Shiv's Microbiology Y1 by ICSM SU

Microbiology 1: Bacterial Properties Main difference between Gram + and Gram – bacteria The vast majority of bacteria are harmless or beneficial Some bacteria are pathogenic including: •

Gram negative bacteria

•

Gram positive bacteria

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Mycobacteria (neither Gram negative nor Gram positive)

Gram negative bacteria

Diseases caused

EP: EP Escherichia coli

Diarrhoea

EHEC: EH Escherichia coli

Dysentery and kidney failure

Salmonella typhimurium

Self-limiting diseases: food poisoning and gastroenteritis

Salmonella typhi

Systemic diseases: typhoid

Shigella

Dysentery

Vibrio cholerae

Cholera

Neisseria meningitidis

Meningitis

Neisseria gonorrhoeae

Gonorrhoea

Gram positive bacteria

Diseases caused

Staphylococcus aureus

Skin diseases, endocarditis, bacteraemia, joint diseases and pneumonia

Streptococcus pneumoniae

Pneumonia, meningitis, otitis media

Streptococcus pyogenes

Tonsillitis, necrotising fasciitis, bacteraemia, scarlet fever

Mycobacteria

Diseases caused

Mycobacterium tuberculosis

Tuberculosis

Mycobacterium leprae

Leprosy

General characteristics of bacteria: •

Prokaryotic

•

Small (typical dimensions of a Gram negative bacterium: 2 μm × 0.5 μm)

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Unicellular

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Lack internal membrane-bound organelles (chloroplasts, nucleus, ER, mitochondria)

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Possess a bacterial chromosome: DNA is organised into a continuous circular loop

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May have plasmids: self-replicating circular loops of DNA

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Haploid: there is 1 copy of gene

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May have flagella: long filamentous structures assembled on the surface of a bacterial cell

Bacterial form

Examples

Cocci (spherical)

Streptococci and Staphylococcus

Bacilli (rod-shaped)

Most Gram negative bacteria: E. coli, Salmonella, Shigella

Spirilli (spiral-shaped)

n/a

Photosynthetic

Cyanobacteria

Gram stain: classifies bacteria according to differences in the structure of the cell wall •

Used to differentiate between Gram positive and Gram negative bacteria

•

Method: o

Stain with a violet dye (crystal violet) and iodine

Rinse in alcohol

Counterstain with a red dye (safranin)

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The stain binds to peptidoglycan (a peptide sugar polymer) in the bacterial cell wall

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Both Gram positive and Gram negative bacteria have peptidoglycan in their cell wall Gram positive bacteria 1 cell membrane

Structure

Thick peptidoglycan cell wall

Gram negative bacteria 2 cell membranes Thinner peptidoglycan cell wall

Peptidoglycan is accessible to the dye

Peptidoglycan is not accessible to the dye: it is present in the periplasmic space

Wash with alcohol

The crystal violet stain is retained

The crystal violet stain is removed

Counterstain

No effect on the stain

Cells are stained pink

Final result

Appear deep violet

Appear pink

Explanation

Peptidoglycan in the cell wall retains the dye

The outer membrane resists the dye

Examples

Lactobacillus, Bacillus, most cocci

E. coli, Salmonella, some cocci

Gram positive cell wall structure:

Gram negative cell wall structure:

Examples of intracellular and extracellular bacteria

Extracellular pathogens: infect the host without entering host cells Examples of extracellular pathogenic bacteria:

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Staphylococcus

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Streptococcus

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Yersinia

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Neisseria

Intracellular pathogens: 2 methods of entry into the host cell: 1. Engulfed by a phagocytic host cell 2. Directly invade a non-phagocytic host cell Inside the host cell: all intracellular pathogenic bacteria are enclosed in a membrane-bound vacuole which is derived from the plasma membrane of the host cell 3 modes of action inside the host cell: 1. Escape from the vacuole and into the cytoplasm E.g. Listeria and Shigella 2. Modify the vacuole and prevent it from interacting with lysosomes; therefore the host cell does not degrade the vacuole E.g. Salmonella and Mycobacteria 3. Remain within the vacuole which fuses with a lysosome to form a phagolysosome; the bacteria are able to resist the harsh conditions and replicate E.g. Coxiella

Flagella and type III secretion – 2 related bacterial multi-protein machines Salmonella: an example of motility and invasion 1. The bacteria are motile outside the epithelial cell 2. A bacterium comes into contact with the surface of epithelial cell 3. At point of contact: the bacteria send a signal to the host cell 4. This causes monomeric actin to polymerise into filaments in the vicinity of the bacterium 5. Polymerisation of actin causes ruffling of the plasma membrane of the host cell 6. This caps the bacterium and seals it into a vacuole 7. The bacterium enters the cell Motility and invasion require 2 related multi-protein machines: 1. Flagella: allow motility 2. Type III secretion systems: allow invasion Flagella and type III secretion systems are structurally similar but functionally distinct Flagella: long protein filaments which are assembled on the surface of a bacterial cell 1. Flagella extend out from 1 pole of the cell 2. Rotations of the flagella propel the bacterial cell 3. Rotations are driven by a motor in the bacterial cell Flagella assembly: flagella are self-assembled from the motor embedded in the inner membrane to the long filament 1. Protein monomers are introduced into the inner membrane of the bacterial cell

2. Protein monomers oligomerise: they bind to other protein subunits to form a multi-subunit ring-like structure 3. A channel-like structure is assembled within the ring Protein monomers are secreted through the channel, including: o

Filament proteins: make up the flagellum

Capping structures: regulate the assembly of filament proteins

4. The channel is assembled towards the outer membrane 5. Enzymatic activity breaks down the peptidoglycans cell wall and the channel pushes through the outer membrane 6. Another ring-like structure is formed in the outer membrane 7. A hook-like structure is assembled by capping proteins 8. The capping proteins fall off after completion of the hook Type III secretion systems: deliver virulence proteins into host cells •

Type III secretion systems have a similar structure to flagella present in some Gram negative bacterial pathogens Structural similarities include the presence of rings and channels

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The type III secretion system has a short needle-like structure at its tip

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The needle forms a pore in the plasma membrane of the eukaryotic host cell

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The bacterial cell injects bacterial proteins into the host cell via the needle

Bacterial effectors can mimic host cell proteins Bacteria have evolved mechanisms to mimic various host cell pathways in order to evade host cell defence mechanisms: •

Some bacterial proteins mimic the activity of eukaryotic proteins E.g. GEF and GAP: eukaryotic proteins which turn rho-dependent GTPases on and off respectively

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When Salmonella comes into contact with the host cell, it expresses a protein which mimics GEF: this activates actin polymerisation

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Actin polymerisation is only a transient process: it stops once Salmonella has entered the host cell

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Once Salmonella has entered the host cell, it expresses a protein which mimics GAP: this deactivates actin polymerisation

Genome diversity, horizontal transfer and evolution Genome diversity: •

Genomes of bacterial pathogens encode between 500 and 4500 proteins

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Genome sequencing of bacterial strains (e.g. strains of E. coli) shows that some genes are present in all strains; however other genes are unique to a particular strain

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As more strains are sequenced, more unique genes are found

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The gene repertoire of bacterial pathogens consists of core genes and accessory genes o

Core genes: always present in all strains of a bacterial pathogen

Accessory genes: unique to a particular strain of a bacterial pathogen

Horizontal transfer: Vertical transmission of DNA: daughter cells inherit DNA from the parent cell during replication •

Replication is asexual: it involves clonal, rapid, simple division

Horizontal transmission of DNA: bacterial cells acquire foreign DNA •

Variation arises through mutation and acquisition of foreign DNA by horizontal transfer

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The vast majority of accessory genes are acquired by horizontal transfer from unknown sources

3 mechanisms of horizontal gene transfer: 1. Transformation 2. Transduction 3. Conjugation Transformation: DNA uptake •

The bacterial cell takes up double-stranded DNA from the extracellular environment

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DNA is integrated into the bacterial chromosome by homologous recombination

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Neisseria and Streptococcus are subject to transformation

Transduction: •

The bacterial cell is infected by bacteriophages (viruses which infect bacteria)

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Bacteriophages replicate within the bacterial cell and cut up bacterial DNA

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Some bacterial DNA is incorporated into the viral genome in bacteriophage heads

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Newly assembled bacteriophages infect other bacterial cells and inject bacterial DNA into them

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Many Gram negative and Gram positive bacteria are subject to transduction since they are susceptible to bacteriophage infections

Conjugation: •

A hollow tube is assembled between 2 bacterial cells

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DNA can be transferred via the tube

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Many Gram negative and Gram positive bacteria are subject to conjugation

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It is a common method of transfer of antibiotic resistance since genes encoding antibiotic resistance are frequently found on plasmids

Conclusion: genetic diversity in the bacterial genome is huge since bacteria can acquire accessory genes from an unlimited gene pool in the biosphere by horizontal transfer Evolution: The old world view of biodiversity: •

Most biodiversity is present within Plantae, Fungi and Animalia

•

Some biodiversity is also present within Protista and Monera

Carl Woese established a method of sequencing small subunit rRNA (ssrRNA): •

Sequence alignments of ssrRNA allow quantitative comparisons among all extant organisms

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ssrRNA is conserved throughout the bacterial kingdom: all bacteria require ssrRNA

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The ssrRNA sequence varies between different bacteria

The new world view of biodiversity: •

Very little biodiversity is present within Plantae, Fungi and Animalia

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Most biodiversity is present within Bacteria, Archaea and Eukarya

In summary: •

There are many bacterial genomes

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All genomes are mixable by horizontal transfer and susceptible to mutation

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They grow with a very rapid generation time: e.g. Streptococcus pyogenes

Evolution of bacteria is caused by a combination of the following factors: •

There is an incredible source of genetic variation within the bacterial genome

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Bacteria have a very rapid generation time

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Selective pressures act on bacteria

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Time: approximately 1,000,000,000 years

Flagella and type III secretion systems are complex structures which have developed by evolution Listeria: another example of manipulation of actin by a bacterium •

It does not possess either a type III secretion system or a flagellum; therefore it exploits the host cell cytoskeleton for intracellular movement

•

It causes food poisoning and more serious diseases in the immunocompromised, the elderly and in pregnant women

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It is an intracellular bacterial pathogen which has the ability to invade host cells

Mechanism of Listeria movement within and between host cells: 1.

The bacterium is present inside a vacuole in the host cell

It breaks down the vacuolar membrane and escapes into the cytoplasm of the host cell

It reorganises and causes polymerisation of host cell actin filaments at 1 pole of the bacterial cell

Assembly of F-actin propels the bacterium through the cytoplasm

Once the bacterium comes into contact with the plasma membrane, it breaks through it and invades a neighbouring cell

Microbiology 2: Properties of Bacterial Pathogens Explain the concepts of infectivity and virulence and define the term infective dose Introduction and definitions: Only a minority of bacterial species are pathogenic: •

Obligate pathogens: can only replicate inside host cells

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Facultative pathogens: replicate in an environmental reservoir; only cause disease in a susceptible host

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Opportunistic pathogens: usually benign; may cause disease in an injured/immunocompromised host

Virulent pathogenic bacteria differ from closely related non-pathogenic bacteria by a very small number of genes •

Virulence genes: genes which contribute to the ability of an organism to cause disease

•

Virulence genes encode virulence factors o

Pathogenicity islands: sections of the bacterial chromosome which contain virulence genes

Virulence plasmids: sections of plasmids which contain virulence genes

Bacteriophages: may carry virulence genes

Complement: The complement cascade is activated by different pathways Complement activation kills pathogens by the following mechanisms: •

MAC complex: inserted into the plasma membrane causing lysis

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C3b: opsonises pathogens and facilitates phagocytosis by neutrophils and macrophages

Meningococcal infection is associated with deficiencies or polymorphisms in complement factors Molecular basis of virulence: •

Commensals: harmless organisms which are part of our normal flora

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Pathogens: organisms which cause disease

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Primary pathogens: cause disease in non-immunocompromised hosts

Opportunistic pathogens: cause disease in immunocompromised hosts

Virulence: the degree of damage that a pathogen can induce in its host; a quantitative measure A highly virulent strain causes a greater extent of damage to its host

•

Infective dose: the number of infectious organisms which are necessary to cause disease in a host

Context: •

1013 human cells in the human body

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1014 bacterial cells in the human body

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There are about 3000 bacterial species in the human body

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Only about 50 bacterial species cause disease in humans

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Some pathogens have an extremely low infective dose: e.g. 1-10 Shigella cause disease

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Inside the gut there is a large diversity of bacteria

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Pathogenic bacteria belong to the same part of the bacterial spectrum; they are closely related

Special attributes of pathogens which contribute to virulence: •

Tropism: pathogens must find a unique niche to settle in (either inside or outside cells)

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Replication: pathogens replicate by acquisition of nutrients

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Immune evasion: e.g. Streptococcus and Meningococcus are host-specific bacteria and must be able to evade the host immune system

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Toxic: pathogens elicit damage to the host by producing toxins, which are either secreted or are part of the outer membrane

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Transmission: pathogens are able to spread between hosts

The genetic constitution of bacteria makes them unique: they can acquire DNA from the environment by horizontal transfer The genome of pathogens often has extra regions of DNA which make them toxic Pathogenicity islands: clusters of genes which are required for pathogenesis; encode virulence factors List the potential sources and possible routes of infection by bacteria Potential routes of infection: Respiratory (aerosol spread): e.g. Meningococcus; Streptococcus Direct contact: primarily STDs and mucosal pathogens (e.g. Meningococcus) Faecal-oral spread Vector borne: e.g. malaria; Leishmania Give examples of extracellular bacterial pathogens transmitted by different routes and outline the ways in which they cause disease Vibrio cholerae: causes cholera John Snow investigated an outbreak of cholera: showed the relationship of the location of cases to a single water supply •

Gram negative bacillus

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Symptoms: sudden onset of profuse, watery diarrhoea (rice water stool)

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Rice water stool is produced by the secretion of intracellular contents of epithelial cells

Pathogenesis of cholera: •

Faecal-oral transmission (e.g. from contaminated water supplies)

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Colonisation of the small intestine: the bacteria adhere to the epithelium of the small intestine via the toxin co-regulated pilus

•

Replication

•

Production of toxins

Cholera structures: Toxin co-regulated pilus: required for the bacteria to bind to epithelial cells Flagella: required for extracellular movement of the bacteria to reach enterocytes Cholera toxin: a toxic protein which is secreted by Vibrio cholerae •

1A 5B toxin: composed of 1 A subunit coupled with 5 B subunits

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B subunits: bind to glycolipids in the plasma membrane of epithelial cells of the gut

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A subunit: an enzymatically active component which catalyses ADP-ribosylation of G proteins

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ADP-ribosylation: the transfer of an ADP-ribose moiety from NAD to a G protein

Mechanism of action of the 1A 5B cholera toxin: 1. The B subunits transfer the A subunit into the epithelial cell across the plasma membrane 2. A1 catalyses ADP-ribosylation of G proteins: this activates adenylate cyclase 3. Activated adenylate cyclase converts ATP  cyclic AMP 4. Therefore the cholera toxin causes an increase in the intracellular concentration of cyclic AMP 5. Cyclic AMP causes ion channels to open: this creates an ion imbalance, which leads to massive watery diarrhoea Normally sodium is absorbed from the lumen of the GI tract and it is retained within cells Presence of the cholera toxin causes chloride channels to open: chloride leaves epithelial cells; sodium is not absorbed; water follows chloride into the GI tract The cholera toxin is acquired by Vibrio cholerae via transduction: •

Virulence genes encoding the cholera toxin are carried by a bacteriophage

•

The bacteriophage infects non-pathogenic strains of Vibrio cholerae

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This produces pathogenic strains of Vibrio cholerae which produce toxins

Similar toxins which cause an increase in the intracellular concentration of cyclic AMP are produced by in Shigella, E. coli and Bordetella pertussis Shigella spp.: cause shigellosis (dysentery) •

Faecal-oral transmission

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Causes inflammation and bleeding of the mucosa of the distal colon

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Symptoms: severe diarrhoea containing blood and mucous

Clostridium difficile: causes mild to severe infections in the GI tract Features: •

Gram positive bacillus

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Resistant: forms terminal spores which are difficult to eradicate

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Spore formation enhances transmission of C. difficile

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Pathogenic strains are acquired exogenously from the hospital environment and from health care workers

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Opportunistic pathogen: causes C. difficile associated diarrhoea (CDAD): o

Diagnosis: observation of pseudomembranes at endoscopy or positive stool test

No other aetiology for diarrhoea

Antibiotic exposure in the last 6-8 weeks

Symptoms: •

Contact bleeding

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Hyperaemia

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Pus formation in pseudomembranes on the mucosa of the colon

Toxins: •

C. difficile produces 2 toxins: toxin A and toxin B

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Toxin A and toxin B are single-protein toxins (i.e. they act independently)

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Each toxin is composed of 3 functionally distinct domains: an enzyme domain (toxic), a translocation domain and a binding domain

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Toxin A (enterotoxin): enters cells at the apical region; damages the GI tract

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Toxin B (cytotoxin): enters cells at the basolateral region; damages cells

Mechanism of action of C. difficile toxins: 1. The toxin enters the cell into an endosome (a membrane-bound vacuole) via endocytosis 2. The enzyme domain is cleaved from the rest of the toxin molecule 3. The vacuole is acidified: this causes the enzyme domain to translocate into the cytoplasm 4. The toxin catalyses glycosylation of Rho GTPases in the cytoplasm: this inactivates Rho GTPases 5. This inhibits effector actions of Rho GTPases: e.g. cytokine production; ROS production

Neisseria meningitidis: causes meningitis •

Gram negative diplococcus

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Important cause of childhood mortality

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There are vaccines against N. meningitidis except for serogroup B

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Serogroup C vaccine: virtually eradicated meningitis C

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Meningitis B is the most prevalent form of meningitis in the UK

Progression of meningitis: 1.

Colonisation: asymptomatic; involves the sub-epithelial layer

Septicaemia: symptoms include fever, rash, cardiac depression and coagulation; may cause fatality

Spread to cerebrospinal fluid: symptoms include neck stiffness, photophobia and vomiting

Type four pili: required for adhesion to epithelial cells •

Bind to CD46 (complement regulatory protein)

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Host-specific: type four pili only bind to human cells

Complement is important in innate immunity; complement deficiency leads to an increase in disease Symptoms of meningococcal septicaemia are caused by: •

The bacteria avoid complement-mediated killing: this leads to high levels of bacteraemia

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Blebbing: bacteria shed components of the outer membrane, including lipopolysaccharides (LPS) LPS is an endotoxin: i.e. it is an integral component of the cell wall of Gram-negative bacteria

Mechanisms of avoiding complement-mediated killing: Capsule: •

Meningococcus coats itself in a polysaccharide capsule composed of sialic acid

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Sialic acid expressed on human cells protects them from complement recognition by recruitment of factor H

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Vaccines against Meningococcus target the capsule

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Meningococcus serogroup C: coated by a capsule composed of α2-9 linked sialic acid

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Meningococcus serogroup B: coated by a capsule composed of α2-8 linked sialic acid α2-8 linked sialic acid is identical to a self-antigen which is expressed on cells of the developing CNS

LPS: an integral component of the outer membrane of Meningococcus •

Part of the LPS molecule is identical to a self-antigen which is expressed on red blood cells

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LPS coats Meningococcus with α2-8 linked sialic acid which recruits factor H

Factor H: a complement factor which down-regulates complement •

Factor H is recruited by a protein expressed on the surface of Meningococcus

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The bacterial factor H binding protein mimics the factor H binding protein expressed on the surface of human cells

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Recruitment of factor H down-regulates complement and prevents recognition of Meningococcus

Replication strategies: involve the acquisition of iron from the host Levels of free iron in the body are low: free iron is highly toxic and can damage proteins and lipids Most iron is transported in storage proteins (e.g. transferrin, lactoferrin and myoglobin) Meningococcus removes iron from transferrin: 1.

Meningococcus expresses 2 transferrin binding proteins on its surface which engage transferrin

Iron is removed from transferrin

Iron is taken up by meningococcal cells by specialised transport mechanisms

Lecture summary: Bacterial pathogens have evolved specific mechanisms to interact with human hosts: •

Often encode extra DNA fragments

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Can subvert the immune system

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Secrete toxins (cholera toxin and clostridia toxin)

Examples of extracellular bacterial pathogens: •

Vibrio cholerae: cholera toxin causes ADP-ribosylation of G proteins

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Clostridium difficile: single-protein toxins cause glycosylation of Rho GTPases

•

Neisseria meningitidis: releases exotoxins (LPS)

Microbiology 3: Defence and Vaccination against Bacteria List the major non-immune host defence mechanisms and describe how they protect against infection Non-immune host defence mechanisms: •

Skin: a natural physical barrier to bacterial infection

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Low pH and antibacterial secretions: make the skin a difficult surface to colonise

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Routine application of soap and water: strengthen the defence provided by the skin

•

Mucosal surfaces: protected by mucous and ciliary clearance

Competition with commensal organisms: •

Bacteria constitute 60% of the Earth’s biomass

•

Most bacteria are harmless and often beneficial (commensals)

•

Commensal bacteria constitute ~1% of the body mass

List the main components of the innate immune response and the major antimicrobial mechanisms Innate immune response: •

Bacteria that penetrate the skin and mucosal barriers are met by the innate immune response

•

Complement system: punches holes into bacteria

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Neutrophils and macrophages: phagocytose bacteria and expose them to toxic radicals and hydrolytic enzymes

Adaptive immune response: •

Antibodies (produced by B cells): prevent adhesion; neutralise toxins; enhance complement-mediated killing and phagocytosis

•

T cells: enhance B cell responses; activate macrophages

•

Memory response: works better on re-exposure to the same pathogen

Vaccines stimulate both aspects of the immune response; they are primarily aimed at eliciting acquired immunity Innate immunity

Acquired immunity

Does not require exposure to the infectious agent

Requires exposure to the infectious agent/its antigens

Immediate

Takes time to develop

Mediated by monocytes and neutrophils

Mediated mainly by T and B cells

Initially an inflammatory reaction

Other cell types are involved: e.g. monocytes and dendritic cells

Humoral immunity

Cell mediated immunity

Directly mediated by antibodies

Mediated by T lymphocytes and NK cells

Antibodies are produced by B cells

Not primarily mediated by antibodies

Plasma B cells are the primary source of secreted

Other cell types indirectly play a role: e.g. macrophages

immunoglobulins

Explain how an adaptive immune response is involved in defence against major bacterial pathogens See above Describe how infectious agents avoid host defences Pathogenic bacteria have evolved strategies to avoid host defences: Strategy

Mechanism

Example

Thick cell wall

Mycobacterium tuberculosis

Capsule

Neisseria meningitidis

IgA protease

Streptococcus pneumoniae

Antigenic variation

Neisseria gonorrhoeae

Polysaccharide capsule

Neisseria meningitidis

Debilitate phagocytes

Yersinia pestis

Hide inside other cells

Chlamydia

Escape from phagosome

Listeria monocytogenes

Block phagosome maturation

Mycobacterium tuberculosis

Resist complement

Resist antibodies

Resist phagocytosis

Inhibit intracellular killing

Explain the difference between active and passive immunisation Active immunity: elicited in the host in response to an antigen Passive immunity: the acquisition of protection from another immune individual through the transfer of antibody or activated T cells Vaccines induce active immunity

Give examples of the different types of vaccine presently available and how they are used Current routine bacterial vaccination in the UK Time of immunisation

Immunisation(s)

Method of administration

Diphtheria Tetanus 2, 3 and 4 months old

Pertussis (whooping cough)

1 injection

Polio Hib (meningitis and pneumonia)

13 months old

Meningitis C

1 injection

Measles, mumps, rubella: MMR

1 injection

Diphtheria 3 years and 4 months to 5 years old

Tetanus Pertussis

1 injection

Polio

10 to 14 years old (sometimes neonatal)

MMR

1 injection

BCG

Skin test and 1 injection (if needed)

Diphtheria 13 to 18 years old

Tetanus

1 injection

Polio

DTP: diphtheria, tetanus, pertussis (whooping cough) •

Subunit vaccines

•

Antibodies neutralise toxins and block adhesion

Conjugate vaccines (carbohydrate): •

T cell recognition of protein carriers enhances B cell activation

•

Promotes efficient antibody response to the polysaccharide capsule

Live attenuated vaccines: •

BCG gives some protection against tuberculosis in children; it is ineffective against adult pulmonary disease

•

New vaccine strategies are based on genome information

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Very effective live attenuated vaccines are being developed for enteric pathogens (e.g. Salmonella typhi)

Microbiology 4: Fungal Infections Outline the main differences between fungi (eukaryotes) and bacteria (prokaryotes) Fungi: •

~200 species are human pathogens

•

Eukaryotic organisms: genetic material is organised into a membrane-bound nucleus

•

Perform extracellular digestion: secrete hydrolytic enzymes which break down biopolymers

•

Disperse over large distances because of spores; humans are constantly exposed to spores

•

Commensal organisms and skin colonisers are transmitted by contact

Summarise briefly the ecology and epidemiology of infectious fungi Fungal allergies: •

Inhalation of/contact with fungal spores may induce a wide range of allergic diseases E.g. rhinitis; dermatitis; asthma; allergic broncho-pulmonary aspergillosis (ABPA)

•

Allergic responses differ according to (a) the individual and (b) the species

E.g. upper respiratory disease (URD): •

Affects 115 million Americans

•

Symptoms: congestion; sneezing; itching; watery eyes; coughing; headache

•

Diagnosis: immunoCAP; specific IgE blood test (this in vitro quantitative assay measures allergenspecific IgE in human serum/plasma)

List the major groups of disease causing fungi and specify their growth forms 3 types of fungal infections: 1.

Allergies

Mycotoxicoses

Mycoses: superficial; cutaneous; systemic

Mycotoxicosis: a toxic reaction caused by ingestion/inhalation of a mycotoxin Mycotoxins: secondary metabolites of moulds which exert toxic effects on animals and humans •

Symptoms: breathing problems; dizziness; severe vomiting; diarrhoea; dehydration; hepatic and renal failure (6 days later)

•

Therapy: gastric lavage and charcoal; liver transplant

Mushrooms which have psychedelic properties include: Liberty Cap and Fly Agaric •

Symptoms: vomiting; nausea; stomach pains

•

Therapy: supportive; correction of hypoglycaemia and electrolyte imbalance

Mycoses: classified by the level of tissue affected •

Superficial

•

Cutaneous

•

Subcutaneous

•

Systemic (deep)

Define the terms superficial mycoses and deep mycoses, giving appropriate examples of each type of infection Superficial mycoses: superficial cosmetic fungal infections of the skin or hair shaft No living tissue is invaded and no cellular response is initiated from the host E.g. black piedra: caused by Piedraia hortae Cutaneous mycoses: caused by dermatophytes (aka keratinophilic fungi) Dermatophytes: produce extracellular enzymes (keratinases) which hydrolyse keratin Inflammation is caused by the host response to metabolic by-products Dermatophytoces/dermatomycoses are characterised by the part of the body affected: •

Tinea capitis: affects the head/neck

•

Tinea pedis: affects the feet (Athlete’s foot)

Tinea capitis: a superficial fungal infection of the skin of the scalp, eyebrows and eyelashes with a propensity for attacking hair shafts and follicles Subcutaneous mycoses: chronic localised infections of the skin and subcutaneous tissue following traumatic implantation of the aetiological agent Rare compared to superficial and cutaneous mycoses E.g. Sporotrichosis Systemic mycoses: Primary systemic mycoses: establish infection in a normal immunocompetent host (i.e. no breach of the host defence is required and an immunocompromised host is not required) •

E.g. Histoplasma capsulatum

Secondary systemic mycoses: require an immunocompromised host in order to establish infection •

E.g. Candida; Aspergillus

Pathogen: a microorganism capable of causing disease True pathogen: a microorganism capable of infecting and causing disease in apparently immunocompetent individuals Opportunistic pathogen: a usually harmless microorganism which becomes pathogenic under favourable conditions Endemic mycoses (true systemic mycoses): •

Caused by thermally dimorphic fungi which exist in natural surroundings, soil, bird and bat droppings

•

Geographically limited to Central and Southern America

•

Infection occurs by inhalation, pulmonary involvement and dissemination

Candida infections: •

Candida albicans is an opportunistic commensal: i.e. it colonises and invades the host tissues of immunocompromised individuals

•

In healthy individuals: it is found in the GI tract, the genitourinary tract and the skin

•

In immunocompromised individuals: it causes superficial, mucosal and systemic infections

The incidence of hospital-acquired fungal infections has risen in recent decades due to the development of more aggressive and invasive surgical techniques Pathogenic Candida species:

•

6/100 Candida species predominate as pathogens

•

They colonise humans: oral colonisation

Superficial Candida infections: •

Regions affected: mouth; throat; skin; scalp; vagina; fingers; nails; bronchi; lungs; GI tract

•

Usually occur due to impaired epithelial barrier functions

•

Occur in all age groups, most commonly in the newborn and elderly

•

Respond readily to treatment

Mucosal Candida infections: •

Infections are symptomatic

•

Occur in neonates and the elderly

•

In HIV patients: oropharyngeal, oesophageal and vulvovaginal regions are affected

•

Frequently seen

Systemic Candida infections: •

Not seen in normal healthy individuals

•

Risk factors include: chemotherapy; gut-related surgery; catheters

Mechanism of Candida virulence: 1.

Colonisation

Superficial infection

Deep-seated infection

Disseminated infection

Aspergillus infections: •

Infections are macroscopic

•

There are mitotic spores at the end of each hypha: these can spread easily

•

More difficult to diagnose and treat compared to Candida infections

•

Higher mortality than Candida infections

Diagnosis of fungal infections: 1.

Sample acquisition Skin; sputum; bronchoalveolar lavage; blood; vaginal swab/smear; spinal fluid; tissue biopsy

Microscopy: rapid and cheap Allows detection of distinct morphological features associated with a particular fungal species

Culture and identification: slow and prone to contamination Requires skilled sample collection Positive identification allows susceptibility testing

Non-culture methods: antibody- and antigen-based detection assays detect: glucan; mannan; enolase; proteinase Disadvantage: none of these techniques has been validated for widespread use in laboratories Describe briefly the main classes of antifungal agents

3 targets for antifungal therapy: 1.

Cell membrane: fungi primarily use ergosterol instead of cholesterol

DNA synthesis: some compounds may be selectively activated by fungi, arresting DNA synthesis

Cell wall: fungi have a cell wall, unlike mammalian cells

Cell membrane active antifungals: Mode of action: •

Inhibit synthesis of ergosterol in the fungal membrane

•

Act upon fungal cytochrome P450 enzymes

Classes: •

Polyene antibiotics: amphotericin B; nystatin)

•

Azole antifungals: ketoconazole; itraconazole; fluconazole; voriconazole; miconazole; clotrimazole

DNA/RNA synthesis: Pyrimidine analogues: flucytosine Cell wall active antifungals: The fungal cell wall is the primary target of antifungal therapy Major components of the fungal cell wall: glucans and chitin Mode of action: non-specific inhibition of ß-1,3 glucan synthase Echinocandins: caspofungin acetate (Cancidas) Case study: Sprotrichosis: a subcutaneous mycosis which occurs due to trauma •

Response time to fungal therapy is relatively slow

Microbiology 5: Antibiotic Resistance and Hospital Acquired Infection Definitions Antimicrobial: any substance which interferes with growth and reproduction of a microbe (bacteria, viruses and fungi) •

A broad category of substances which includes detergents, soaps and disinfectants

Antibacterial: any substance which can reduce or eliminate bacteria Antibiotic: a type of antimicrobial which is used as a medicine for humans and animals •

Originally: referred to naturally occurring compounds

•

Now: refers to either synthetic derivatives of naturally occurring compounds or to purely synthetic compounds

Nosocomial infections: hospital acquired infections which occur after 48 hours of admission The scale/impact of the problem and its underlying causes 1940-1970s: the golden era of antibiotic discovery •

Penicillin: the first widely used antibiotic

•

Cephalosporins: synthetic analogues of penicillin (i.e. they have the same structure as penicillin but possess different side chains)

Misconceptions regarding bacteria: •

Bacteria are unlikely to become resistant to more than 1 class of antibiotics

•

Bacteria cannot exchange genetic material (i.e. horizontal gene transfer is not possible)

•

Resistant bacteria are less fit

Evolution of resistance in bacteria: •

Antimicrobial-resistant strains of Staphylococcus aureus have evolved including: o

Penicillinase-producing Staphylococcus aureus: resistant to penicillin

Methicillin-resistant Staphylococcus aureus (MRSA): a significant cause of bacteraemia

•

Resistance in Staphylococcus aureus is due to the spread of 2 virulent strains which are resistant: EMRSA-15 and EMRSA-16

•

E. coli is developing increasing resistance to ciprofloxacin

Infection with resistant organisms is associated with: •

Increased mortality

•

Increased duration of hospital stays

•

Increased costs

Reasons for resistance Resistance is emerging in bacteria due to the following factors: •

Normal flora: composed of many bacterial cells

•

Organic biomass: there is significantly more bacterial biomass than plant organic biomass There are many environmental bacterial reservoirs, including oceans and deep sea vents

•

Mutation rates are very high because generation times are low

•

There is a huge amount of genetic diversity which may contain resistance elements

•

Horizontal transfer of genetic material: occurs by conjugation, transformation and transduction

•

There is significant production and release of antibiotics into the environment: 90-180 million kg of antibiotics are used per year The predominant use of antibiotics is in the agricultural industry to increase meat yield

Reasons for the high rate of hospital acquired infections Hospitals are a potent source of infection as a result of: •

Intervention methods including: o

Lines: intravenous; central; arterial; CVP/pulmonary artery

Catheterisation

Intubation

•

Chemotherapy: this may reduce the innate immune response by causing reduced neutrophil and macrophage function

•

Prophylactic usage of antibiotics: this may eliminate normal flora (i.e. commensals)

•

Inappropriate prescription of antibiotics

•

Prosthetic material in patients: e.g. joints and pacemakers Bacteria present on abiotic surfaces are highly resistant to antimicrobial treatment

•

Dissemination due to vectors: e.g. hospital care workers, stethoscopes and computer terminals

•

Concentration of bacteria: e.g. in multi-bed wards and in ICUs

Mechanism of action of some important classes of antibiotics Selective toxicity: antibiotics must be selectively toxic to bacteria in order to limit damage done to eukaryotic host cells Targets and mechanisms of antibiotic action: 1.

Cell wall components: antibiotics inhibit cell wall synthesis Presence of a peptidoglycan cell wall in bacteria differentiates them from eukaryotic cells E.g. penicillins (cephalosporins) and glycopeptides (vancomycin) Bactericidal: kill bacteria

Protein synthesis: antibiotics target ribosomes and inhibit protein synthesis Bacteria have 70S ribosomes (30S + 40S); eukaryotic cells have 80S ribosomes (40S + 60S) E.g. aminoglycosides (streptomycin) and tetracyclines Bacteriostatic: inhibit replication of bacteria

Metabolic targets: antibiotics inhibit nucleotide synthesis There are sufficient differences in nucleotide synthesis between bacteria and eukaryotic cells E.g. sulphonamides and trimethoprim

Nucleic acid synthesis: antibiotics inhibit nucleic acid synthesis Rifampicin: inhibits RNA synthesis (anti-tuberculosis) Quinolones and fluoroquinolones (e.g. ciprofloxacin): inhibit DNA gyrase (urinary tract infections)

Other targets: metronidazole treats infections caused by anaerobic bacteria The nitro group of metronidazole is chemically reduced by ferredoxin Ferredoxin is only present in anaerobic bacteria; therefore metronidazole is non-toxic to eukaryotic cells

Mechanism of antibiotic action Inhibition of cell wall synthesis

Inhibition of protein synthesis

Metabolic targets (inhibition of nucleotide synthesis)

Antibiotic families Penicillins (cephalosporins) Glycopeptides (vancomycin) Aminoglycosides (streptomycin) Tetracyclines Sulphonamides Trimethoprim

Inhibition of RNA synthesis

Rifampicin

Inhibition of DNA synthesis

Quinolones and fluoroquinolones (ciprofloxacin)

Other

Metronidazole

Mechanisms of antibiotic resistance General mechanism of antibiotic action: 1.

The antibiotic is taken up into the bacterial cell

It binds to its target

It inhibits its target

The bacterial cell dies

Bacteria have evolved mechanisms of antibiotic resistance: 1.

Decreased influx: the antibiotic is not taken up into bacteria

Increased efflux: bacteria have specific membrane pumps which pump out the antibiotic E.g. tetracycline resistance

Drug inactivation: bacteria produce enzymes which cleave the antibiotic, inactivating it E.g. penicillin resistance (penicillinases are produced which cleave penicillin)

Target modification: the target site is modified so that the antibiotic can no longer bind to it E.g. quinolone resistance and penicillin resistance (the structure of the penicillin binding protein is modified)

Target amplification: target site production is increased so that it outcompetes the antibiotic E.g. sulphonamide resistance

Mechanisms of passing on antibiotic resistance: Integrons: genetic structures which act as shopping trolleys for Ab R cassettes •

Integrons have 3 elements: a promoter, a single AbR cassette and a recombination site

•

AbR cassette 2 from another integron is integrated into the bacterial genome at the recombination site of the original integron

Plasmids: circular, extrachromosomal DNA which are capable of independent replication •

Plasmids often carry multiple AbR cassettes

•

They are transferred between different bacterial strains by transformation or conjugation

•

Bacterial cells contain many copies of a plasmid

Development of antibiotic resistance in Neisseria gonorrhoeae: Neisseria gonorrhoeae has developed multiple antibiotic resistance mechanisms to various antibiotics Antibiotic

Resistance mechanism

Mechanism of transfer

Penicillinase production (drug inactivation)

Plasmid transformation

Target modification

Point mutation

Tetracycline

Efflux pump (increased efflux)

Plasmid conjugation

Quinolone

Target modification

Point mutation

Penicillin

Some of the approaches to prevent the emergence of drug-resistant bacteria and nosocomial infections Strategies for the preventing the spread of resistance: •

Hygiene

•

Monitor lines and change lines regularly

•

Single rooms

•

Screen high risk patients

•

Discharge patients as soon as possible

•

Avoid unnecessary prescription of antibiotics

•

Know local sensitivities

•

Always prescribe narrow spectrum antibiotics rather than broad spectrum antibiotics

•

Directly observed therapy (DOTS): completion of the antibiotic course

•

Use drug combinations

•

Antibiotic policies

•

Develop new drugs

Lecture summary: •

Antibiotic resistance is increasing: this is a major problem as it costs lives and money

•

Hospitals are an important focus for spread of infection

•

New antibiotics are needed

Microbiology 6: Viral Properties Describe the nature of viruses: their small size, mode of replication and diversity Properties of viruses: •

Size: 20-450 nm

•

Obligate intracellular parasites: i.e. viruses are dependent upon a host cell for replication; viruses are inert outside a host cell

•

Structure: nucleic acid and protein; lipid and carbohydrate may be present

•

Unique mode of replication (different to all other organisms)

•

Diversity: o

Viruses infect all species and contribute to evolution

Viruses may cause great plagues or be asymptomatic

Virus classification: the poxvirus family Family

Poxviridae

Subfamily

Chordopoxvirinae

Genus

Orthopoxvirus

Species

Vaccinia virus

Strain

Lister

Other parameters used for classification include: •

Type of disease caused: e.g. pox diseases, such as chickenpox and smallpox

•

Mode of transmission: e.g. arthropod born (arbo) viruses are transmitted by biting insects

•

Structure: viruses with common structures are likely to belong to the same family

•

Immunological relatedness: viruses which are immunologically related are likely to belong to the same family

•

Nucleic acid sequence: viruses which have a common nucleic acid sequence are likely to belong to the same family

•

Mode of replication (Baltimore classification): viruses with a common mode of replication are likely to belong to the same family

Virus structure: Nucleic acid: constitutes the viral genome •

DNA or RNA

•

Linear or circular

•

Monopartite (i.e. a single segment) or segmented (i.e. multiple segments)

•

Double-stranded (ds) or single-stranded (ss)

•

Polarity of single-stranded nucleic acids: either + or − o

+ polarity: the nucleic acid has the same sense as mRNA

o •

− polarity: the nucleic acid has the complementary sense to mRNA

Size range: 3-1200 kb

Nucleocapsid: composed of viral proteins •

Helical or icosahedral (an icosahedron is a 20-faced polygon)

•

Surrounds and protects the viral nucleic acid, especially while the virus is in transit

Lipid envelope: may be present •

Derived from the host cell

•

Fragile: destroyed by organic solvents

•

May contain embedded proteins which allow the virus to bind to the host cell

Examples of virus structure: Virus

Helical/icosahedral

Envelope

Tobacco mosaic virus (TMV)

Helical

−

Polio

Icosahedral

−

Influenza

Helical

Herpes simplex virus (HSV)

Icosahedral

Examples of viral nucleic acid: Virus

Size (kb)

DNA/RNA

ss or ds

Segments

Polio

7.5

RNA

ss +

Measles

15.9

RNA

ss −

Influenza

13.6

RNA

ss −

HIV

RNA*

ss +

1 (diploid)

HSV

152

DNA

HBV

3.2

DNA*

Circular

*HIV and HBV are retroviruses and carry reverse transcriptase HIV: packages RNA •

Reverse transcriptase converts RNA  DNA which is integrated into the host cell genome

HBV: packages DNA •

Reverse transcriptase converts DNA  RNA  DNA

Methods of measuring viruses: •

Observation of disease symptoms in the host

•

Plaque assay: measures the number of infectious virus particles (i.e. the viral titre)

•

Electron microscopy: measures the total number of virus particles; analyses viral structure

•

Polymerase chain reaction: amplifies the viral genome and measure the total number of viral genomes present

•

Immunological evidence of infection: serological evidence of infection is provided by a blood sample

Plaque assay: measures the viral titre 1.

Make a series of dilutions of virus particles

Place the dilution on a culture of host cells

The virus infects host cells and replicates

Virus particles are released by host cell lysis and infect new host cells

The virus destroys an area of host cells and forms a plaque (i.e. an area of dead cells)

The area of the plaque and the dilution factor can be used to calculate the viral titre

Viral titres are expressed as plaque forming units per mℓ Not all viruses can be titrated by plaque assay since they cannot be cultured: e.g. HBV Virus replication: One step growth curve:

•

Latent period: time taken from the point of infection until the first virus particles are produced

•

Eclipse phase: no virus is present; components of new virus particles are being synthesised

•

Mean burst size: the average increase in viral titre from infection to burst A mean burst size of 50 implies that 50 new virus particles are produced on average per host cell T4 bacteriophage

HSV

Host cell

E. coli

Human fibroblasts

Latent period

20 minutes

10 hours

Mean burst size

Mechanism of virus replication: 1.

Binding to host cell: this is often highly specific since host cells express specific surface receptors

Penetration: e.g. enveloped viruses fuse with the host cell membrane

Eclipse phase: expression of virus proteins and replication of viral nucleic acid; highly regulated Temporal control: enzymes are synthesised before structural proteins Quantitative control: enzymes are produced in lower concentrations than structural proteins

Assembly: production of new infectious virus particles; spontaneous

Release: virus particles are released either by cell lysis or by budding Cell lysis: all virus particles are released from the cell Budding: virus particles continuously bud out of the cell over a long period causing a persistent infection

Binding: occurs via a specific interaction between viral surface proteins and receptors expressed on the surface of the host cell Virus

Viral surface protein

Receptor

HIV

gp120

CD4

Epstein-Barr virus (EBV)

gp340

CD21

Influenza

Haemagglutinin (HA)

Sialic acid

Penetration: Enveloped viruses: enter the host cell by fusion between the virus envelope and host cell membrane Examples: •

HIV and measles: fuse at the cell surface with the plasma membrane (able to fuse at neutral pH)

•

Influenza: fuses with acidified intracellular vesicles (requires a low pH for fusion)

Influenza entry: 1.

Binding to sialic acid

Endocytosis of the virus into an endosome

Acidification of the endosome: this causes conformational changes in HA

Fusion between the virus envelope and the cell membrane (of the endosome)

Release of RNA into the cytosol

Non-enveloped viruses: cause disruption of the integrity of the host cell membrane; the viral genome or core enters the cytosol Examples:

•

Polio virus

•

T4 in E. coli

Eclipse phase: 1.

Disassembly of virus particles: no infectious virus particles are present

Expression of viral proteins: this is highly regulated- temporal and quantitative control

Replication of viral nucleic acid

Assembly: viral proteins and nucleic acids are assembled to form new infectious virus particles Release: Release may be… •

Spontaneous: e.g. tobacco mosaic virus (TMV)

•

Over a long period

•

Complex with multiple stages: e.g. vaccinia virus (the smallpox vaccine)

Release may occur at the cell surface or internally Budding: lytic infections e.g. HIV •

Viral envelope glycoproteins are inserted into specific areas of the host cell plasma membrane

•

Newly synthesised virus particles are attracted to these areas

•

The plasma membrane forms buds around the virus particles and the buds pinch off the cell

Latency: latent infections e.g. HSV; varicella zoster virus (VZV) •

After lytic infection viruses enter host cells (neurones) and may remain dormant

•

The viral genome is maintained as circular DNA (episomes) in the nucleus of host cells

•

The viral genome may reactivate many years later to cause recurrent infections: o

HSV causes cold sores

VZV causes shingles

Examples of virus replication HIV, polio, influenza, herpes simplex virus Baltimore classification of viruses: viruses are grouped according to their replication strategy Virus

Replication strategy

Examples

ss − RNA

Encode a virus RNA-dependent RNA polymerase: RNA  mRNA

Orthomyxo; paramyxo; rhabdo

ds RNA

Encode a virus RNA-dependent RNA polymerase: RNA  mRNA

Reo; rota

RNA is directly translated since it is the same sense as mRNA

Picorna; alpha; flavi; corona

Encode reverse transcriptase: RNA  ds DNA  mRNA

Retro

ss DNA

DNA  ds DNA  mRNA

Parvo

ds DNA

ds DNA  mRNA

Pox; adeno; herpes; papilloma

ss + RNA

Polio virus: Properties: •

Size: 20 nm

•

ss + RNA genome

•

Icosahedral capsid

•

Very stable to acid pH and proteases

Replication: ss + RNA  ss − RNA  mRNA Genome replication occurs via a complementary RNA intermediate 1.

mRNA is translated into a single giant polyprotein

The polyprotein is cleaved into mature individual proteins by proteolytic enzymes

Influenza virus: Properties: •

Segmented ss − RNA genome (8 segments)

•

Helical capsid

•

Enveloped

Replication: ss − RNA  mRNA and cRNA 1.

The genome is transcribed into mRNA and cRNA by virus RNA-dependent RNA polymerases

mRNA is translated into virus proteins

cRNA is converted into virus RNA (vRNA): this is viral nucleic acid

HIV: Properties: •

Retrovirus: HIV replicates via reverse transcription

•

Size: 110 nm

•

Diploid ss + RNA genome

•

Enveloped

•

The genome encodes: o

Functional proteins: gag, pol and env

Regulatory proteins: tat and rev

Replication: ss + RNA  ds DNA  mRNA 1.

The RNA genome is transcribed into ds DNA by reverse transcriptase

DNA integrates into the host cell DNA to form a provirus and may remain dormant Provirus: a virus genome in the form of DNA which has integrated itself into the DNA of a host cell This allows vertical transmission of the virus when host cells replicate

DNA is expressed by host RNA polymerase II to produce HIV mRNA; this is regulated by splicing

Herpes simplex virus: Properties: •

Size: 130 nm

•

Linear ds DNA

•

Icosahedral capsid

•

Enveloped

•

HSV infection occurs via skin abrasions

•

It may replicate via a lytic cycle or it may become latent

•

HSV-1 causes cold sores

•

HSV-2 causes genital herpes

Lytic replication: HSV replicates in the nucleus and undergoes a cascade of gene expression 1.

IE (initial early)/α genes are expressed

DE (delayed early)/ß genes are expressed

Late/γ proteins genes are expressed

N.B. Expression of each class requires prior expression of genes of the previous class Functions of proteins: •

IE proteins: regulatory function

•

DE proteins: replicative function (e.g. DNA polymerase)

•

Late proteins: structural function

Define the following terms as used in the description and classification of viruses: DNA virus, RNA virus, capsid type, enveloped, non-enveloped

Microbiology 7: Viral Disease How are viruses transmitted? Virus transmission occurs by: gaining entry, replication and dissemination to new hosts The host is hostile: •

•

Non-specific defences: o

Skin: forms an impervious barrier; viruses can only enter via breaks in the skin

Mucous membranes: swept by cilia and mucous secretions

Stomach: acidic pH and proteases form a hostile environment

Innate immunity: o

Complement

NK cells

Phagocytes

Interferons

Fever

Inflammation

Apoptosis: may not allow the virus to complete its replication cycle

Adaptive immunity: specific for viral proteins and virus infected cells o

Antibodies

Cytotoxic T cells

Factors affecting virus transmission: •

Particle stability: o

Presence of a lipid envelope affects particle stability: enveloped viruses are less stable The lipid envelope is fragile: if it is destroyed, viral proteins are removed and infectivity is destroyed

Viruses are usually spread by close contact: e.g. influenza virus in winter In winter we are indoors and closer together; therefore this helps influenza transmission

o •

•

Some viruses are able to spread over long distances: e.g. foot and mouth disease virus

Duration of virus shedding: o

Short duration viruses cause acute infections and require higher viral titres: e.g. rhinoviruses and influenza

Long duration viruses cause chronic infections and require lower viral titres: e.g. HSV-1

Virus concentration: o

Viruses causing acute infections tend to be released in higher concentrations

E.g. rotaviruses may be shed at 1010 pfu/ml

Availability of new hosts: o

Population size: e.g. measles virus may cause epidemics in isolated communities There must be a sufficient number of hosts to continue transmission of measles

Availability of animal reservoirs: e.g. yellow fever virus (YFV) YFV is transmitted between biting mosquitoes and humans (urban cycle) YFV is also transmitted between biting mosquitoes and monkeys (jungle cycle)

Entry routes: •

Respiratory tract: influenza; mumps; measles; variola; varicella-zoster virus; rhinovirus

•

Skin: papilloma viruses; HSV-1 and HSV-2; rabies (bites); yellow fever virus (biting mosquitoes)

•

Blood products: HIV; HBV; HCV

•

Genital tract: HIV; HSV-2; HPV 16 and HPV 18

•

Alimentary canal: polio virus; Hepatitis A virus (HAV); rotavirus

Outcome of infection: cell death, persistent infection, cell transformation / cancer Factors which influence outcome of infection: •

Virus dose

•

Route of entry: e.g. smallpox causes variolation by an unusual route (via the skin)

•

Age, sex and physiological state of the host: o

HBV: neonatal infection results in a greater chance of establishing chronic infection Males have a greater chance of developing Hepatitis B

Epstein-Barr virus (EBV): children are asymptomatic; young adults develop glandular fever

VZV: symptoms of chickenpox are more severe in adults than in children

Outcomes of infection: •

Cell death

•

Persistent (i.e. latent) infection

•

Cell transformation and cancer

•

Local or systemic infection

Cell death Virus

Cell type affected

Disease caused

Poliovirus

Motor neurones

Paralysis

Rotavirus

Gut epithelium

Diarrhoea

HIV

CD4+ T lymphocytes (T helper cells)

Immunodeficiency

HBV

Hepatocytes

Hepatitis

Rabies virus

Perkinji cells in the cerebellum

Hydrophobia

Virus

Cell type affected

Disease caused

HBV

Hepatocytes

Hepatitis

Persistent infection

Measles

Neurones

Subacute schlerosing panencephalitis

HSV-1 and HSV-2

Neurones

Cold sores; genital herpes

VZV

Neurones

Chickenpox; shingles

Virus

Cell type affected

Disease caused

HBV

Hepatocytes

Hepatocellular carcinoma

HPV 6 and HPV 11

Epithelial cells

Common warts (benign)

HPV 16 and HPV 18

Epithelial cells

Cervical/penile carcinoma

EBV

B cells

Burkitt’s lymphoma; nasopharyngeal carcinoma

Cell transformation and cancer

Local infections: •

Replication only occurs locally

•

Shorter incubation period (i.e. the period between infection and appearance of symptoms)

•

E.g. rhinovirus; rotavirus; influenza; HPV 6 and HPV 11

Systemic infections: •

Replication proceeds through multiple phases

•

Longer incubation period

•

Infection may disseminate via the bloodstream or the nerves

•

Infection is more severe

•

Clearance of infection is more dependent on cellular immunity (esp. CTLs)

•

E.g. VZV; variola virus; measles

Give examples of different viruses associated with infectious disease in humans and describe the way in which they cause disease Virus release From

Virus

Blood

YFV; HBV; HCV; HIV

Skin

HPV; VZV; measles; variola

Gut

Polio virus; rotavirus; HAV

Respiratory system

Rhinovirus; influenza virus; VZV; measles; variola

Saliva

EBV; rabies virus; mumps

Semen

HIV; HBV

Breast milk

HCMV

Placenta

Rubella; HCMV

Influenza virus antigenic shift and drift Influenza virus causes new epidemics It does this by undergoing antigenic variation to produce new strains which evade existing immunity Existing immunity is of limited value against new strains Methods of antigenic variation: •

Antigenic drift

•

Antigenic shift

Influenza viruses from avian species infect humans and may acquire human-human transmission Components of influenza virus: •

Lipid envelope: contains embedded glycoproteins o

Haemagglutinin (HA): important in causing influenza epidemics and pandemics

Neuraminidase (NA)

•

M2: ion channel

•

Matrix protein

•

Nucleoprotein

•

Polymerase: PB1, PB2 and PA

•

RNA genome

Haemagglutinin (HA): •

Structure: trimer

•

Each monomer consists of 2 polypeptides: HA1 and HA2 o

HA1: globular head

HA2: stalk

•

HA binds to sialic acid (a cell surface receptor) via the sialic acid binding pocket at the top of HA

•

Antibodies bind to HA and sterically block its ability to bind to cells: this prevents infection

•

HA2: contains a fusogenic peptide buried internally in HA

Fusogenic peptide: necessary to induce fusion between the virus envelope and the host cell membrane Influenza entry: 6.

Binding: HA binds to sialic acid

Endocytosis of the virus into an endosome

Acidification of the endosome: this causes conformational changes in HA

Fusion between the viral envelope and the host cell membrane (of the endosome)

10. Release of RNA into the cytosol Conformational changes: caused by the low pH a.

The fusogenic peptide is transferred to the top of HA where it can engage with the host cell membrane and induce fusion

Alpha helices at the bottom of HA are rearranged so that the membrane anchor is moved to the top of HA; therefore the virus envelope and host cell membrane are moved closer together

Antigenic drift: •

Involves the H3 HA

•

Amino acid mutations occur in HA and accumulate with time

•

There is continual change in HA which is mediated by antibodies: new HA variants which escape existing antibodies are selected

•

It is a less dramatic change than antigenic shift

Antigenic shift: •

The genome of each influenza particle is segmented: it consists of 8 RNA segments

•

The segmented genome is crucial for the ability of the virus to cause antigenic shift

•

If a cell is simultaneously infected by human influenza virus and avian influenza virus: the viral RNAs of both strains travel to the nucleus and replicate simultaneously

•

Reassortment of genetic material occurs during the RNA replication of both strains

•

New virus strains may acquire genetic material from both parental strains

•

Danger: if the new strain acquires the avian influenza gene encoding HA, this may cause a pandemic since existing human antibodies are completely ineffective avian HA E.g. the 1918 H1N1 pandemic killed 40 million people with a mortality rate of 2.5%

Birds (i.e. avian species) are natural hosts for influenza viruses: •

16 different HA subtypes: H1-H16

•

9 different NA subtypes: N1-N9

•

All HA and NA subtypes are present in avian species

•

Only 3 HA subtypes (H1-H3) and 3 NA subtypes (N1, N2 and N8) are present in man

•

Reassortment of HA and NA genes has the potential to produce a large variety of influenza strains

•

Avian influenza viruses may be transmitted to other species, including humans

H5N1 influenza: •

H5N1 influenza viruses are endemic in avian species; they are spread globally by migratory birds

•

H5N1 is transmitted to other birds: e.g. in the poultry industry, the density of birds is high, which leads to high virus concentrations

•

H5N1 has transmitted from birds to man (initially in S and SE Asia; now elsewhere)

•

H5N1 has a very high mortality rate in man (63%)

•

Human-human transmission has not developed yet… but there is a serious threat of this if the virus adapts

Mechanisms by which H5N1 may adapt to man: •

Better binding to human cells

•

Better replication in human cells

•

Better evasion of human innate immunity

•

Better transmission between humans

N.B. adaptation may be multi-factorial

Binding to host cells: •

•

Sialic acid is present on the surface of both human and avian cells, but with different linkages: o

Avian cells have α-2,3 sialic acid

Human cells have α-2,6 sialic acid

HA binds to sialic acid on the surface of the host cell: o

HA from avian influenza viruses binds to α-2,3 linkages

HA from human influenza viruses binds to α-2,6 linkages

•

The sialic acid binding pocket on the surface of HA has a complementary fit to sialic acid

•

Surrounding amino acid residues may induce this complementary fit o

Amino acid residues 226 and 228 influence the ability of HA to bind to sialic acid

Therefore it these residues are altered, this will alter the HA binding specificity

Replication efficiency in host cells: •

•

Avian influenza and human influenza have different amino acids at amino acid residue 627 of PB2 o

Avian influenza virus: glutamic acid; replicates well in avian cells but poorly in human cells

Human influenza virus: lysine; replicates well in both human and avian cells

Experimental change (E627K): glutamic acid is changed to lysine at amino acid residue 627 of PB2 o

This allows better replication of avian influenza in human cells

Avian influenza strains that have adapted to man have lysine at amino acid residue 627

Resistance to host innate immunity: •

NS1 (non-structural protein 1): confers resistance to interferon-mediated inhibition of influenza replication

•

Avian NS1: resistant to avian interferon but less resistant to human interferon

•

Changes in avian NS1 may increase the resistance of avian influenza virus to human interferon and hence increase its virulence in man

Anti-influenza virus drugs: Amantidine and rimantidine: Mechanism of drug action: inhibition of influenza virus by raising the pH of endosomes •

Low pH of endosomes is critical for the conformational changes in HA which induce fusion of the viral envelope and host cell membrane

•

Therefore if the pH of endosomes is increased, HA does not undergo conformational changes to enable fusion

Disadvantage: drug-resistance mutations arise quickly; therefore these drugs are of limited clinical use Relenza and tamiflu: Mechanism of drug action: inhibition of the viral neuraminidase (NA) NA: an enzyme which removes sialic acid from the cell surface •

It prevents budding influenza particles from sticking to the host cell surface and aggregating

•

Therefore if the viral NA is inhibited, influenza dissemination is inhibited

The DOH has purchased stocks of tamiflu

HIV life cycle and epidemic The HIV epidemic: Los Angeles: there was an unusual cluster of opportunistic infections in young men, including: pneumocystis carinii; disseminated cytomegalovirus; mucosal candida; chronic HSV infection •

Patients had T lymphocyte dysfunction

•

Initial patients: homosexuals; intravenous drug users

Disease spread to haemophiliacs, blood transfusion recipients and sexual partners of individuals at risk Human immunodeficiency virus (HIV) was isolated and identified as the cause of AIDS More than 95% of AIDS is in LEDCs There is no vaccine, no cure once infected and without drugs, death is the inevitable outcome Retrovirus: •

Enveloped virus

•

RNA genome

•

Replicate via a DNA intermediate: RNA  ds DNA  mRNA

•

Possess reverse transcriptase and integrase: o

Reverse transcriptase converts RNA into DNA

Integrase: integrates DNA into the host cell genome

HIV structure: •

Core: contains 2 copies of RNA

•

The core is surrounded by a capsid, which is in turn surrounded by a lipid envelope

•

p24: viral protein which constitutes the capsid

•

gp120 and gp41: viral envelope glycoproteins which are embedded in the envelope These proteins are analogous to HA in influenza

HIV genome: •

Diploid ss + RNA

•

Lentivirus: subgroup of retroviruses which have more complex genomes, which contain extra regulatory genes (in addition to 3 common genes possessed by all retroviruses)

•

Genes which are common to all retroviruses: encode structural proteins o

gag (group-specific antigen): encodes viral capsid proteins (i.e. p24)

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pol (polymerase): encodes viral enzymes (i.e. reverse transcriptase and integrase)

env (envelope): encodes viral envelope proteins (i.e. gp120 and gp41)

Regulatory genes: expressed by differential splicing o

Differential splicing: primary mRNA transcript  smaller mRNAs  small regulatory proteins

HIV infection: Transmission methods: •

Sexual: initially homosexual transmission; now predominantly heterosexual transmission

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Intravenous drug use

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Mother to baby transmission

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Contaminated blood products (particularly initially)

Mode of entry: viral gp120 binds to cells expressing CD4 and a co-receptor (CCR5 or CXCR4) •

gp120 embedded in the viral envelope binds to CD4 on the plasma membrane of the host cell

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This causes a conformational change

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gp41 mediates fusion of the viral envelope and the plasma membrane

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Fusion requires the presence of a co-receptor: o

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Co-receptor molecules (CCR5 and CXCR4): 7-transmembrane molecules which normally function as chemokine receptors

Viruses are tropic (i.e. they bind preferentially) to either CCR5 or CXCR4: o

CCR5 tropic viruses: macrophage tropic; this is the initial tropism in HIV infection

CXCR4 tropic viruses: T cell tropic; this is the subsequent tropism in HIV infection

Human polymorphism in CCR5: •

Mutant CCR5 allele: has a 32 nucleotide deletion which causation termination of CCR5 after transmembrane domain 4

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Mutant CCR5 is non-functional: it does not function as a co-receptor for HIV-1

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The mutant CCR5 allele is found Caucasians; not in Japanese or Africans

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Homozygotes: resistant to HIV infection because transmission is predominantly cause by CCR5 tropic viruses

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Heterozygotes: less resistant to HIV infection than homozygotes

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Both homozygotes and heterozygotes for the mutant CCR5 allele may still be infected by CXCR4 tropic viruses

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The mutant CCR5 allele may still exist at a high frequency due to natural selection

HIV pathogenesis: 1.

Acute infection: 2-3 months •

Active virus replication occurs (burst of viral replication)

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Viraemia occurs: i.e. the virus enters the bloodstream

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CD4+ cell count declines temporarily

Minor/asymptomatic phase: 15 years •

Host immune response starts: HIV-specific CD8+ CTLs are produced

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Viral titres decline

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CD4+ cell count recovers and plateaus; CTL count increases and plateaus

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Virus replication continues in lymph nodes and variation occurs

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The balance between the T cell response and ongoing viral replication maintains the virus but confers protection to the host

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The patient shows minor symptoms or is asymptomatic

AIDS: 1-3 years •

Host immune response is overcome: virus variants are no longer controlled by CTLs

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Viral titres increase

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CD4+ cell and CTL counts decline to low levels

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The patient develops AIDS, suffers opportunistic infection and dies

Outcomes of HIV infection: Outcome

CTL response

CD4+ cell and CTL counts decline after

Slow progressors

Good

10-15 years

Long term non-progressors

Strong

15+ years

Rapid progressors

Poor

1-5 years

HIV vaccine: Antibody-based vaccines: target HIV env protein gp120 •

Some anti-gp120 antibodies neutralise HIV

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Problem: HIV undergoes antigenic variation and escapes from the effects of antibody; therefore the vaccine is ineffective

CTL-based vaccines: target internal conserved epitopes in gag, pol and nef The vaccines stimulate high and long-lasting levels of CTLs and kill HIV-infected cells Problem: CTLs are only effective against infected cells; therefore the vaccine cannot prevent infection Possible solution: an effective vaccine requires a combination of antibodies and CTLs Anti-HIV drugs: AZT (zidovudine, retrovir): nucleoside analogue Mechanism of action: chain terminator Advantage: specific to HIV-infected cells- AZT is a better substrate for the HIV reverse transcriptase than the host cell DNA polymerase Dideoxycytidine (ddC) and dideoxyinosine (ddI) 3TC, (lamivudine): nucleoside analogues Disadvantage: have some toxicity Ritonavir, saquinovir, indinavir: protease inhibitors Mechanism of action: target the HIV aspartate protease by preventing cleavage of HIV polyprotein precursors into mature proteins Classes of antiretroviral drugs: •

Nucleoside/nucleotide reverse transcriptase inhibitors

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Non-nucleoside reverse transcriptase inhibitors

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Protease inhibitors

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Fusion (gp41) inhibitors

HIV drug resistance: 1.

Mutations arise in HIV due to the error prone nature of reverse transcriptase and RNA pol II

With time the virus becomes resistant to a single drug

If the drug is changed, mutations arise again

Solution: •

HAART (highly active antiretroviral therapy): use several drugs simultaneously

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Advantage: it is more difficult for the virus to develop multidrug resistance

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Disadvantage: expensive

Virus immune evasion Mechanisms of immune evasion: •

Antigenic variation: viruses either evade either the antibody response or the CTL response E.g. influenza; HIV; HCV

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Hiding: viruses establish a latent infection in which virus proteins are not expressed; therefore the infected cell is not recognised by the immune system E.g. HSV hides in neurones

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Viruses express proteins which inhibit the immune response in the following ways: o

Proteins block antigen presentation of viral peptides via class I MHC molecules; therefore CTLs do not recognise virus infected cells

Proteins block recognition of virus infected cells by NK cells

Secreted proteins capture cytokines, chemokines or interferons (in solution)

Proteins block intracellular signalling pathways or apoptosis

Examples of immune evasion: Vaccinia virus: encodes a protein (B15) which can control the body temperature of the infected host •

Mechanism of action: B15 only binds to human IL-1ß (it does not bind to any other cytokines)

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IL-1ß: the principal endogenous pyrogen that regulates body temperature

Interferons (IFNs): specific, soluble glycoproteins which induce an antiviral state in cells which express the appropriate surface receptors •

Type I IFNs (IFN-α and IFN-ß): bind to a common receptor (type I IFN-R)

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Type II IFNs (IFN-γ): binds to a different receptor (type II IFN-R)

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Type III IFNs (IFN-λ): bind to another receptor

All interferons have: •

Direct antiviral activity

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Immunomodulatory roles: e.g. IFN-γ promotes the Th1 response

Mechanism of interferon action: blocking virus replication 1.

The cell signalling pathway is activated

The IFN gene is transcribed

IFN is expressed

IFN is secreted and binds to IFN receptors

Engaged receptors trigger another signalling pathway

Antiviral proteins are expressed (this is induced by IFN)

Antiviral proteins remain in the cytoplasm and mediate antiviral activity

If virus infection occurs: antiviral proteins block virus replication

Protein kinase (PKR): an antiviral protein which is induced by IFN and activated by ds RNA 1.

PKR activation: inactive PKR + ds RNA  active PKR

Auto-phosphorylation: active PKR + ATP  active PKR + ADP

eIF2-α inactivation: active eIF2-α + ATP + active PKR  inactive eIF2-α + ADP

Inhibition of protein synthesis: viral and cellular protein synthesis stops and the cell dies

Vaccinia virus: gene E3L encodes an intracellular protein (E3) which binds to ds RNA •

Viruses lacking gene E3L: avirulent

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Mechanism of action of E3: binds to ds RNA and inhibits PKR activation; therefore virus replication continues

Vaccinia virus: produces soluble interferon receptors which are secreted

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Mechanism of action: the virus produces and secretes soluble proteins which mimic cellular proteins and capture interferons in solution; therefore it blocks the ability of interferon to bind to host cell interferon receptors

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B18 blocks type I IFN: B18 binds to type I IFN in solution and on the cell surface

Interfering with interferon: •

Many mammalian viruses interfere with interferon; if they did not they would probably not exist

Virus-host evolution: •

Threat of viruses has driven the evolution of interferons and shaped the human genome

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Threat of interferons has driven the evolution of viruses and shaped the virus genome

Microbiology 8: Prevention and Treatment of Viral Disease Prevention is better than cure; give examples of other viral infections for which vaccination is a successful strategy •

Vaccinia virus (the smallpox vaccine) has eradicated variola virus (smallpox)

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Vaccines have controlled several diseases including: diphtheria; tetanus; yellow fever; pertussis; measles; mumps; rubella; poliomyelitis

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New vaccines are needed for other unchecked diseases: e.g. AIDS; malaria

The eradication of smallpox and lessons from this for control of other diseases Smallpox (variola virus): the first and only disease which has been eradicated •

1796: Edward Jenner produced a vaccine

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1980: the WHO certified the eradication of smallpox

Smallpox eradication was possible due to the following factors: •

Smallpox did not have an animal reservoir (i.e. smallpox was a strictly human disease)

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Smallpox did not cause latent or persistent infections (i.e. smallpox was an acute disease)

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Easily recognisable disease

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The vaccine was effective against all strains of smallpox (i.e. all strains of variola virus)

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Vaccine properties: effective; potent; low cost; abundant; heat stable; easy to administer

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Determination by the WHO to eradicate smallpox

Reason for the effectiveness of smallpox vaccination: •

Outer envelope proteins of vaccinia virus and variola virus are highly conserved

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Capsid proteins of vaccinia virus and variola virus are highly conserved

These facts were only discovered after the eradication of smallpox, so… Lesson: to have an effective vaccine, you don’t need an understanding of all the antigens recognised by the immune system  if the vaccine works, use it! Considerations for vaccine development: •

Which antigens should be used (for antibody-based vaccines)?

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What type of immunity is needed? Humoral (antibody-mediated) or cell-mediated? o

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In the case of humoral immunity: are secretory (IgA) or systemic (IgG) antibodies needed?

When is the immunity needed? o

When does the pathogen induce disease?

Consider exposure in endemic areas (i.e. vaccination before travelling)

How should the vaccine be administered?

Types of vaccine: Passive vaccines: •

Immune globulin (e.g. for rabies; infants born to HBV positive mothers)

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Maternal antibodies

Advantages: offer immediate protection

Disadvantages: protection is short-lived; cause serum sickness; induce immune responses to foreign proteins Live vaccines: •

Attenuated forms of virulent organisms (e.g. yellow fever virus)

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Organisms which are immunologically related to viruses (e.g. vaccinia for smallpox)

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Maternal antibodies

Advantages: induce both T cell and antibody responses; protection is long lasting; low cost; easy to manufacture and administer Disadvantages: unsafe (may revert to virulence or cause serious infection in immunocompromised people); heat labile; may be shed into the environment •

Many virus vaccines used in humans are live attenuated vaccines

Dead vaccines: antigen preparations which have been chemically treated to inactivate infectivity and toxicity •

Whole viruses (e.g. rabies)

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Specific viral proteins (e.g. surface antigen for HBV; HA for influenza)

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Peptides to important epitopes

Advantages: safe (provided that the inactivation is complete) Disadvantages: require multiple administration (i.e. boosters) to achieve solid immunity; may require adjuvants; protection is short-lived; high cost; reduce cell-mediated immunity Sabin (live) polio vaccine

Salk (dead) polio vaccine

Methods of producing new vaccines: Genetically engineered subunit vaccines: 1.

Identify the gene encoding the desired antigen

Express the gene: clone the gene using vectors

Purify the protein to use as an immunogen

Advantages: safe; specific; cheap; abundant E.g. Hepatitis B vaccine Genetically engineered live recombinant viruses: 1.

Identify the gene encoding the desired antigen

Express the gene: insert the gene into the genome of a live virus to produce a recombinant virus

Use the live recombinant virus as the vaccine: this simultaneously expresses the antigen and delivers it to the immune system

This method enables the development of polyvalent vaccines which target multiple antigens simultaneously Explain why it is difficult to develop drugs which selectively act against viral infections Antiviral chemotherapy:

Must inhibit the virus without toxicity for the host Viruses have fewer targets than bacteria Targets in viruses: binding to the host cell; replication (esp. enzymes); assembly; dissemination Give examples of classes of drugs which have been used successfully in antiviral therapy Anti-herpes virus drugs: Acyclovir (ACV) (Zovirax): nucleoside analogue •

Active against HSV-1 and HSV-2

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Apply topically

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Activity: requires HSV thymidine kinase (TK) and DNA polymerase

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Mode of action: once incorporated into the DNA, ACV blocks further elongation

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Specificity: ACV is active in HSV-infected cells and not in uninfected cells o

ACV is a better substrate for HSV TK than host cell TK

ACV triphosphate is a better substrate for HSV DNA polymerase than host cell DNA polymerase

Ganciclovir and cidofovir: nucleoside analogues •

Used for human cytomegalovirus (HCMV) infections

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Specificity: due to use by viral DNA polymerase

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Cidofovir must be given intravenously and has some renal toxicity

Describe the strategies underlying the search for novel antiviral agents Viruses: friend or foe? Viruses are valuable research tools: •

For studying cell biology and immunology

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For gene therapy

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As new vaccines

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As tools for molecular biology