BIO221 Chapter 15 Microbial Mechanisms of Pathogenicity
Inclusion Body
A granule or viral particle in the cytoplasm or nucleus of some infected cells; important in the identification of viruses that cause infection
Waxy Lipid
(mycolic acid) that makes up the cell wall of Mycobacterium tuberculosis also increases virulence by resisting digestion by phagocytes, and can even multiply inside phagocytes
Hemolytic
Destruction of the red blood cells inside of your body, usually by a toxin
Resistance (R) Factor
A bacterial plasmid carrying genes that determine resistance to antibiotics
Mycotoxin
A toxin produced by a fungus
Adhesin
A carbohydrate-specific binding protein that projects from prokaryotic cells; used for adherence, also called a Ligand
Lipid A
Endotoxin. Lipid portion of the membrane's lipopolysaccharide
Ligand
A carbohydrate-specific binding protein that projects from prokaryotic cells; used for adherence, also called an Adhesin
Aflatoxin
A carcinogenic toxin produced by Aspergillus flavus.
Invasin
A surface protein produced by Salmonella typhimurium and Escherichia coli that rearranges nearby actin filaments in the cytoskeleton of a host cell
Cadherin
A glycoprotein called which bridges the junctions, to move from cell to cell
Which of the following statements is false?
Coaglulase destroys blood clots
Exoenzymes
Extracellular enzymes
Endotoxic Shock
Septic shock caused by gram-negative endotoxins
Streptolysins
A hemolytic enzyme, produced by streptococci
Toxemia
The presence of toxins in the blood
Types of Exotoxins
Exotoxins are divided into three principal types on the basis of their structure and function: (1) A-B toxins (2) membrane-disrupting toxins (3) superantigens
Fever Response caused by Endotoxins
1. Gram-negative bacteria are ingested by phagocytes. 2. As the bacteria are degraded in vacuoles, the LPSs of the bacterial cell wall are released. These endotoxins cause macrophages to produce cytokines called interleukin-1 (IL-1),formerly called endogenous pyrogen,and tumor necrosis factor alpha (TNF-α) 3. The cytokines are carried via the blood to the hypothalamus, a temperature control center in the brain. 4. The cytokines induce the hypothalamus to release lipids called prostaglandins, which reset the thermostat in the hypothalamus at a higher temperature. The result is a fever.
Production of Toxins
1. Poisonous substances produced by microorganisms are called toxins; toxemia refers to the presence of toxins in the blood. The ability to produce toxins is called toxigenicity. 2. Exotoxins are produced by bacteria and released into the surrounding medium. Exotoxins, not the bacteria, produce the disease symptoms. 3. Antibodies produced against exotoxins are called antitoxins. 4. A-B toxins consist of an active component that inhibits a cellular process and a binding component that attaches the two portions to the target cell, e.g., diphtheria toxin. 5. Membrane-disrupting toxins cause cell lysis, e.g., hemolysins. 6. Superantigens cause release of cytokines, which cause fever, nausea, and other symptoms; e.g., toxic shock syndrome toxin. 7. Endotoxins are lipopolysaccharides (LPS), the lipid A component of the cell wall of gram-negative bacteria. 8. Bacterial cell death, antibiotics, and antibodies may cause the release of endotoxins. 9. Endotoxins cause fever (by inducing the release of interleukin-1) and shock (because of a TNF-induced decrease in blood pressure). 10. Endotoxins allow bacteria to cross the blood-brain barrier. 11. The Limulus amebocyte lysate (LAL) assay is used to detect endotoxins in drugs and on medical devices.
Pathogenic Properties of Fungi, Protozoa, Helminths, and Algae
1. Symptoms of fungal infections can be caused by capsules, toxins, and allergic responses. 2. Symptoms of protozoan and helminthic diseases can be caused by damage to host tissue or by the metabolic waste products of the parasite. 3. Some protozoa change their surface antigens while growing in a host, thus avoiding destruction by the host's antibodies. 4. Some algae produce neurotoxins that cause paralysis when ingested by humans.
Pathogenic Properties of Viruses
1. Viruses avoid the host's immune response by growing inside cells. 2. Viruses gain access to host cells because they have attachment sites for receptors on the host cell. 3. Visible signs of viral infections are called cytopathic effects (CPE). 4. Some viruses cause cytocidal effects (cell death), and others cause noncytocidal effects (damage but not death). 5. Cytopathic effects include stopping mitosis, lysis, formation of inclusion bodies, cell fusion, antigenic changes, chromosomal changes, and transformation
Opa
A bacterial outer membrane protein; cells with Opa form opaque colonies
In response to the presence of endotoxin, phagocytes secrete tumor necrosis factor (TNF). This causes
A fever; a decrease in blood pressure
Biofilm
A microbial community that usually forms as a slimy layer on a surface
Saxitoxin
A neurotoxin produced by some dinoflagellates
Phalloidin
A peptide toxin produced by Amanita phalloides,affects plasma membrane function
Amanitin
A polypeptide toxin produced by Amanita spp., inhibits RNA polymerase
Antitoxin
A specific antibody produced by the body in response to a bacterial exotoxin or its toxoid
Lysogeny
A state in which phage DNA is incorporated into the host cell without lysis
Septic Shock
A sudden drop in blood pressure induced by bacterial toxins
Fimbriae
An appendage on a bacterial cell used for attachment
Hemolysins
An enzyme that lyses red blood cells. Membrane-disrupting toxin that destroy erythrocytes (red blood cells), also by forming protein channels
Toxoid
An inactivated toxin
Toxin
Any poisonous substance produced by a microorganism
Adherence
Attachment of a microbe or phagocyte to another's plasma membrane or other surface. The attachment between pathogen and host is accomplished by means of surface molecules on the pathogen called adhesins or ligands that bind specifically to complementary surface receptors on the cells of certain host tissues. a). Surface projections on a pathogen called adhesins (ligands) adhere to complementary receptors on the host cells. b). Adhesins can be glycoproteins or lipoproteins and are frequently associated with fimbriae. c). Mannose is the most common receptor. d). Biofilms provide attachment and resistance to antimicrobial agents.
Kinases
Bacterial enzymes that break down fibrin and thus digest clots formed by the body to isolate the infection
Coagulases
Bacterial enzymes that coagulate (clot) the fibrinogen in blood. Fibrinogen, a plasma protein produced by the liver, is converted by coagulases into fibrin, the threads that form a blood clot. The fibrin clot may protect the bacterium from phagocytosis and isolate it from other defenses of the host
A-B Toxin
Bacterial exotoxins consisting of two polypeptides. Most exotoxins are A-B toxins. The A part is the active (enzyme) component, and the B part is the binding component. 1) In the first step, the A-B toxin is released from the bacterium. 2) The B component attaches to a host cell receptor. 3) The plasma membrane of the host cell invaginates (folds inward) at the point where the A-B exotoxin and plasma receptor make contact, and the exotoxin enters the cell by receptor-mediated endocytosis. 4) The A-B exotoxin and receptor are enclosed by a pinched off portion of the membrane. 5) The A-B components of the exotoxin separate. The A component alters the function of the host cell, often by inhibiting protein synthesis. The B component is released from the host cell, and the receptor is inserted into the plasma membrane for reuse.
Siderophores
Bacterial iron-binding proteins. When a pathogen needs iron, siderophores are released into the medium, where they take the iron away from iron transport proteins by binding the iron even more tightly. Once the iron-siderophore complex is formed, it is taken up by siderophore receptors on the bacterial surface. Then the iron is brought into the bacterium. In some cases, the iron is released from the complex to enter the bacterium; in other cases, the iron enters as part of the complex
How Bacterial Pathogens Penetrate Host Defenses
Capsules Cell Wall Components Enzymes Antigenic Variation Penetration into the Host Cell Cytoskeleton
Membrane-Disrupting Toxin
Cause lysis of host cells by disrupting their plasma membranes. Some do this by forming protein channels in the plasma membrane; others disrupt the phospholipid portion of the membrane. The cell-lysing exotoxin of Staphylococcus aureus is an example of an exotoxin that forms protein channels, whereas that of Clostridium perfringens is an example of an exotoxin that disrupts the phospholipids. Membrane-disrupting toxins contribute to virulence by killing host cells, especially phagocytes, and by aiding the escape of bacteria from sacs within phagocytes (phagosomes) into the host cell's cytoplasm
Antigenic Variation
Changes in surface antigens that occur in a microbial population. Some microbes vary expression of antigens, thus avoiding the host's antibodies
Which of the following organisms is most infectious?
E. coli - ID 50 = 20
Endotoxin
Endotoxins are released when gram-negative bacteria die and their cell walls undergo lysis, thus liberating the endotoxin. (Endotoxins are also released during bacterial multiplication.) Antibiotics used to treat diseases caused by gram-negative bacteria can lyse the bacterial cells; this reaction releases endotoxin and may lead to an immediate worsening of the symptoms, but the condition usually improves as the endotoxin breaks down. Endotoxins exert their effects by stimulating macrophages to release cytokines in very high concentrations. At these levels, cytokines are toxic. All endotoxins produce the same signs and symptoms, regardless of the species of microorganism, although not to the same degree. These include chills, fever, weakness, generalized aches, and, in some cases, shock and even death. Endotoxins can also induce miscarriage
Hyaluronidase
Enzyme secreted by certain bacteria, such as streptococci. It hydrolyzes hyaluronic acid, a type of polysaccharide that holds together certain cells of the body, particularly cells in connective tissue. This digesting action is thought to be involved in the tissue blackening of infected wounds and to help the microorganism spread from its initial site of infection. Hyaluronidase is also produced by some clostridia that cause gas gangrene
IgA proteases
Enzyme that can destroy IgA antibodies of the host
Direct Damage
Host cells can be destroyed when pathogens metabolize and multiply inside the host cells
Membrane Ruffling
Invasins affect actin in host membrane causing "folds"
Cell Wall Components
M Protein Fimbriae Opa Waxy Lipid Proteins in the cell wall can facilitate adherence or prevent a pathogen from being phagocytized
Penetration into the Host Cell Cytoskeleton
Major component of the cytoskeleton is a protein called actin, which is used by some microbes to penetrate host cells and by others to move through and between host cells. Bacteria may produce proteins that alter the actin of the host cell's cytoskeleton allowing bacteria into the cell
Portals of Entry - Mucous Membranes
Many bacteria and viruses gain access to the body by penetrating mucous membranes lining the respiratory tract, gastrointestinal tract, genitourinary tract, and conjunctiva, a delicate membrane that covers the eyeballs and lines the eyelids. Most pathogens enter through the mucous membranes of the gastrointestinal and respiratory tracts
Leukocidins
Membrane-disrupting toxins that kill phagocytic leukocytes (white blood cells)
A needlestick is an example of which portal of entry?
Parenteral route
Endotoxins are
Part of the gram-negative cell wall
Collagenase
Produced by several species of Clostridium, facilitates the spread of gas gangrene. Collagenase breaks down the protein collagen, which forms the connective tissue of muscles and other body organs and tissues
Differentiate between the terms pathogenicity and virulence
Pathogenicity is the capacity for a pathogen to cause disease; virulence is the degree of pathogenicity. For a pathogen to have high pathogenicity, it must be able to cause disease -have a portal of entry, adhere to the host, remain in the host for a long enough period of time to cause damage to the host (and while not a pure requirement for pathogenicity, have a portal of exit). If a pathogen can cause disease, then virulence would be the level; something quantitative like the quantity of microbes required expressed as ID50
Portals of Entry - Parenteral Route
Portal of entry for pathogens by deposition directly into tissues beneath the skin and mucous membranes
How Microorganisms Enter a Host
Portals of Entry Preferred Portal of Entry Numbers of Invading Microbes Adherence
Exotoxin
Produced inside some bacteria as part of their growth and metabolism and are secreted by the bacterium into the surrounding medium or released following lysis. Exotoxins are proteins, and many are enzymes that catalyze only certain biochemical reactions. Because of the enzymatic nature of most exotoxins, even small amounts are quite harmful because they can act over and over again. Bacteria that produce exotoxins may be gram-positive or gram-negative. The genes for most (perhaps all) exotoxins are carried on bacterial plasmids or phages. Because exotoxins are soluble in body fluids, they can easily diffuse into the blood and are rapidly transported throughout the body. Exotoxins work by destroying particular parts of the host's cells or by inhibiting certain metabolic functions. They are highly specific in their effects on body tissues. Exotoxins are among the most lethal substances known. It is the exotoxins that produce the specific signs and symptoms of the disease. Thus, exotoxins are disease specific.
Shock
Refers to any life-threatening decrease in blood pressure. Shock caused by bacteria is called septic shock. Gram-negative bacteria cause endotoxic shock
Gram-negative Sepsis
Septic shock caused by gram-negative endotoxins
Gram-positive Sepsis
Septic shock caused by gram-positive bacteria
A life-threatening decrease in blood pressure is
Shock
M Protein
The M protein mediates attachment of the bacterium to epithelial cells of the host and helps the bacterium resist phagocytosis by white blood cells. The protein thereby increases the virulence of the microorganism
Lysogenic Conversion
The acquisition of new properties by a host cell infected by a lysogenic phage
Portals of Entry
The avenue by which a pathogen gains access to the body. The portals of entry for pathogens are mucous membranes, skin, and direct deposition beneath the skin or membranes (the parenteral route). a) Many microorganisms can penetrate mucous membranes of the conjunctiva and the respiratory, gastrointestinal, and genitourinary tracts. b) Most microorganisms cannot penetrate intact skin; they enter hair follicles and sweat ducts. c) Some microorganisms can gain access to tissues by inoculation through the skin and mucous membranes in bites, injections, and other wounds. This route of penetration is called the parenteral route
Toxigenicity
The capacity of a microorganism to produce a toxin
Capsules
The capsule resists the host's defenses by impairing phagocytosis, the process by which certain cells of the body engulf and destroy microbes. The chemical nature of the capsule appears to prevent the phagocytic cell from adhering to the bacterium. 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
LD50
The lethal dose for 50% of the inoculated hosts within a given period
How Bacterial Pathogens Damage Host Cells
The microorganism can damage host cells in four basic ways: (1) by using the host's nutrients; (2) by causing direct damage in the immediate vicinity of the invasion; (3) by producing toxins, transported by blood and lymph, that damage sites far removed from the original site of invasion; and (4) by inducing hypersensitivity reactions
The most frequently used portal of entry for pathogens is the
The mucus membranes of the respiratory tract
ID50
The number of microorganisms required to produce a demonstrable infection in 50% of the test host population
Septicemia
The proliferation of pathogens in the blood, accompanied by fever; sometimes causes organ damage
Portals of Exit
The route by which a pathogen leaves the body. 1. Pathogens have definite portals of exit. 2. Three common portals of exit are the respiratory tract via coughing or sneezing, the gastrointestinal tract via saliva or feces, and the genitourinary tract via secretions from the vagina or penis. 3. Arthropods and syringes provide a portal of exit for microbes in blood.
Portals of Entry - Skin
The skin is the largest organ of the body in terms of surface area and weight and is an important defense against disease. Unbroken skin is impenetrable by most microorganisms. Some microbes gain access to the body through openings in the skin, such as hair follicles and sweat gland ducts. Larvae of the hookworm actually bore through intact skin, and some fungi grow on the keratin in skin or infect the skin itself
Enzymes
The virulence of some bacteria is thought to be aided by the production of extracellular enzymes (exoenzymes) and related substances. These chemicals can digest materials between cells and form or digest blood clots, among other functions. a) Local infections can be protected in a fibrin clot caused by the bacterial enzyme coagulase b) Bacteria can spread from a focal infection by means of kinases (which destroy blood clots), hyaluronidase (which destroys a mucopolysaccharide that holds cells together), and collagenase (which hydrolyzes connective tissue collagen). c) IgA proteases destroy IgA antibodies
Poisonous substances produced by certain microbes are called
Toxins
Cytopathic effects are changes in host cells due to
Viral infections
Plasmids, Lysogeny, and Pathogenicity
a) Plasmids may carry genes for antibiotic resistance, toxins, capsules, and fimbriae. b) Lysogenic conversion can result in bacteria with virulence factors, such as toxins or capsules.