invasion plasmid genes’) • icsA & icsB: intracellular spread (identified by mutagenesis) • 20 genes encoding a Type III secretion system - mxi: membrane excretion of Ipa - spa: surface presentation of inv antigens Shigella or EIEC: Overview of invasion of host cells Adhesion Activation of Type III secretion system • IpaA injected into cytoplasm depolymerisation of actin filaments • IpaB + IpaC – needle ‘bulb’ pore, with cytoplasmic active domains • IpaC required for actin polymerisation • IpaD – regulates secretion? a5b1 integrin IpaA/B/C/D Spread Ipa B/C? Multiply in cytoplasm IcsA IcsB Invasion overview: Entry Distinct from the ‘zipper-phagocytosis’ uptake seen with Listeria & Yersinia – reflects different signalling mechanisms Shigella sp. & Salmonella sp. initiated via Type III secretion ‘signals’ Extensive actin polymerisation + membrane perturbations (ruffles) - not confined to immediate vicinity of adhering bacteria ‘triggered’ phagocytosis Shigella & EIEC polarized CaCo2 cells via baso-lateral surfaces only. • Shigella may invade initially via M cells, in vivo Multiplication in enterocytes production of IL-8 Cell damage LPS release Recruits PMNs Inflammation Shigella induce apoptosis in macrophages & release of proinflammmatory cytokine IL-1b Multiplication in host cells helps Shigella evade PMNs Recall: Necrosis v apoptosis • • • • • Accidential Injury - cell swells Osmotic lysis Contents released into tissues Triggers inflammation • • • • • • Programmed Suicide pathway activated Cell shrinks DNA & nucleus fragment Membrane changes - phagocytosis Cell engulfed ‘cleanly’ Apoptosis mediated by proteases called caspases Family (>12) of cysteine proteases that cleave targets adjacent to aspartic acid. Most specific for other procaspases – activate cascade, leading to cleavage of nuclear lamins, DNase inhibitor, & cytoskeleton components Some cleave > 1 substrate protein - multiple roles in cell • Caspase-I - cleaves inactive IL-1b precursor to produce active IL-1b, a proinflammatory cytokine also called ICE = Interleukin 1b converting enzyme) SBM 2044 Lecture 10 Salmonella : Nontyphoidal and thyphoid fever Salmonella • Gram negative rods • Motile with peritrichous flagella Salmonella that infects humans • • • • • Salmonella Typhi Salmonella Choleraesuis Salmonella Paratyphi A Salmonella Paratyphi B Enter host via the oral route, usually with contaminated food or drink. 4 clinical syndromes, plus the carrier state, are associated with the genus Salmonella • gastroenteritis: nausea, vomiting and diarrhoea; caused mainly by S. enterica • focal infection of vascular endothelium; caused by serovars Choleraesuis and Typhimurium • infections of particular organ systems; osteomyelitis in patients with sickle cell disease; commonly by S. typhimurium • typhoid fever; caused by serovars S. typhi and S. paratyphi A and B. Salmonella • Vast no. of serological varieties (serovars) • Antigens are distinguishable among serovars: somatic (O), flagellar (H), and capsular (K) • Acid sensitive (hypochlorhydria, achlorhydria) – express > 40 proteins for pathogenesis • A large inoculum is needed to produce a disease (10-100 million organisms) Electron photomicrograph demonstrating invasion of guinea pig ileal epithelial cells by Salmonella typhimurium. Arrows point to invading Salmonella organisms. (Courtesy Akio Takeuchi, Walter Reed Army Institute of Research, Washington, D.C.). Entry: • Salmonella enter M cells and the apical membrane of epithelial cells – Ruffling of the plasma membrane – cytoskeletal rearrangement, and uptake of organisms within phagocytic vesicles (BME) – Type III secretion system is encoded by Salmonella pathogenicity island 1 (SPI1) – Macrophages might help, leading to dissemination – Into deeper tissue beyond the intestine by intestinal dendritic cells Damage • Host-epithelial cells interaction activates the inflammatory response and damage to intestinal mucosa – Mitogen-activated protein kinase (MAPK) receptor on the cell surface phospholipase A2, release arachidonic acid, produce PG+leukotrienes Ca2+ How do Salmonella survive in macrophages? • Regulation by two-component regulator or signal system, two genes: PhoP and PhoQ – PhoP and PhoQ act to modify the bacterial lipopolysaccharide hence resistance to innate kiling by host immune system i.e. cationic peptides • Salmonella • http://youtube.com/watch?v=VFGb3RKm-4o • Treatment: – Not antibiotics – Antimicrobial therapy for systemic nontyphoidal Salmonella infection – Typhoid vaccine – Salmonella carriers jail?
