Microbes and diseases: what to study-1 1. Causative microbe: name, morphology (shape, size, Gram stain, etc.), physiology (aerobe, anaerobe, etc) and some info on classification (what's it related to?) 2. Pathogenesis and clinical disease: what disease does it cause (signs and symptoms) and how does it do it (capsule, toxins..)? 3. Transmission and epidemiology: how do you get the disease?
Microbes and diseases: what to study-2 4. Diagnosis: How does the lab usually identify the causative agent? 5. Treatment: antibiotics prescribed (or not- no cell wall, no penicillin) or other treatment (oral rehydration therapy for cholera). 6. Prevention and control (stop the spread; condoms, kill urban rats..)
Staphylococcus: G+ coccus S. aureus and S. epidermidis. S. aureus much worse, S. epi an opportunist. Sturdy, salt tolerant, fac anaerobes; clusters S. epidermidis common on skin, S. aureus less. Diseases of S. aureus Food poisoning, skin diseases (impetigo, folliculitis, furuncles & carbuncles, scalded skin syndrome), systemic diseases (TSS, bacteremia, heart, lung, and bone infections) Diseases spread by fomites and direct contact.
Characteristics of S. aureus infections tray.dermatology.uiowa.edu/ DIB/SSSS-002.htm www.omv.lu.se/.../ rorelse/popup/01d1x.htm
S. aureus virulence factors & Rx Coagulase, triggers blood clotting. Capsules, beta-lactamases (destroy penicillins) Toxins: various, including TSS toxin, exfoliatin, and enterotoxins (heat stable) 95% resistant to penicillin, but now many resistant to methicillin, oxacillin. Treatment usually clindamycin (oral) or vancomycin (IV). http://www.biology4kids.com/extras/dtop_micro/7821_580.jpg
Streptococci: G+ cocci Genera: Streptococcus and Enterococcus Aerotolerant anaerobes, catalase negative Grow in chains, pairs Strep: Lancefield groups, viridans, S. pneumoniae Group A strep: S. pyogenes Pharyngitis, scarlet fever, pyoderma, erysipelas, TSS, necrotizing fasciitis Sequelae: rheumatic fever and glomerulonephritis http://genome.microbio.uab.edu/strep/info/strep5.gif
Characteristics of Streptococcal infections http://euclid.dne.wvfibernet.net/~jvg/Bio208/resp_pix/scarlet-fever.jpg http://textbookofbacteriology.net/vvpath.jpeg
Virulence factors, etc. S. pyogenes (“pus-producing”) M protein and capsule: avoids phagocytosis Streptokinase, streptolysins for escape & attack Pyrogenic erythrotoxins (SPEs) at least 3 different types Cause scarlet fever: fever, rash; toxic shock Beta hemolytic on blood agar Viridans group: greenish alpha hemolysis Common in throat, mouth, but can be opportunists S. mutans associated w/ dental caries
Clostridium: G+ rods Strict anaerobes! Endospore formers. Toxigenic Common in soil, sewage animal GI tracts Produce neurotoxins, enterotoxins, histolytic toxins Four important species: C. perfringens, C. botulinum, C. tetani, and C. difficile. C. perfringens Food poisoning: cramps and diarrhea From injury: myonecrosis to gas gangrene Fermentation in tissues, killing of tissues and spread of cells into anaerobic areas. Oxygen treatment, debridement, amputation
More clostridia C. difficile: normal GI microbiota Cause of pseudomembranous colitis, resulting from overgrowth following broad spectrum antibiotics Damage to GI wall can lead to serious illness Nosocomial infection, easily transmitted C.botulinum: cause of botulism Usually acquired by ingestion: intoxication Food borne, infant (no honey), wound Produces neurotoxin, inhibits acetylcholine release Flaccid paralysis; Botox: deadly poison / beauty Mouse bioassay; administer antitoxin
Opposing muscle groups When biceps contracts, triceps relaxes. When triceps contracts, biceps relaxes. Excitatory neurons send signal to contract, inhibitory neurons send signal to NOT contract. http://upload.wikimedia.org/wikipedia/sv/thumb/d/dd/185px-Muscles_biceps_triceps.jpg
Function of nerves http://upload.wikimedia.org/wikipedia/fr/thumb/e/e4/200px-Synapse.png http://www.people.virginia.edu/~dp5m/phys_304/figures/motor_unit.jpg
More clostridia-2 C. tetani: cause of tetanus Growth in anaerobic wounds, makes tetanus toxin Toxin prevents action of inhibitory neurons Opposing muscle pairs both contract Spastic paralysis, leading to death. Recommendation is booster shot every 10 years DPT, Toxoid vaccine Booster: DT (with diphtheria toxoid) No natural immunity: you would die first.
Mycobacterium: G+ rods Many non-pathogenic species, most disease: M. tuberculosis and M. leprae Mycolic acids as part of complex cell wall Protects against desiccation Protects against destruction by phagocytes Requires acid-fast staining Generally grow very slowly (chronic illnesses) Can grow intracellularly
Acid Fast stain of Mycobacteria http://www.md.huji.ac.il/mirror/webpath/AIDS071.jpg
M. tuberculosis Causes disease tuberculosis, mostly lung dis. Disease: cells enter lungs, infect macrophages Macrophages not activated, can’t kill invader Cell mediated immunity fights back, walls off infection; forms tubercle (caseous necrosis occurs) Disease remains controlled, cured, or returns Disseminated TB: spreads thru body Worldwide problem; lowered immunity=risk Skin test, chest x-ray, drug treatment, vaccine?
M. leprae Cause of Hansen’s disease, aka leprosy Slow growing, likes it cool; armadillos as model Grows in peripheral nerve and skin cells Numbness is characteristic of disease Tuberculoid vs. lepromatous leprosy Mild, severe, respectively, depending on cell mediated immune response. Numbness vs tissue destruction Spread mostly by direct contact Treatable with antibiotics, but long term
Gram negative rods and cocci Endotoxin: Lipid A, the superantigen Part of LPS of the Gram negative outer membrane Causes an over-stimulation of macrophages with production of various cytokines Fever, vasodilation, inflammation, shock, and disseminated intravascular coagulation While Gram negative pathogens can have other virulence factors (capsules, fimbriae, exotoxins), all have endotoxin and are thus dangerous.
Enterobacteriaceae: Gram negative rods Gram negative, small rods, facultatively anaerobic, oxidase negative; found in soil, water, and GI tracts some strictly pathogens, others opportunists Coliforms (ferment lactose) and non-coliforms Virulence factors Endotoxin, capsules, fimbriae, exotoxins, others. Enteric bacteria identified by biochemical tests Selective/differential media, IMViC tests, etc. Strains identified by serological techniques
Serology and enteric bacteria Because enteric bacteria are very closely related to each other, differentiation requires serology Use of antibodies to identify particular antigenic molecules on cell surfaces O antigen: repeating sugar group on LPS H antigen: flagellar protein K antigen: capsule antigen around cell. Example: E. coli O157:H7 describes particular serotype which happens to also produce a dangerous exotoxin.
http://www. ratsteachmicro http://www.ratsteachmicro.com/Assets/Enterobacteriaceae/Enterobact_diagram2.gif
E. coli: friend or foe? E. coli: cause of 90% of urinary tract infections Most strains common to GI tract, not harmful there. Strains have fimbriae needed for attachment Proanthocyanidins in cranberry juice interfere E. coli: common cause of diarrhea Many strains possess genes (some on plasmids) that code for additional virulence factors like exotoxins which cause disease E. coli O157:H7: possesses shiga toxin; strain causes hemolytic uremia syndrome, damages kidneys. E coli strains classified as EHEC, EIEC, EPEC, etc. Enterohemorrhagic, enteroinvasive, etc.
Truly pathogenic enterics Salmonella: species so closely related that they are really all S. enterica. But medically, species epithets still used: S. typhi and others. Divided serologically. Present in eggs, poultry, on animals such as reptiles Large dose results in food poisoning; diarrhea, fever, etc. Cells phagocytized by intestinal lining cells, kill cells causing symptoms, may pass through into blood. S. typhi: typhoid fever. Spread through body Gall bladder as reservoir; Typhoid Mary Importance of clean water and sewage treatment. http://www.newsday.com/community/guide/lihistory/ny-history-hs702a,0,6698943.story
Truly pathogenic enterics-2 Shigella: especially S. sonnei (most common) and S. dysenteriae (most serious); cause shigellosis. Food, flies, fingers, feces, fomites: very small infectious dose, personal hygiene important in prevention. Infection of intestinal lining damaged, cells pass directly from cell to cell; cramps, diarrhea, bloody stools. S. dysenteriae produces shiga toxin which inhibits protein synthesis, increases damage. Most serious problem with diarrheal diseases in general is dehydration.
Truly pathogenic enterics-3 Yersinia: Y pestis is cause of plague, other species cause food-borne infections Plague: 3 cycles: sylvan, urban, and human endemic in sylvan cycle; mixing of woodland and urban rodents brings urban cycle, fleas jump from dying rats to humans. Infection leads to large swollen lymph nodes: buboes Bubonic plague, with high fever. Septicemic plague: with DIC, bruising (black death) Raises mortality from75% to near 100% Pneumonic: coughed out and spread human to human 100% mortality
The S.F. earthquake and plague http://library.thinkquest.org/03oct/00904/images/sanf.jpg http://www.cdc.gov/ncidod/dvbid/plague/plagwest.htm
Other Gram - rods Francisella: F. tularensis, cause of tularemia Also called rabbit fever, tick fever, deerfly fever, etc. Most cases in US in Arkansas/Missouri Ozarks Survives phagocytosis, lives intracellularly Present in many animals, transferred to humans by vector, ingestion, direct contact, inhalation Chills, fever, malaise, swollen nodes http://er1.org/docs/photos/Tularemia/Amblyomma%20Americanum%20(lone%20star%20tick).jpg http://mercury.bio.uaf.edu/~george_happ/Francisella.jpg
Other Gram – rods-2 Legionella: L. pneumophila and several others Fastidious in culture, requires special media Very common in aquatic environments: ponds, cooling towers, hotwater heaters, showers. Grows normally in amoebae, so also grows in phagocytes Most dangerous as opportunistic pneumonia, inhalation Mild form of disease: ‘pontiac fever’ www.angelfire.com/.../ bicentennial.html
Chlamydia Very small, obligate intracellular parasites Cell and outer membrane, but no peptidoglycan Spread directly rather than by vectors Two stage life cycle Elementary body: tiny (0.2-0.4 µm) and inert Spore-like: dormant and resistant Infectious: form that moves between cells Reticulate body: 0.6-1.5 µm, metabolically active, reproduce inside host cells
Chlamydial diseases C. trachomatis: infects cells of mucous membranes, conjunctiva. Mostly eye & STD Infection kills cells, stimulates inflammation which also causes cell destruction Trachoma- leading cause of non-traumatic blindness. Caused by certain strains. Infection of conjunctiva causes scarring, turning in on eyelashes which scratch cornea. Scarred cornea, with ingrown blood vessels, obscure vision. STD strains can also infect eyes, self-inoculation.
Sexually transmitted Chlamydial disease Non-gonococcal urethritis, about 50% of cases Chlamydia infections are the most common STD, but even more are infected and asymptomatic 85% of women asymptomatic; others can develop PID; scarring of uterine tubes can lead to sterility, ectopic pregnancy. Eye infections of newborns prevented with antibiotic drops. Also protects against N. gonorrhoeae
Gram negative curved rods Vibrio: comma shaped Like enteric but oxidase positive; polar flagella Halotolerant to halophilic, grow in estuarine and marine environments V. cholerae: cause of cholera Toxin-mediated severe diarrhea Salt, fluid leave intestinal cells, patient dies of dehydration. Oral rehydration therapy (ORT): water, salts, and glucose, now saving lives. Causes pandemics that spread around the world Lack of adequate sewage treatment
Campylobacter Campylobacter jejuni: number one cause of bacterial gastroenteritis; zoonotic More common than Salmonella and Shigella combined for food borne disease. Most retail chickens are contaminated; improperly cooked chicken and contaminated milk typical vehicles. Low infectious dose Gram neg. curved rod http://www.shef.ac.uk/staff/newsletter/vol23no10/images/campylobacter.gif
Helicobacter pylori Cause of ulcers and gastritis 2005 Nobel Prize for Medicine or physiology to Barry Marshall and J Robin Warren Unusual because it can live in stomach Produces urease enzyme Released ammonia neutralizes stomach acid, irritates stomach lining. Basis for radioactive urease test. Correlated with stomach cancer. http://s99.middlebury.edu/BI330A/STUDENTS/KASSIS/images/pylori1b.jpg