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Microbiology 261 –Lecture Notes Microbes and Hosts: Infection, Disease and Defenses

Microbiology 261 –Lecture Notes Microbes and Hosts: Infection, Disease and Defenses. Dr. Gary G. Andersen. We make contact!.

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Microbiology 261 –Lecture Notes Microbes and Hosts: Infection, Disease and Defenses

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  1. Microbiology 261 –Lecture NotesMicrobes and Hosts: Infection, Disease and Defenses Dr. Gary G. Andersen

  2. We make contact! • Resident flora – (skin, upper respiratory tract, gastro-intestinal tract, urethra, genitalia, vagina, external ear canal, external eye) (Note: All internal tissues and organs are sterile) • Birth is a microbe event • See pg 388 for microbes established on humans.

  3. Flora Locations and Types • Transient – (variable) such as on skin surface • Resident – (stable populations) • Skin - deeper layers of skin (stable populations of Staphlococcus, Corynebacterium, & Yeasts) • GI tract: Mouth – Streptococcus species • GI tract: Intestine – Anaerobes such as Bacteroides, Bifidobacterium, Fusobacterium, Clostridium and Coliforms

  4. Flora Locations and Types (cont.) • Respiratory Tract – upper nasal passages and throat (Staphylococcus aureus) • Genitourinary Tract – eurethral opening and vagina (Lactobacillus, Steptococcus, Corynebacterium, Escherichia, Mycobacterium) • Germ-free animals are healthier as long as they remain in a sterile environment

  5. Host Parasite Relationships • Symbiosis – the relationship between bacteria (microbiota) and us (the host!). 1. Parasitism – pathogenic, harmful to the host. 2. Mutualism – both microbe and host benefit. Bacteria in the colon release Vitamin K as a waste product. Vitamin K is used in clotting. 3. Commensalism – microbe benefits by absorbing nutrients released from sloughed dead cells.

  6. Normal Microbiota Mutualists and commensalists comprise the normal microbiota of the host. Normal microbiota can be permanent (resident), or transient bacteria. Opportunistic bacteria are normal microbiota that may cause disease when the immune system is depressed from cold or flu viruses. It has been estimated 1015 bacteria live in or on the human body. (500 – 1000 species) Yet, the human body itself comprises only 1014 eukaryotic cells in the adult!

  7. The disruption of Normal Microbiota • Vaginal Bacteria pH 4.0 birth - 2-3 wks. Lactobacilli (residual estrogen) pH 7.5 2-3 wks. – puberty Various Microbes (no estrogen) ex. Staph & Strep. pH 4.0 puberty – menopause Lactobacilli (estrogen levels high) pH 5.0 Oral contraceptives, broad spectrum antibiotics, or frequently douching may cause: Opportunistic infections may arise causing vaginosis: ex. Candida albicans (yeast), Gardenerella vaginalis (bacteria), or Trichomonas vaginalis (protozoan) pH 7.5 postmenopausal Various Microbes: Staph & Strep. GA f07

  8. Infectious Disease Classifications A. Symptomology – changes in body function resulting from infectious diseases. 1. asymptomatic – without symptoms. Detection based on positive blood test indicating presence of antibodies. Inapparent, subclinical and carrier are synonyms. Insidious infection if damaging host tissues without symptoms, Ex. Pelvic Inflammatory Disease. Etiology: Chlamydia, or Neisseria gonorrhea.

  9. Subjective symptoms – malaise, a general feeling of discomfort. • Objective symptoms – observable and measured conditions. Ex. Rash size and color, body temperature, and extent of lymphadenopathy (lymph node swelling).

  10. Infectious Disease Stages p 402 • Incubation Period – no symptoms • Prodromal period – subjective symptoms • Period of Invasion – objective symptoms • Convalescence – decrease to subjective or no symptoms.

  11. Modes of Transmission MOT Ye’ ole 6 F’s: feces, flies, fingers, fomites, food and fornication! • Contact Transmission a. Direct contact – STD’s, or vertical (prenatal and perinatal). b. Indirect contact – fomites: ex. money, catheter, syringe, eating utensils. c. Droplet contact – within 1 meter zone!

  12. GA f 07 • Vehicle Transmission a. Water – raw sewage in water results in fecal-oral cycle. b. Food – poisoning via bacterial toxins as with botulism (ex. Clostridium botulinum), or gastroenteritis from bacteria (ex. Salmonella typhi) or viruses (ex Rotavirus) that invade the colon. c. Airborne – greater than 1 meter in extreme wind blown conditions such as in military settings. 747 airlines recirculate air.

  13. Vectors • Vector Transmission a. Mechanical – the feet of flies b. Biological – insect bites ex. Anopheles mosquito transmits malaria, etiology: Plasmodium vivax. ex. Rat Flea transmits bubonic plague, etiology: Pasteurella pestis ex. Tick transmits Lymes disease, etiology: Borrelia burgdorferi

  14. Flies defecate, vomit, feed

  15. Zoonoses(pl.)– diseases transmitted directly from animals to humans, or indirectly from animals by insect vectors. ex. Malaria and Yellow Fever have a monkey reservoir. Wild and domestic animals are carriers for many human infectious diseases. Zoonoses include diseases transmitted by feathers, hides, or furs to humans. ex. Tularemia – “rabbit fever” etiology: Francisella tularensis (Gram – bacteria) ex. Toxoplasmosis – etiology: Toxoplasma gondii. A protozoan parasite found in cat litter boxes. Beware if pregnant or with reduced immunity. ex. Rabies – etiology; Rhabdovirus. A virus transmitted by skunks and raccoon.

  16. Rabies (Dog and restrained man) GA sp07

  17. Epidemiology • Definition – the study of the incidence, transmission and frequency of a disease. • Centers for Disease Control and Prevention (the CDC) in Atlanta, MMWR, the Morbidity and Mortality Weekly Report. Provides cumulative statistical public health information. http://www.cdc.gov/mmwr/ • The World Health Organization (W.H.O.) in Geneva, Switzerland. Conducts international epidemiological research.

  18. Communicable disease – direct contact • Non-communicable disease – vehicle, vector or indirect contact transmission. ex. Bacillus anthracis endospores in the mail! • Endemic – a disease that is constantly present in a local population. Ex. malaria • Epidemic – many people contracting a disease in a short period of time. Ex. Lyme disease • Pandemic – global spread of pathogen.

  19. NOSOCOMIAL INFECTIONSp433 Nosocomial def. – from the Greek word for “hospital” • The CDC claims that ~8% of all inpatients acquire new infections while in the hospital. ~ 20,000 deaths/year. • Three reasons for nosocomial infections: 1. There is a concentration of virulent, antibiotic resistant microbes in hospitals. 2. Patients are normally immunocompromised from chemotherapy, radiation, malnutrition, and psychological or physiological stress. 3. Chain of Transmission – from patients to doctors to other patients. Lack of handwashing!

  20. What Normal Microbiota become Nosocomial Infections • E. coli, Enterococcus faecalis, and Staph. saprophyticus cause roughly ~50% of all nosocomial infections. Due to urinary catheterizations that push fecal bacteria into the bladder (bladder infection- cystitis) High mortality rate. • E. coli causes roughly ~25% of all nosocomial infections due to colon surgery. Clostridium difficile from prolonged use of antibiotics which destroys normal bacterial communities.

  21. Lower respiratory tract pneumonia causing microbes. ~12% of all nosocomial infections. Pneumocystis carinii is the most common opportunist in AIDS patients. • Cutaneous (skin) infections, ~ 8% of all nosocomial infxns. Staph. aureus outbreaks in nurseries and bedsores in long term care patients. Ex. Methicillin Resistant Staph aureus (MRSA). • Bacteriemia – bacteria accidentally introduced into blood stream by contaminated intravenous fluids. Ex. portacaths (implanted caths) or dialysis.

  22. Portacaths

  23. What makes microbes pathogenic or virulent?

  24. SEVEN MECHANISMS OF PATHOGENESIS • Maintain a reservoir – in humans (carriers), animals (zooneses), water, soil, dust etc. • Adherance hooks, spikes, tacky chems • Anti-phagocytic properties: capsule, Wax D, M-protein in Streptococcus pyogenes, and antigenic drift in Influenza (virus), Neisseria (bacteria), and Trypanosomes (protozoan).

  25. Adhesion: How do pathogens stick? • Fimbriae (bacterial projections) • Capsules (bacterial coatings) • Spikes (viral particles) • Hooks (Treponema) or flagella (Salmonella) Vibro cholerae attaching to intestinal cells

  26. 4. EXOENZYMES – secreted by pathogens • Hemolysin – lysis of erythrocytes (RBC) • Leukocidin – degrades lysosomes, the digestive vacuole found in phagocytes. Staph. aureus. • Coagulase – clots blood Staph aureus. • Streptokinase – dissolves clots ex. Strep. and Staph. • Hyaluronidase –hydrolyzes the “glue” that holds cells together, I.e. the dermis to the epidermis. Leaves tissues black. ex. Clostridium perfringens causes gas gangrene.

  27. Collagenase – degrades collagen, Strep. pyogenes (necrotizing faciitis) • Urease – ex. Helicobacter pylori survives at low stomach pH. Causes ulcers. http://www.bact.wisc.edu/Bact330/lecturehelico2 • Neisseria gonorrhea degrades imunoglobulin (IgA) found in mucous rendering its antibody activity to be lost.

  28. 5. SIDEROPHORES Most pathogens obtain iron from the host by secreting these low molecular weight proteins into the blood which strip iron from transferrin, a glycoprotein in the blood.

  29. Secreted to attack specific targets Toxic in small amounts Polypeptide composition Unstable at 60 C Convert to toxoid Stimulate antitoxins No fever Found in cell wall of gram – bacteria Released on cell lysis Toxic in high doses Lipopolysaccharide composition Stable at 60 C Do not convert to toxoid Do not stimulate antitoxins Fever Exotoxins Endotoxins

  30. 6. EXOTOXINS • Toxic proteins secreted by bacteria that disrupt cell membranes. • Toxemia – exotoxins in blood or lymph. • Toxoid – inactivated altered exotoxins used for vaccination. • Exotoxins are toxic in small quantities. • Exotoxins are heat labile (sensitive) iftreated at 60 degrees Celsius for 30 minutes.

  31. f. Three examples of powerful exotoxins: 1. Cytotoxins – kill host cells by disrupting protein synthesis. Toxoid used in “D” part of the DTP vaccine. ex. Corynebacterium diphtheriae 2. Neurotoxins – act on nerve cells ex. Clostridium tetani – (tetanus) blocks Ach inhibitors and leaves ACh on. Spastic paralysis. ex. Clostridium botulinum – (botulism) binds ACh receptors blocking them. Flaccid paralysis. 3. Enterotoxins – binds to villus cells causes excess loss of water and electrolytes (gastroenteritis). ex. Vibrio cholerae.

  32. ENDOTOXIN – also known as “Lipid A” • Found in lipopolysaccharide of Gram – cell wall. • Heat resistant. • Toxic only in large quantities • No toxoid (vaccine) available • Limulus test – an industrial Lipid A detection method used by manufacturers of IV fluids. (Came from horsehoe crab)

  33. f. PHYSIOLOGICAL EFFECTS OF LIPID A In Six Easy Steps! Causes Endotoxic Shock, synonymous with Blood Poisoning, and Sepsis Shock. 1. Originates with lysed Gram – bacteria in blood (bacteremia). Lipid A fragments of Gram - cell wall are scattered throughout cardiovascular system, and becomes lodged in the capillary network of vital organs.

  34. Prostaglandins are released by endothelial cells in contact with Gram – bacteria causing vasodilation. • Macrophage (MP) phagocytize some Gram – bacteria. MP release IL-1 signals the hypothalamus to produce fever. Fever has 3 benefits: Inactivates bacterial enzymes, hides iron from bacteria, and increases leukocytic infiltration. • Neutrophils cannot squeeze through endothelial cells to reach lipid A lodged in basement membrane of capillaries. “Frustrated” neutrophils release digestive enzymes on endothelial cells.

  35. 5. On massive scale causes Disseminated Intravascular Coagulation (D.I.C.). 6. Result: Endotoxic Shock. Impaired oxygen exchange in lungs leads to coma, and death. ~ 175,000 deaths per year in the U.S. 7. Diseases that cause Endotoxic Shock: a. Neisseria meningitidis meningitis b. Salmonella typhi – typhoid fever c. Nosocomial infections (cystitis) Opportunistic Gram - (E. coli)

  36. Application of Pathogenesis: Bioterror • NOVA “Bioterrorism” http://www.pbs.org/wgbh/nova/bioterror/biowarriors.html

  37. Body Defenses Overview • 1st line of defense (physical, chemical and genetic barriers) • 2nd line of defense (Inflammation, Interferons, Phagocytosis) (linked to 3rd) • 3rd line of defense (Immune response)

  38. Body Defenses Nonspecific Immunity (Innate) offers general protection from all pathogens. I. Skin - the largest organ of the body in terms of surface area. A. Epidermis - outer thin layer contains stratified squamous epithelium. Forms a barrier against most pathogens. Keratinocytes secrete keratin, a type of wax. Most microbiota is located here.

  39. Body Defenses cont. GA f 07 • Dermis – skin’s inner thicker part composed of connective tissue made of collagen. • 1. Dendritic cells are a type of phagocyte found in the skin derived from monocytes. These cells migrate to the lymph nodes after phagocytosis. • 2. Mast cells release histamine during inflammation. Not normally in circulation but in the skin. • Suderiferous glands produce sweat. Sweat contains lysozyme and NaCl which inhibits most bacteria except - Staphylococcus epidermidis • Sebacous glands produce sebum, an unsaturated fatty acid, lowers skin pH to 4.0.

  40. Dendritic Cell

  41. Dendritic Cells

  42. Skin Diagram (Cross Section) (Nerve ending)

  43. Body Defenses cont. C. Subcutaneous Tissue – mostly themembranes that line the G.I.T., G.U.T., and R.T! 1. Goblet cells secrete mucus. Prevent cells from drying out and cracking. Keeps bacteria flowing over the surface of cells lining tracts of the body. 2. Ciliated columnar cells wave dirt, dust and bacteria out of the body. In the R.T., cilia wave particles up toward the epiglottis where they are swallowed. The "muco-ciliary escalator." 3. Hydrochloric Acid (HCl) pH 1.8 stomach 4. Salivary glands 1 liter of saliva per day. Bathes teeth with lysozyme (destroys peptidoglycan layer ). 5. Lacrimal glands produce tears, contain lysozyme.

  44. Mucous membranes

  45. Phagocytic System II. Phagocytic System - Phagocytosis (to eat) A. Mechanism Fig. 16.3 1. Chemotaxis - chemical attraction of phagocytes to a microbe. 2. Adherence - attachment 3. Ingestion - pseudopods extend around microbe. 4. Digestion - the plasma membrane of a phagocytic cell pinches off into the cell and forms a vacuole (phagosome). Lysosomes fuse with phagosome. Contain nitric oxide and lysozyme which kills microbes, and digestive enzymes that degrade microbes.

  46. Phagocytosis diagram

  47. Five Leukocytes B. Five Types of Leukocytes (wbc’s)- made in the bone marrow (Figure 16.1 p. 448). 3 Granulocytes- with granules in cytoplasm. 1. Neutrophils stain poorly and have 2- 7 nuclei. 1st phagocytes to arrive at site of inflammation. 60% of blood leukoctyes. 2. Eosinophils stain red have 2 nuclei and phagocytize large parasites (protozoans, worms and fungi).2-4%. 3. Basophils stain blue and release histamine during inflammation. Non- phagocytic. < 1%.

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