44 notecards = 11 pages (4 cards per page)
A symbiotic relationship in which one organism benefits and other is unaffected
Both organisms benefit
One organism benefits, and is harmed
Emerging infectious diseases (EIDs)
Are ones that are new or changing, showing an increase in incidence in the recent past, or potential to increase in the near future.
What is an emerging disease?
Virus, bacterium, fungus, a protozoan, or helminth.
Factors contribute to EIDs
1)New strains, such as E. coli and influenza
2) a new serovar such as vibrio choke raw May result in changes in evolution of existing micros
3) Widespread use of antibiotics and pesticides encourages the growth of more resistant to micro
Variety factors continued
4) Global warming and changes in weather patterns may increase the distribution and survival if reservoirs and vectors resulting in the introduction and dissemination of diseases such as malaria and hantavirus pulmonary syndrome.
5) spread of diseases such as cholera and West Nile virus by modern transportation
6) previous unrecognized infections
7)incidence of a disease. The increase in Lyme disease
Total number of cases (old & new) in existence at a certain time in a designated population or
number of cases at a particular time
Number of people contracting the disease
Always present but not enough to be public health concern
Increase in mortality or morbidity in numbers it becomes a health concern
Word wide epidemic
Disease occurs in random and unpredictable manner.
The spread of infection
(reservoirs of infection)
1) a continual source of infection is called a reservoir of infection
2) people who have the disease or are carriers of pathogenic micro organisms are human reservoirs of infection
3) zoonoses are disease that affect animals and can be transmitted to humans
4) some pathogenic micros grow in no living reservoirs, such as soil & water
Transmission of disease
1) physical contact between the source of the disease and a susceptible host
2) by fomites (inanimate objects) constitutes indirect contact
3) via saliva, mucus
4) vehicle transmission water, food, airborne
5) arthropod vectors carry pathogens from one host to another by mechanical and biological transmission
The emergence of the new infectious diseases is probably due to all of the following EXCEPT
The need of bacteria to cause disease
Which of the following disease is not correctly matched to it's reservoir?
Correctly matched to it's reservoir
Be Familiar with concept of portals of entry
The specific route by which a particular pathogen gains access to the body is called its portal entry
Ways of portal entry
*Penetrate mucous membranes of conjunctiva and the respiratory, gastrointestinal, and genitourinary tracts. Most microorganisms cannot penetrate intact skin; they enter hair follicles and sweat ducts.
* Some can gain access to tissue by inoculation through the skin and mucous membranes in bites, injections, and other wounds. This route of penetration is called parenteral route.
* Surface projections on a pathogen called adhesions (ligands) adhere to complementary on the host cells
* Adhesions can be glycoproteins or lipoproteins and are frequently associated with fimbriae.
* Mannose is the most common receptor
( Biofilms attachment and resistance to antimicrobial agents.
How can Microbes penetrate into host cytoskeleton
Bacteria may produce proteins that alter the actin of the host cell's cytoskeleton allowing bacteria into the cell
Know the various classes of enzymes microbes can produce to spread and evade host defenses:
Coagulases- are bacterial enzymes that coagulate (clot) the fibrinogen in blood. Example: Coagulases are produced by some members of the genus staphylococcus; they may be involved in the walking-off process in boils produced by staph.
Kinases- are bacterial enzymes that break down fibrin and thus digest clots formed by the body to isolate the infection. Example: One of the better-known kinases is fibrinolysin (strepokinase) which is produced by such streptococci as Streptococcus pyogenes.
Hyaluronidase- enzyme which destroys a mucopolysaccharide that holds cell together Example: secreted by certain bacteria such as streptococci
Collagenase: enzyme which hydrolyzed connective tissue collagen Example: produced by several species of Clostridium, facilitates the spread of gas gangrene.
IgA proteases: destroy IgA antibodies
How do some microbes evade phagocytosis?
Phagocytes are not always successful; sometimes there are adherence problems, as with bacteria that comes with slimy capsules. Example: Strep pneumonia, and some organisms like TB can live inside the macrophage, resistant to its lysosome enzymes, unless the macrophages is further strengthened by chemicals released by T cells.
* However, the human body can produce antibodies against the capsule, and when these antibodies are present on the capsule surface, the encapsulated bacteria are easily destroyed by phagocytosis.
Be able to characterize, compare and contrast exotoxtins and endotoxins. Table 15.3 is useful.
How else do microbes damage the host?
1) Using the hosts nutrients: Bacteria get iron from the host using siderophores
2) Direct damage:Host cells can be destroyed when pathogens metabolize and multiplying inside host cells.
3)The production of toxins
Chapter 16-- innate host defenses
What are the physical and in a general sense, that along with normal microbiota constitute the body's first line of defense against pathogenic microbes?
First like of defense:
1)The structure of intact skin and waterproof protein keratin provide resistance to microbial invasion.
2) Some pathogens can penetrate mucous membranes.
3) The lacrimal apparatus protects the eyes from irrupting substances and microorganisms.
4) Saliva washes microorganisms from teeth and gums
5) Mucus traps many microorganisms that enter the respiratory and gastrointestinal tracts; in the lower respiratory, the ciliary escalator moves music up and out.
6) The flow of urine moves microorganisms out of the urinary tract, and vaginal secretions move microorganisms out of the vagina.
What are the Chemical Factors, that along with normal microbiota constitute the body's first line of defense against pathogenic microbes?
1) Fatty acids in sebum and earwax inhibit the growth of pathogenic bacteria.
2) Perspiration washed microorganisms off the skin
3) Lysozyme is founds in tears, saliva, nasal secretions, and perspiration.
4) The high acidity (pH 1.2-3.0) of gastric juice prevents microbial growth in the stomach.
What are the roles of the various leukocytes and their derivatives: Types of phagocytes and their origins, natural killer cells?
How do phagocytes do their jobs?
Phagocytes are cells that engulf and ingest forge in matter and cellular debris
1) circulating in the blood these include neutrophils and monocytes
2) In the tissues are macrophages, which may be wondering or fixed (lung alveolar macrophages, dendritic cells, Kupffer cells of the liver, microglia of the brain, macrophages or reticuloendothelial cells of lymphoid tissue)
3)Toll like receptors
Explain the process of inflammation, its cardinal signs and they're caused, including chemical mediators, processes, and results
1) Rubor (Redness)- Vasodialation and increased blood flow
2) Tumor- Swelling from leakage of fluid into tissues
3) Calor- heat also from increased blood flow
4) Dolar-pain from swelling and some chemicals
A fifth sign sometimes present is loss of function due to swelling in joint.
How does fever benefit the host?
Mild to moderate fever is beneficial; too high may cause enzymes denaturation; pyrogens (II-1) secreted by leukocytes and macrophages exposed to for gin substances reset the brain's thermostat" in the hypothalamus
a) fever increases tissue metabolic rate speeding repair
b) fever inhibits the multiplication of bacteria as the body sequesters iron and zinc in the liver and spleen during fever (these are necessary minerals for bacterial growth)
c) can enhance interferon's actions
How do interferons alfa and beta "interfere with" viral infections?
Interferons-- alpha and beta types are chemicals produced by body cells, including fibroblasts of connective tissue, infected y viruses.
Alpha and beta interferons protect other cells attacked by viruses by blocking viral replication, example They enable those cells to block the virus from taking over cellular machinery to make more viruses.
What cells make gamma interferon, and what does it do?
Gamma interferons produced by lymphocytes activate macrophages and mobilize NK cells; they stimulate macrophages to make nitric oxide which enhances their killing power.
What is the complement system?
Complement--about 30 plasma proteins circulating in the blood plasma in an inactive state; also known as the complement system
What are the three primary outcomes of the complement system?
A. "MAC attack": forms a membrane attack
complex (MAC) that makes holes in invaders’ cell membranes allowing
water to rush in and cause cell lysis
And in general what are the three ways it is activated? How does it "complement" the adaptive immune system? You need not memorize the numbers of the particular components or their individual actions, but understand the idea of cascade and amplification.
What are the following and how do they figure in innate immunity? Lysozyme, macrophages, dendritic cells, Toll-like receptors, cytokines, opsonization, chemotaxis, apoptosis, antimicrobial peptides
Lysozyme- an enzyme capable of breaking down cell walls of Gram + bacteria, found in tears, saliva, nasal secretions and tissue fluid.
Macrophages-The chief phagocytes are macrophages "big eaters" which derive from white blood cells called monocytes that leave the bloodstream, enter the tissues and develops macrophages.They wander throughout the tissue spaces in search for cellular debris of "foreign invaders".
Dendritic Cells- Protective cells that phagocytize antigens, migrate to lymph nodes, and present the antigen T cells, causing them to activate and mount an immune response; called epidermal dendritic cells or langerhans cells in the skin.
Toll-like Receptors- protein receptors, on defensive cells (macrophages and dendritic cells) that encounter components of microbe and induce defense cells to release cytokines.
Cytokines-can increase the inflammatory response and activate B and T cells; A small protein released from human cells that regulates the immune response, directly or indirectly may induce fever, pain, or T cell proliferation.
Opsonization- certain complement proteins can bind to
microbes, thereby enhancing phagocyte adherence to and ingestion of
the microbes; opsonize means “to make tasty”
Chemotaxis- is the chemical attraction of phagocytes to microorganisms. Book definition- Movement in response to the presence of a chemical.
Apoptosis-cutting of genome, blebbing, digestion,
calling in of phagocytes--intra-cellular contents, including pathogens
are not released
Antimicrobial peptides-recently discovered and found in most forms of life; over 600 identified to date; produced in humans by neutrophils, macrophages, platelets, and epithelium; names generally end in -in as in defensins; have less than 100 amino acids and usually a positive charge which facilitates disruption of microbial membranes which have negative charge; may block viral receptors and target intracellular targets in bacteria, such as nucleic acid and protein synthesis; resistance to them does not appear to develop; also stimulate or participate in other immune functions such as attracting dendritic cells and stimulating mast cells to release histamine; even sequester endotox
Antibiotics--a brief look: Chapter 20 figs 20.2 and 20.10
Page 561- and 580
Know in general the ways antibiotics work against bacteria
* Antimicrobial drugs target certain essential functions of the microbe. Mechanisms of actions include inhibiting cell wall synthesis, inhibiting proton synthesis, inhibiting nucleic acid synthesis, injuring the plasma membrane, or inhibiting synthesis of essential metabolites.
*The antimicrobial drug must not interfere with essential functions of the microbes host.
Know in general the defenses against them bacteria have developed.
* There are only a few mechanisms of microbial resistance to antimicrobial agents: blocking the drugs entry into enzymes, alteration of the drugs target site, efflux on the drug from the cell, or alteration of the metabolic pathways of the host.
*The mechanisms of bacterial resistance to antibiotics are limited. Knowledge of these mechanisms is critical for understanding the limitations of antibiotic use.