Infectious Diseases Flashcards
Describe what is meant by the term communicable disease
Communicable disease is defined by diseases which can be transmitted from one host to another unaffected individual. Grows in host before being shed.
Describe the different types of microbes and infectious agents
- Prokaryotic organisms - single cell organisms with no nucleus or defined organelles. (e.g. bacteria)
- Eukaryotic organisms - single or multi-celled organisms with defined nucleus and organelles. (e.g. fungi, protozoa, helminths, malaria, pinworms, tapeworms/
- Viruses - DNA or RNA surrounded by protein capsule; obligate parasite
- Prions - Infectious proteins
Define opportunistic infection
In immunocompromised host, the indigenous flora gain access to normally sterile tissue/sites of the body, colonizes the site, and causes
Describe the obligatory steps in microbial infection and transmission between hosts
Pathogens must colonize a host and invade a target tissue or organ for disease to be caused.
Transmission between hosts:
- respiratory or salivary spread
- faecal-oral spread
- venereal (sexual) spread
- Vectors (insects)
- Vertebrae (animals) reservoir
- Vector-vertebrate (animals and insects) reservoir
Describe the chronology of vaccine development (e.g. contributions of Jenner, Pasteur)
Edward Jenner - gave people cowpox and noticed they didn’t get small pox afterwards
Louis Pasteur - Debunk the theory of spontaneous generation of microbes. Boiled bacteria broth, sealed flask, and showed that no new cells grew.
Describe the sanitary movement; Van Leeuwenhoek, microscopes and the discovery of “animalcules” and Lister’s contribution
- Sanitary movement - Need for clean water and air in highly populated areas
- Dr. John Snow - traced the source of cholera outbreak to a waterhole in London
- Van Leeuwenhoek - Invented microscope and observed ubiquity of microscopic life
- Dr Joseph Lister - Surgical fever and abscess are due to bacteria in wounds.
Describe the contagion theory
Contagion theory: communicable diseases were the work of an external and transmissible
Miasma theory: Disease was due to “bad air” that caused the imbalance of “blood, phlegm, black and yellow bile”
Discuss Koch’s postulates and the germ theory of communicable disease
Germ theory of communicable disease: Diseases are caused by microorganisms which will invade hosts and grow and reproduce within their host to cause disease
Koch’s postulates
- microbe must be present in every case of the disease
- Microbe must be isolated from the diseased host and grown in pure culture
- disease must be reproduced when a pure culture is introduced into a non-diseased susceptible host
- Microbe must be recoverable from an experimentally infected host.
Modifications on Koch’s postulates - not all microbes can be cultured in vitro and so many communicable diseases do not have experimental animal models
Outline advances in bacterial culture and staining
Advances in bacterial culture
- Koch used solid media for pure cultures
- Gelatin -> Agar
gram staining - used to determine if peptidoglycan wall is present on a bacteria species
Describe the discovery of toxin-mediated diseases
- In 1888 Yersin and Emile Roux isolated a toxin secreted by the diptheria bacteria
- showed that the toxin alone caused symptoms of the disease
Describe the discovery of the role of insects in disease transmission
In 1898 Ross and Grassi demonstrated that malaria was transmitted by anopheles mosquitoes.
Describe the discovery of viruses
- Reed showed yellow fever was caused by agent that could pass through porcelain filter
- In 1898 Loeffler and Frosch demonstrate that filtrates of lesion fluid collected from animals infected with foot–and-mouth diseases could transmit the disease into susceptible animals
- Visualization of viruses was only achieved in the mid 20th century via electron microscopes.
Describe how poliomyelitis drove vaccine research
- Epidemic of poliomyelitis led to governments to conduct research of vaccination against polio
- Jonas Salk developed an inactivated polio vaccine in 1955
- Albert Sabin generated a second Polio vaccine which could be given orally and was able to transmit from person to person. It was used to eradicate Poliomyelitis
Describe the discovery of penicillin, antibiotics and antivirals
- Alexander Fleming discovered antibacterial properties of fungal toxin Penicillin
- while working on staphylococci, penicillium mould was surrounded by a bacteria-free zone
- Penicillin mould culture prevented growth of staphylococci even diluted 800 times
Outline the classification of bacteria
Gram staining:
- gram-positive bacteria have a much thicker peptidoglycan layer than Gram-negative bacteria
- steps to gram stain:
1) crystal violet applied to bind with peptidoglycans in wall (more retained in gram-positive)
2) gram’s Iodine applied to seal in crystal violet dye
3) Decolorizer (acetone/alcohol) washes away crystal violet from gram-negative bacteria
4) Carbol fushsin/safranin counter-stain stains gram-negative bacteria pink
shape:
- bacilli - elongated/rod-shaped bacteria
- cocci - spherical shaped bacteria
Respiration:
- anaerobes - can grow in environments without oxygen
- Aerobes - require oxygen
- Facultative anaerobes - use aerobic respiration when oxygen is present, but can switch to anaerobic
Reproduction:
- clusters - staphylo- (multidirectional growth)
- Chains - strepto- (one-dimensional growth)
- Pairs - diplo- (unidirectional growth)
genomic similarity - Bacteria are classified together when strains share similar DNA sequences
Outline the rationale and importance of Gram staining
- Very quick diagnostic tool for bacterial infection
- Determining gram-stain of bacteria allows narrowing down of antibiotics in half. Certain antibiotics work on gram-positive and other on gram-negative
Outline the main features of Gram-positive staphylococcus aureus
- gram-positive aerobic clustered cocci
- Golden colour
- Virulence: Structural components, toxins, and enzymes
- Pathology: 1) Endocarditis: Fibrinogen on heart, 2) Toxic shock syndrome, 3) necrotic pneumonia (holes in lungs), 4) infection and necrosis of skin
- Epidemiology: colonizes nasal mucosa and skin, spread through direct contact or contaminated materials
- MRSA = Methicillin-resistant Staphylococcus aureus
Outline the main features of Gram-positive streptococcus pyogenes
- Gram-positive aerobic cocci in long chains
- Part of the normal flora in respiratory in respiratory, gastrointestinal and genital tracts
- Virulence: Toxins and enzymes
- Pathology: suppurative infection (i.e. to epidermis, dermis, and subcutaneous tissue), systemic infection, scarlet fever, post-streptococcal sequelae (acute glomerulonephritis, rheumatic fever)
- Epidemiology: colonizes in skin and upper respiratory tract, spread through direct contact, respiratory droplets, and contaminated material
Outline the main features of gram-positive streptococcus pneumoniae
- Gram-positive aerobic cocci in pairs
- Virulence: Capsule (prevents phagocytosis) and pneumolysin
- Pathology: pneumonia, meningitis, sinusitis
- Epidemiology: colonizes nasal mucosa and skin, spread through endogenous spread from colonized nasopharynx (person-person spread is rare)
Outline the main features of gram-positive bacillus anthracis
- Gram-positive aerobic bacilli in long chains
- Causes anthrax infection: “Anthrax” = black necrotic wound
- Spore forming bacteria
- Virulence: Edema toxin and capsule
Outline the main features of gram-positive mycobacterium tuberculosis
- Weakly gram-positive aerobic bacilli: complex lipid-rich wall with mycolic acid
- Acid-fast bacteria (AFB) stained by Ziehl-Neelsen (ZN) stain
- Difficult to culture (slow growing)
- Pathology: 1) intracellular growth in alveolar macrophages, 2) granulomas prevent further spread (latent infected), 3) symptomatic disease state may occur during life
- Epidemiology: 1/3 of world has TB, spread person-to-person by aerosol, Immunocompromised patients have higher risk of asymptomatic disease
Outline the main features of gram-positive listeria monocytogenes
- Gram-positive aerobic short rods
- Grown in high concentration of salt
- Virulence: Haemolysins and intracellular pathogen
- Pathology: Neonatal sepsis, meningitis, gastroenteritis
- Epidemiology: in soil and mammal GIT, Transmission via foodborne or vertical, eating contaminated milk, cheese, or raw vegetables.
Outline the main features of gram-positive clostridium botulinum
- Gram-positive anaerobic rods
- spore-forming
- In normal flora of GIT
- Virulence: Produces exotoxins and haemolytic enzymes
- Pathology: Blocks neurotransmitters in peripheral nerve endings (muscle weakness)
- Epidemiology: Food-borne
Explain how bacteria are named
Genus name is capitalized, and the species name is written in lower case, all in italics
Outline the main characteristic of gram-negative cocci: Neisseria (general)
- Gram-negative cocci pairs (i.e. diplococci)
- Flattened adjacent sides
- Capsule protects from phagocytosis
- Epidemiology: Neisseria species are commensal in nasopharynx of 10% of humans, Respiratory spread person-to-person
- Prevention: Vaccines, antibiotics
Outline the main characteristic of gram-negative cocci: Neisseria gonorrhoeae (gonococcus)
- Causes gonorrhoea (i.e. urethritis, epididymitis and pelvic inflammation)
Outline the main characteristic of gram-negative cocci: Neisseria meningitides (meningococcus)
- Causes pharyngitis, sepsis and meningitis
Outline the main characteristics of gram-negative rods (general)
- Many are part of normal flora of GIT
- Virulence: Surface antigens (O = outer membrane, H = flagella, K = capsule), adhesins, endotoxins
Outline the main characteristic of gram-negative rods: Escherichia coli
- Facultative anaerobic
- Pathology: Urinary infection, neonatal sepsis and meningitis, Intestinal infection -> Enterohaemorrhagic E. coli (EHEC) is most common: complicated by haemolytic uraemic syndrome (HUS)
Outline the main characteristics of gram-negative rods: Klebsiella
- Klebsiella pneumoniae is most common
- Facultative anaerobic
- Virulence: large polysaccharide capsule (mucoid colonies)
- Pathology: UTI, lobar pneumonia, liver abscesses, sepsis
- Epidemiology: antibiotic resistant
Outline the main characteristics of gram-negative rods: salmonella
- Intracellular pathogen
- Facultative anaerobic
- Pathology: non-typhoid salmonella - gastroenteritis in GIT mucosa, extra-intestinal infections; typhoid fever - caused by salmonella typhi, life-threatening systemic infection
- Epidemiology: foodborne/waterborne, human-to-human transmission via fecal-oral route, animal contact
Outline the main characteristics of gram-negative rods: shigella
- Facultative anaerobic
- Non-motile, non-lactose fermenting
- Virulence: shiga toxin damages intestinal and glomerular endothelium
- Pathology: necrosis in colonic epithelium, dysentery: frequent low-volume stools with blood, mucous, and pus and abdominal cramping
- Epidemiology: humans are the only reservoir, faecal-oral transmission, water and foodborne, infectious dose is low
Outline the main characteristics of gram-negative rods: bordetella
- Bordetella pertussis causes ‘whooping cough’
- Aerobic gram-negative rods
- Vaccine contains pertussis toxin and filamentous haemagluttin
- Epidemiology: humans are only reservoir, spread via respiratory droplets
Outline the main characteristics of gram-negative rods: legionella
- Aerobic gram-negative rods
- Grows between 20-45 degrees celsius in warm water sources
- Legionella pneumophila is the cause of Legionnaire’s disease
- Virulence: invades alveolar macrophages
- Pathology: pneumonia
- Epidemiology: contaminated water source; NO human-to-human transmission
Outline basic mechanisms of bacterial pathogenesis
- Acquire virulence genes
- pathogenic bacterial contain genes that are not present in related non-pathogenic bacteria
- Transformation: lysis of one cell releases DNA for other bacteria to integrate into own DNA
- Transduction: bacteriaophage (virus) develop capsule of bacteria DNA and inject into another bacterium for recombination
- Conjugation: A DNA plasmid moves between bacterial via a pilus (tube)
- Virulence can also arise due to gene loss - Switch virulence genes on:
- genes switch on in response to environment
- Quorum sensing - bacteria to know when there are enough bacteria to proliferate and survive within an infected host or also know if there are enough nutrients and space to grow. Switches ON virulence genes - Avoid immune system
- Hide in capsules, biofilms, or in phagocytes
- Mimic host cells
- immune evasion by changing antigens
- Escape phagocytosis via phagocyte recruitment suppression, reduction of vascular permeability, or phagocyte enzyme inhibition - Damage host tissues and spread through cells and organs
- Colonization, proliferation and invasion of tissues
List bacterial mobile genetic elements
Plasmids - Extra-chromosomal DNA that can be incorporated via recombination with the chromosomal DNA into the genome. Passed via pilus
Prophage - Non-lytic bacteriophages (virus) which incorporate host bacteria DNA into capsid, then inject DNA into another bacterium for recombination
Pathogenecity Island - segment of the chromosome which harbours clusters of virulence genes
Outline bacterial protection and attack strategies
Enzyme production:
- proteases help survival on mucosal surface
- Coagulases/collagenase damage tissue
- Hyaluronidase help spread
Toxin production
- Endotoxins - lipopolysaccharides from gram-negative bacteria
- Exotoxins - proteins from gram-positive and gram-negative bacteria
Outline some host factors that alter susceptibility to infection
Host factors include:
- immune status
- Age
- Genetics
- Nutrition
- Overall health
Define the term ‘virus’
Virus definition:
- Ultramicroscopic infectious agent that ONLY replicated within cells of living hosts
- obligate intracellular parasites = totally dependent upon host cells for replication (has no machinery)
- RNA or DNA wrapped in thin protein coat
- Virion - name for virus particle composed of nucleic acid, capsid and envelope (in some cases)
Outline the structure of a virus structure and the composition of the virus genome
Nucleic acid - genetic content is either DNA or RNA but not both:
- DNA viruses can have ssDNA or dsDNA
- RNA viruses can have dsRNA, positive sense ssRNA or negative sense ssRNA
Capsid - protein shell around nucleic acid
- capsomeres = viral protein subunits that make up capsid
- helical capsid - rod shaped shell
- icosahedral capsid - roughly spherical shell
- Complex capsid - neither helical or icosahedral
Envelope
- lipid bilayer membrane surrounding the capsid of some viruses
- derived from host cell membranes
- contain encoded proteins
- consequence: must remain in moist environment; very sensitive to environment (die in GIT)
- Non-enveloped virus can spread easier, infective after drying, and are much more resilient
List the steps in the virus multiplication cycle
- attachment - virus particle binds to the potential host cell via capsid/envelop to cell surface proteins
- penetration - movement of the virus across plasma membrane
- uncoating - loss of capsid proteins and release of nucleic acid (DNA/RNA)
- byosynthesis - synthesis of viral proteins and viral nucleic acid using host cell
- Assembly - association of viral structural proteins and nucleic acid form virions
- Release - accumulation within the host cell leads to exit of virus from the infected cell
For DNA viruses, DNA is synthesized in nucleus
For RNA viruses, RNA is synthesized in cytoplasm
List the effects of viruses on cells
- Cell-death - known as cytopathic effect (CPE); may induce apoptosis or necrosis
- Transformation - cell phenotype properties become cancer-like
- Latent infection - virus remains within cells with no obvious effects; may infect later with full effect
List important modes of virus transmission
- Respiratory and salivary transmission: aerosis, salivary spread
- Faecal-oral spread: person-to-person, fecal contaminated water/food
- vector-mediated transmission (through other animals and insects)
- sexual transmission
- blood-borne transmission
- vertical transmission (mother to baby)
Key requirements for successful viral infection
- viral entry
- immune response evasion
- dissemination/spread within host
- transmission to another host
