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CHAPTER 5 REQUIREMENTS FOR INFECTION © Professor P. M. Motta et al / Science Photo Library WHY IS THIS IMPORTANT? • This chapter introduces the mechanisms involved in the infectious disease process. • Understanding the requirements for infection is critical to understanding prevention and treatment of disease. • Four of the five requirements for infection will be discussed in this chapter. OVERVIEW REQUIREMENTS FOR A SUCCESSFUL INFECTION • • • • • Entry – getting in Establishment – staying in Defeat the host defenses Damage the host Exit the host and be transmitted to another host 1) Entry 2) Colonization 3) Immune evasion 4) Growth / replication 5) Exit / disease transmission PORTALS OF ENTRY (GETTING IN) • Any point at which pathogens can enter is called a portal of entry. Entry via broken skin is referred to as Parenteral inoculation. PORTALS OF ENTRY (GETTING IN) MUCOUS MEMBRANES • Mucous membranes are in direct contact with the external environment. • They allow pathogens to gain access into the body. • They are found in the: – Respiratory tract – Gastrointestinal tract – Genitourinary tract THE RESPIRATORY TRACT • This is the most favorable portal of entry to pathogens because we have to breathe continuously. • Pathogens can be found on droplets of moisture as well as on dust particles. THE GASTROINTESTINAL (GI) TRACT • This is the second most favorable portal of entry for pathogens since we have to eat and drink regularly. • It has many barriers to infection but is still the entry point for many pathogens. THE GI TRACT • The GI tract is also an important portal of exit. – Pathogens can be found in fecal material after leaving the body. • The fecal-oral route of contamination is very important in the infection process. THE GI TRACT • Helicobacter pylori infects the stomach and duodenum of the small intestine. • It survives the acidic environment of the stomach by producing an alkaline halo around itself. • It takes up residence in the mucus that lines the stomach and duodenum. • Infection with H. pylori is a known risk factor for stomach and duodenal ulcers. THE GENITOURINARY TRACT • This portal of entry is more complicated than the ones previously discussed. • Urinary tract infections (UTIs) are more common in women than in men. • These types of infections cause major problems in hospitals and clinical settings. • Diseases of the reproductive tract are usually sexually transmitted and are also part of this portal of entry. SKIN • The skin is the largest organ in the body. • The large surface area of the skin provides a vast area through which microorganisms may enter the body. • Many microorganisms reside on the skin. • Skin provides an impermeable barrier to most microbes and must be broken to allow entry. THE PARENTERAL ROUTE • The term parenteral route refers to breaks in the skin which permit entry of microorganisms. • The parenteral route depends on injections, cuts, or wounds, and surgical procedures to provide an entry point. • Insect bites can also allow entry of microbial organisms. • Insect transfer is referred to as vector transmission. ESTABLISHMENT (STAYING IN) • After entry into the host, pathogens must find a way to stay in the body. • Pathogens use structures, such as capsules or fimbriae to attach to the surface of cells or tissues. ESTABLISHMENT (STAYING IN) • Pathogens can use adhesins (glycolipids or glycoproteins) to adhere to tissue. • An example of this is the plaque found on teeth. – Plaque forms when a pellicle coats the tooth and bacteria subsequently adhere to it. – As many as 300 to 400 different types of bacteria will adhere to each other building a biofilm on the tooth. This is the plaque. ESTABLISHMENT (STAYING IN) Spirochetes like Treponema pallidum (the causative agent of syphilis) corkscrew into tissues. © CDC/ Dr. David Cox INCREASING THE NUMBERS • Increasing the number of pathogens can establish the infection in the host. • Rapid growth and increased numbers of pathogens can happen very quickly. – Some pathogens can double their numbers in as short a period as twenty minutes. – An organism that doubles every twenty minutes will become 1 x 1021organisms in just 24 hours. • Some pathogens are more infectious and virulent than others. • We use the terms ID50 and LD50 to characterize these differences between pathogens. INCREASING THE NUMBERS • ID50 = infectious dose 50% – The number of organisms required for 50% of the host population to show signs of infection. • LD50 = lethal dose 50% – The number of organisms required to kill 50% of a host population. INCREASING THE NUMBERS • Binary fission is the form of reproduction seen in most bacteria. One cell divides to yield two. Two divide to become four and so on. The number of bacteria can increase very quickly. INCREASING THE NUMBERS • In viral infections, the number of viruses increases even more dramatically. • Virally infected cells will lyse (burst) and this releases millions of viral particles. – Each particle can infect a new cell. – Each newly infected cell will produce millions of viral Attachment particles. Infection Release of Viral Particles (Cell Death) Assembly of Viral Particles Biosynthesis DEFEATING THE HOST DEFENSES • The body possesses powerful defense mechanisms. • Pathogens must avoid, evade, or compromise these defenses in order to survive and thrive. • Pathogens can defeat host defenses in 2 ways: – Passive defense – using built-in structures found on the pathogen cell. – Active defense – attacking the host defenses VIRULENCE FACTORS • Pathogens use virulence factors as part of the infection process. – They allow pathogens to survive and thrive in the host. – They make harmless organisms dangerous and make dangerous organisms deadly. PASSIVE DEFENSE: Capsules The main passive defense mechanism is the bacterial capsule which inhibits phagocytosis by host cells. • Cell wall componentsDEFENSE: can also contribute passive PASSIVE CelltoWalls defense. – M proteins are found in the cell wall of streptococcus. • They increase virulence by increasing adherence to host cells • They can also inhibit phagocytosis. • Can also cause toxic shock -Protein A found on Staphylococcus aureus binds the “tail end” of host antibodies to evade detection PASSIVE DEFENSE: Cell Walls • Another method of passive defense is through components of the bacterial cell wall. – Mycolic acid is a waxy material found in the cell walls of Mycobacterium species. • It can inhibit phagocytosis and the entry of antibiotics. ACTIVE DEFENSES: Enzymes • Active bacterial defenses involve the production of extracellular enzymes which can: – Increase protection against host defenses (e.g. coagulase). – Enable the spread of infection by attacking and killing host defensive cells (e.g. staphlyokinase). • • • • • EXAMPLES OF BACTERIAL DEFENSIVE ENZYMES Leukocidins – destroy white blood cells. Hemolysins – attack red and white blood cells. Coagulase – causes the formation of fibrin clots. Kinases – break down fibrin and destroy clots. Hyaluronidase and collagenase – break down connective tissue and collagen HIDING FROM THE HOST DEFENSE • Pathogens can hide in host cells to avoid the host immune response. – Viruses are obligate intracellular parasites and can easily enter host cells. – Some bacteria use the host cell cytoskeleton (microtubules and microfilaments) to get into and move around a host cell. – Other bacteria reside in phagocytic vesicles. DAMAGING THE HOST • Most of the damage to a host can be divided into two causes: – Damage that occurs because pathogens are present and active. (Virulence) – Damage that occurs because of host defense mechanisms. (Collateral damage from the host immune response) DAMAGING THE HOST • Damage to the host committed by the pathogen can be direct or indirect – Direct damage • Is obvious and includes the destruction of host cells or tissues • Is usually controlled by the host immune response. – Indirect damage • Involves systemic infection as a result of toxin production by the pathogen. BACTERIAL TOXINS • Bacterial toxins are: – toxic – Soluble in aqueous solutions – Easily diffusible into blood and lymph which causes distal pathology. BACTERIAL TOXINS • Bacterial toxins can produce fatal outcomes in patients. • They produce common symptoms such as fever, shock, diarrhea, cardiac and neurological trauma, and the destruction of blood vessels. • There are 2 types of toxins: – Exotoxins – Endotoxins EXOTOXINS • Exotoxins are produced by and exported from certain pathogens and then enter host cells. • They are among the most lethal substances known. • They are usually an enzymatic protein soluble in the blood and lymphatic system. EXOTOXINS • Exotoxins rapidly diffuse into tissues where they inhibit metabolic function. • They are usually produced as pro-enzymes. • Many genes that code for toxins are carried on plasmids or spread by phages. Phage encoded toxins: •Cholera toxin •Diphtheria toxin •Botulinum toxin •Shiga toxin •Staphylococcal exfoliative toxin and enterotoxins •Streptococcus pyrogenic toxin Plasmid encoded toxins: Anthrax toxins Clostridium enterotoxins EXOTOXINS • There are 3 types of exotoxins: – Cytotoxins – kill cells – Neurotoxins – interfere with neurological signaling – Enterotoxins – affect the lining of the digestive system. EXOTOXINS EXOTOXINS: Anthrax Toxin • Anthrax toxin is a cytotoxin. • It is produced by Bacillus anthracis (a grampositive rod commonly found in pastures). • It is made up of three parts which are: – Produced separately within the pathogen – Assembled outside the anthrax organism cell wall. • It increases vascular permeability in host cells. EXOTOXINS: Diphtheria Toxin • Diphtheria toxin is a cytotoxin. • It is produced by Corynebacterium diphtheriae. • It is first produced in an inactive form. • It inhibits protein synthesis in the host. • A single molecule can kill a host cell. EXOTOXINS: Diphtheria Toxin • The structure of diphtheria toxin is well studied and composed of 2 chains called α and β (A-B toxin). • The β chain binds to the target cell and facilitates the entry of the α chain. • The α chain causes inhibition of protein synthesis. EXOTOXINS: Botulinum Toxin • Botulinum toxin is a neurotoxin. • It is produced by Clostridium botulinum. • There are seven forms of this toxin, all of which inhibit the release of the neurotransmitter acetylcholine. – This disrupts neurological signaling of the skeletal muscle. – This disruption causes paralysis. EXOTOXINS: Tetanus Toxin • Tetanus toxin is a neurotoxin. • It is produced by Clostridium tetani. • It causes loss of skeletal muscle control. – Prevents muscle relaxation – Causes uncontrollable convulsive muscle contractions – Lock jaw is an early symptom EXOTOXINS:Vibrio Toxin • Vibrio toxin (also known as cholera toxin) is an enterotoxin. • It is produced by Vibrio cholerae. • It has a 2 chain polypeptide structure – The β chain binds to the target cell •The release of large – The α chain causes cells to release large amounts of amounts of electrolytes electrolytes. causes potentially lethal diarrhea and vomiting. EXOTOXINS: S. aureus Toxin • Toxic shock syndrome is caused by the enterotoxin from Staphylococcus aureus. • This condition causes excessive loss of electrolyte fluids. • The loss of the fluids leads to hypotensive shock. ENDOTOXINS • The damage to the host caused by endotoxins is very different from the damage caused by exotoxins. • Endotoxins are part of Gram-negative cell walls and are released on the death of the host. – Endotoxins are released in the form of Lipid A. EXOTOXINS AND ENDOTOXINS ENDOTOXINS • Endotoxins cause the following symptoms: – – – – – Chills Fever Aches Muscle weakness Large amounts of endotoxins can cause disseminated intravascular clotting (DIC). ENDOTOXINS • Exotoxins can elicit an immune response. • Endotoxins do not elicit an immune response. • Endotoxins can contaminate materials and equipment. • There are tests for endotoxin contamination. VIRAL PATHOGENIC EFFECTS • Viral host cell damage is referred to as a cytopathogenic effect (CPE). • The cytopathogenic effect of viruses occurs in three ways: – From viral overload – From cytocidal effects (killing of host cells) – From noncytocidal effects (damage caused by host defense) • Viral cytopathology can be seen microscopically. – Viral inclusions such as Negri bodies can be seen in rabies infections. – The presence of syncytia (large fused cells)