IB 114
Dynamics: SIR model
R- recovered, resistant or dead disease will increase if ΔI positive, (host density above threshold) as disease spreads, individuals enter resistant class or die when resistant class becomes sufficiently large, density of susceptibles get too low and disease dies out
Visher et al paper
influenza: high levels of productivity, high burden on health care infrastructure. no vomiting A: generally talked about H_N_ B: only in humans, more stable than A, less antigenic drift. children/milder disease C:rarely reported, mild symptoms, not associated with epidemic disease avian: alpha-2-3-linked in respiratory/GI tract human: alpha-2-6-linked sialic acid in upper respiratory Mutation rate matters: 1. high mutation rates may help with host shift 2. high mutation rates constatnly generate novel variants 3. Fast evolution makes control difficult mutational robustness Quasispecies model- fitness of variant depends on mutational neighborhood leads to brittle and robust genotypes Methods: 1. Made random mutants across genome 2. Directly compete mutants against wt strian to measure fitness H/N higher fitness if mutated? influenza similar to those of same genome size novel treatment options: lethal mutagenesis
Endoparasites
intimate association
Virus
intracellular obligate parasites -use cell components to replicate -DNA or RNA + proteins -transferred extracellulary (plasmids, transposons) FMD disease, first viruses. highly variable in size, structure and complexity
Leeuwenhoek
invented microscope-
Macroparasites
large bodied-nematodes/tapeworms/fleas longer generation times adults release infective stages that can persist outside of host persistent infection no lasting immunity impact is a function of number of parasites per host
Megavirus and Mimivirus
largest viruses. 1million bp DNA and 1000 genes.
ectoparasites
less intimate association
Phage Lambda
linear dsDNA in virion, circulizes on cell entry, large genome infects e. coli DNA virus: recombination following multiple infection use host's recombinational machinery 1. Lytic 2. Integrated into host genome; lysogenic
Parasites
macroparasites
Toxoplasma gondii
manipulates host behavior, more risk taking mice sniffs cat pee and likes it
Mixed infection
may cause genetically different strands in same virion
Infectious Disease history
much of our emotional and moral attitude to disease is legacy of past history principles of disease biology apply to plants, animals, humans. Studying plant/animal disease helps to understand human.
Antigenic drift
mutations cause small changes in H or N antigens on surface of virus
Negative virus
need to replicate complementary strand which is then transcribed and translated need to be converted to positive sense RNA by RNA polymerase before translation don't seem to produce dsRNA and may evade host immunity
Upward incorporation
new definitive host, typically higher up a food web and which preys on original definitive host is added Original host becomes intermediate host, in which reproduction is suppressed Advantages: - avoid mortality due to predator -greater body size at maturity, higher fecundity (more space to grow)
Downward Incorporation
new intermediate host is added at a lower trophic level Advantages: - reduces mortality -facilitates transmission to original definitive host
SARS
newly emergent Asia, spread worldwide. 774 died. Transmission through direct person-to-person contact
Disease cause
non-infectious: caused by internal and external conditions infectious agents: replicating entities that multiply in or on hosts, and are transferred from host to host; when these agents cause harm to the host, we call them pathogens or parasites; when they enter a host we say the host is "infected", manifestations of the harm that they cause is termed a disease infectious disease: infectious disease is product of interaction between host and pathogen or parasite
Rabies
none in Switzerland
leptokurtic
normal curves that are tall and thin, with only a few scores in the middle of the distribution having a high frequency advance is faster than with normal
Disadvantage vertical transmission
not efficient way for pathogen to increase reproductive rate, at best only same level of disease on avg, indivudal leaves only one mature offspring in constant population. Transmitting to one offspring doesn't spread disease not sustained unless 100% transmission Always trade-offs, increase transmission in one pathway reduces transmissinon by other. Intracellular transmission Reproductive organs are where pathogen is located Persist to reproduction No adaptation for dispersal needed To persist as vertical pathogen must: 1. Have additional horizontal transmission mode OR 2. increase reproductive success of host- By definition makes it a mutualist
Parsimonious
not overwhelmed by unknowns. We want to have it be as simple and straightforward as possible
Intellectual fossilization
not pushing forward. erroneous paradigm.
βxIxs
number of newly diseased individuals per time interval
S
#healthy/susceptible
Basic Reproductive Number
#secondary infections produced by single infected host in susceptible population You need susceptibles for chain of infection to establish
Transposons
(jumping genes) short strands of DNA capable of moving from one location to another within a cell's genetic material
Tobacco Mosaic Virus (TMV)
+ssRNA Virus that affects many species of plants e.g. tomatoes Symptoms: a mosaic pattern on the leaves - parts of the leaves become discoloured The discolouration prevents the plant from photosynthesising as well, thus the virus affects growth
Samy et al
- Socioeconomic model criticized by disease biologists human densities as ZIka informer higher people densities will increase spraying public health much higher risk for bees
Bacterial classification
1. Morphology 2. Staining 3. Serology 4. Biochemical properties
Bacteria variation generation
1. Mutation -replication error (have DNA repair) -transposons 2. Recombination -transformation -transduction -conjugation 3. Plasmids 4. Infection by phages that integrate into genome
Virus generate new variant mechanism
1. Mutation/Errors during replication 2. recombination
Different host adoption phylogenetic frameworks
1. Vertebrate first 2. Mollusc first 3. Blend
Bacteria
1. freeliving or extracellular or intracellular 2. no nucleus or membrane bound organelles 3. Genome consists of singular circular dsDNA/ smaller plasmids 4. Small, visible in light microscope
HIV new variants
1. mutation: reverse transcriptase has no error repair. rate per base pair: 3x 10-5. 9100 bp. Produces 10^9 virions per day. 2. Recombination: virion diploid; two RNA molecules, code for identical genes
Viral Classification
1. ssDNA, dsDNA, ssRNA, dsRNA 2.Replication via DNA or RNA 3. positive or negative translation 4.Replication site- nucleus or cytoplasm 5. Capsid morphologies A MESS!
Vertebrate host
1.further dispersal 2.predation survival 3. Find a mate- vertebrates larger so more different types that can potentially be there (no use in mating with same genes)
Viroids
3-400 bases, no protein coding, infect platns, circular naked ssRNA (no protein coat)
Ringworm
40 types of fungi can cause, Diseases: athlete's foot (tinea pedis) / jock itch (tinea cruris ) reproduce asexually in "conidia", sexual stages unknown
Microviridae
5000 bases, circular encapsulated ssDNA, 10 genes, 6 partially overlapping genes
positive frequency dependent selection
Phenotypes are favored only when common. Example is warning coloration or DVD vs blu-ray. Equivalent but DVD died since it was less common as blu ray was more common and was able to afford licensing more movies and selling them making more money.
negative frequency dependent selection
Phenotypes favored only when rare. Example is left-handed fighting ability, converse shoes. As host type becomes popular, then there's common so lots of things trying to infect common host as it increases their own proability of reproducing. Selection pressure to infect common host. Host will then survive better if rare which drives down the frequency in population of common host type.
Malaria
Plasmodium species, protoza phylum Apicomplexa disease of reptiles, birds, mammals Humans: P. falciparum, Pvivax P. malariae Life cycle: human and mosquito ANopholes mosquito Vector: female Anopholes mosquito definitive host: where sexual reproduction occurs, not just a vehicle High historic importance locations became permanently or seasonally uninhabitable. huge impact on armies, high cause of hospitalization ~50deaths/hour
Gram positive
Positive stain blue for peptidoglycan cell wall constituents
Antigenic shift
Acquisition of entirely new antigens when influenza viruses reassort looks totally different
niche models
Species Distribution Modelling (SDM) applied in ecology biogeography correlative
Plague
Yersinia Pestis
Mutational robustness
ability of organism to maintain phenotype when genotype changes
Exogenous prion
abnormal protein is ingested
Prions
abnormal proteins that cause neural degeneration but are transmissible transmissile, abnormal folding of specific normal "prion proteins" that are found most abundantly in brain Normal folding: helices Abnormal: sheets abnormal folding of prion proteins leads to brain damage and characteristic signs and symptoms of disease Ex: Creutzfeldt- jakob infectious protens Endogenous origin: mutation in gene coding causes it to fold into "sheet" fconformation
Chestnut blight
accelerated speed, leptokurtic
Coitocaecum parvum
accelerates devlopment and rapidly reach precocious maturity in crustacean intermediate in absence of chemical cues from fish definitive host Worms were longer when exposed to control water than fish-conditioned water
Transduction
accidental transfer of bacterial DNA by bacteriophage
Aerial transmission
aerosoles, airborne spores
Robert Koch
anthrax caused by bacterium bacilis anthracis. Experimental criteria to establish causal relationship between microorganisms and disease 1. Microorganism has to be present in diseased and not healthy individuals 2. Has to be isolated and grown in pure culture 3. When re-inoculated into host must cause same disease 4. Same organism must then be re-isolated from experimentally diseased host
t
arbitrary time interval
carrier
asymptomatic but still infectious
latent
asymptomatic for disease
Abundance
average # parasites across all hosts (prevalence*intensity)
Intensity
average # parasites within infected host mean # worms/host usually macroparasites only
R0
average number of new cases that each primary infection produces over infectious period in completely susceptible population must be >1 for invasion
Rust fungi
caused by numerous Uredinales species alternate hosts Wheat rust- Puccinia graminis Alternates barberry and wheat- Uredinia produces urediniospores. Asexual summer cycle on wheat (rust color) Basidiospores in spring go to barberry Barberry eradication program
Dikaryon stage
cell genetically diploid but nuclei remian separate
Lytic vs non-lytic
cell lysis of virion production and release
incidence
change in number of cases or prevalence per unit time
Causes of disease
concept of contagion remained undefined and vague for centuries.
core
contains nucleic acid,
Macroparasite population biology
count number of worms or parasites in body , number matters tapeworm
Microparasite population biology
count whether infected or not- binary, particulates don't really matter flu/rabies/measles
Threshold density
critical community size
Pathogenicity
degree of damage to host tissue by pathogens
virulence
describes negative effects of parasites on host fitness (disease-induced mortality, or severity of infection)
Horizontal transmission routes
direct contact transmission aerial transmission waterborne transmission soil borne vector transmission trophic transmission
Potato blight
direct observation of germs-organisms= disease Miles Berkeley- potato blight caused by fungus
Positive strand virus
directly codes for mRNA viral RNA similar to mRNA, immediate translation in and of itself infectious even without full viral particle
At equilibrium...
disease is endemic not epidemic. not all population is diseased
zoonotic
disease primarily transmitted from animals to humans
β
disease transmission coefficient per individual contact rate cx 𝛿 hard to measure directly
Seasonality
disease transmission is not constant during year childhood disease- more transmission in term time
α
disease-induced host mortality rate
Baculoviridae
dsDNA virus insect form crystal-like structures in cells of insects (inclusion bodies or polyhedra) polyhedrosis viruses polyhedra: DNA-protein complexes that can survive outside the cell biocontrol
V. cholerae ecology
endemic in estuaries/oceans. parasites of crustaceans Hindgut of crabs, influences osmo-regulation
Wolbachia
endosymbiotic bacterium. changes males to females, more females increases transmission kills males: good if progeny compete- more resources for females- good if progeny eat each other bad for host population as it may lead to too few males to fertilize females
Trematodes
flatworms/flukes internal parasites of molluscs and vertebrates most trematodes have complex life cycle with at least 2 hosts primary host where flukes sexually reproduce is a vertebrate intermediate host, asexual reproduction, usually snail
Cercaria
free swimming larval stage of trematodes (flukes) they leave host and then enter again, may want to have upstream density
Nematodes
free-living and parasitic on plants and animals complex morphology; separate sexes, females lay eggs Larvae have deterministic development, fixed number of larval stages separated by "molts" 3rd stage larvae are dispersal or infectious stage Medical symbol Ex: Loa loa, Root knot disease, Guinea worm. Dracunculus
Vertical transmission
generations from parent to offspring female to offspring most common Types: -Cytoplasmic -transplacental -perinatal (during birth) -postnatal (lactation)
Transmission factors
greater number of livestock, greater transmission/risk of infection certain species transmit more and are more susceptible
Fungi
grows as hyphae to produce mycelium or yeast-like forms. Reproduce asexually by spore production fertilization (syngamy) occurs by hypahal fusion, fusion of single cells, or fusion of spore with hypha meiosis may occur directly after fusion or after extended dikaryon stage greatest cause of species extinction or extirpation events
INfected
harboring disease agent
Neuraminidase
helps release virions from the host cell after replication and assembly
b
host birth rate, per capita
d
host natural mortality rate
morbidity
host weakness or lethargy caused by disease
SIR assumptions
hosts uninfected at birth infection doesn't affect host fecundity recovered hosts remain resistant for life population large enough that stochastic processes can b ignored
Bacterial pathogens
humans: cholera, syphilis, plague Plants: citrus greening disease, fire blight
Avian influenza
in birds, occurs worldwide. Highly pathogenic form caused by H5 and H7 viruses. Antigenic shift: genetic reassortment with human influenza virus to enable person-person transmission. First cases of avian influenza in humans in HK 1997a
Clonal amplification
in their first intermediate host leads to average 4-fold expansion of numbers of individuals at next life stage. Trophic transmission to definitive host results in no numerical change. (getting eaten)
Downsides of complex life cycle
increased chances of not finding host and dying Evidence that life cycle truncation has evolved independently many times
Complex life cycle parasites
indirect life cycle parasites parasites that sequentially infect different hosts over lifecycle curse NOT multi-host NOT same as vector-transmitted parasites/pathogens
virions
individual particles have core and capsid may or may not be coated with membrane from host cell may or may not be accompanied by cell lysis
Susceptible
individual who will acquire infections if exposed to pathogen
Leucochloridium paradoxum
infected snails will position themselves in more exposed/illuminated places and situated higher in vegetation hopes to get eaten by birds
I
infected/infectious
nosocomial
infections occuring primarily in hospitals
Paragordius tricuspidatus
infects wasps, makes them fall in water and worms come out
Lytic viral particles
infects, multiplies and bursts bacterial cell (lysis) producing more virus
Zika
Aedes aegypti, A. Albopictus birth defects sexual transmission Flaviviridae Americas/Brazil prevention: life immunity, hard to limit transmission when don't know infectious mosquito removal- habitat removal/spraying (hard to get information for spraying)
Messina et al.
Alt. model -brazilian data -accounts for change in virus since discovery -may not represent a "typical" year florida/lower USA yes bees at risk.
parasitoids
An organism that lays eggs inside other organisms. always harmful
Carlson et al.
Conservative model: -used african data -assumed zika hasn't changed -limited by small data mostly in tip of Florida
Complex life cycle parasite diseases:
Dracunculiasis (guinea worm disease) caused by Dracunculus medinensis Schistosomias caused by digenetic blood trematodes "swimmer's itch" caused by Trichobilharzia regenti
Transplacental
HIV at low percentage, german measels (rubella)
Perinatal
HIV at substantial, gonorrhea, seed borne viruses and fungi in plants
postnatal
HIV through breast feeding seeds under parental trees get soil borne pathogens from parents
Humoral theory
Hippocrates- natural causes Humoral theory: Elemental ideas (Aristotle) disease caused by disequilibria and imbalances key people weren't medical scientists imbalances caused by stars/weather/behavior/decoposition. disease contagious but mechanism of spread was by "smells and miasmas" STILL influences us. words still reflect theory- cold, ulcers.
Cucumber mosaic virus, CMV
Host: cucumber and wide range of wild/cultivated plants particulate virus- needs 3 virions
Holding types
IP- infected premise CP- contiguous premise DC- dangerous contact
fomites
objects on which diseases are transmitted (objects are vector)
Protozoa
one-celled organisms that are more complex than bacteria Ex: Giardia Trypanosomes: sleeping sickness, chagas, coffee phloem necrosis, dourine horse STD
Waterborne transmission
oral-fecal
OID
ordinary infectious disease aerial, soil, waterborne, non sexual contact diseases number of contacts increase with crowding Density-dependent or "mass action" transmission Ex: hookworm abundance or microsporidians in Daphnia
Endemic
parasite consistently present, no large or sudden fluctuations in prevalence
Male to offspring transmission
pathogens may adhere to sperm, enter sperm, or carried in seminal fluid. Problem in human infertility and cattle insemination Chlamydia adheres to sperm pathogens adhere to pollen grains
FMD Keeling et al
peak in late March, long tail after May. rapidity in culling would have been ideal. 1. We need robust set of models to deal with range of human/livestock diseases 2. Models should be in place before disease invades 3. Need suite of powerful statistical techniques to rapidly ascertain parameter values 4. Excellent lines of communication between vets, scientific advisors, policy makers 5. Rapidity key to success: in terms of detection, decisions and control farm as unit environmental niche modeling stochasity heterogeneities large farms, more infectious prompt culling
𝛿
per contact probability of infection Probability of gettind disease given contact was made
c
per individual contact rate number of contacts per individual per unit time
Naled
pesticide for mosquito highly effective applied in small amounts rapidly degenerates kills bees on exposure
Reservoir hosts
place for storage alternate or passive host or carrier that harbors infectious organism without harm to itself and can serve as source of infection for other individuals or species mainly refers to among-species transmission so depends on reference host species
Ring vaccination or culling
pre-emptive: prevent new infections within prescribed area -local vacc -killing/culling individuals locally Ex. citrus canker, FMD in england Rabies switzerlandn
Isolation
prevent dispersal of infectious individuals -infected needs to be identified rapidly prevent dispersal of whole population -if diseased individuals are not easily recognized
Quarantine
prevent immigration of infected individuals by keeping them through the incubation period
Transformation
process in which one strain of bacteria is changed by a gene or genes from another strain of bacteria direct uptake of exogenous DNA
Strand switching
produces recombinant RNA molecule from reverse transcriptase
DISEASE is not the causal agent
product AIDS: disease HIV: pathogen
infectious disease
product of interaction between host and pathogen/parasite.
Prevalence
proportion of hosts infected or expressing disease (#infected/ total N)
βxI
rate at which each susceptible individual becomes infected
γ
recovery rate probability a diseased individual recovers in a unit of time
Herd immunity
reduced probability of infection due to the presence of a high proportion of individuals in the population with immunity.
Immunity
resistance to infection incurred through exposure to previous infection
Influenza Virus
segmented -ss RNA virus, enveloped host: most vertebrates bind through hemagglutinin synth viral proteins secreted through neuraminidase Exit: membrane rupture multiple infection recombination- highly pathogenic avian can recombine with human making a highly pathogenic human strain
Disease
semi-permanent bodily condition that reduces an individual's well-being biological organism: any semi-permanent bodily condition that has a negative effect on an individual's fitness product of interaction between host and parasite
Segmented
several RNA molecules in one virion
Particulate
several virions needed for infection
Particulate virus
several virions needed for successful infection
Direct contact transmission
sexual vs non sexual
STD
sexually transmitted disease contacts relatively independent of density, tranmission depends on fraction of individuals diseased "frequency-dependent transmission"
HIV
sexually transmitted, attacks T-helper cells of immune system CD4 or CCR5, destruction of immune system, death by opportunistic infections (AIDS) Control issues: 1. Delayed disease onset, undetectable without testing 2. High genetic variability 3. Integrated into host genome and can remain cryptic 4. Sexually transmitted
Bassi
silkword disease caused by fungal infection. germs- organisms-disease
Dynamics conclusion
simple models can capture a range of disease dynamics: endemic, outbreak, sequential epidemics SIR model with demography (births, deaths) and forcing is enough to explain the different dynamics of childhood diseases
Microparasites
small- protozoa, viruses, bacteria, fungi rapid multiplication in host short generation time usually leads to crisis in host...
Critical community size
smallest population of susceptible hosts below which disease goes extinct, and above which disease persists mealses and whooping cough persist in large cities but "Fade out" in smaller towns
Nt
some parasites have critical population size for establishment
Benedict Prevost
spores could produce fungus
Basidiomycetes
spores produced externally on basidium
Ascomycetes
spores produced internally in ascus
Norovirus
ssRNA, non enveloped gastroenteritis Cyclical dynamics: common driven by seasonality, transmission increases with weather conditions pulses of susceptibles Hypothesis: Winter vomiting: moisture/temperature/humidity, how long viruses can stay in airor can persist longer in water sources
Koskella et al paper
study Potamopyrgus antipodarum (frewhater new zealand snail, high clonal diversity) Microphallus sp. (sterilizing trematode with complex life cycle NO direct horizontal transmission-good for lab. Asexual reproduction in snails and sexual in the ducks that eat snail (here it's mice) Coevolution drive changes in host population composition Recycled: common clone frequency decrease compared to control parasites are targeting common clone. Cross-inoculated with parasties from field population and those from experimental populations. Prevalence stays same because each running as fast as it can to escape it. Prevalence doesn't change but no forward progress, genetically changes rapidly. Red Queen hypothesis
Epidemic
sudden increase in prevalence or intensity (sharp rise in new cases): parasites characterized by periodic outbreaks
Linnaeus
suggested diseases caused by living organisms- Systema Naturae "Chaos"
N
total population size S+I
Conjugation
transfer of bacterial DNA via conjugative plasmid
iatrogenic
transmission because of medical attendants ( humans are vectors)
Disease fails to spread if:
transmission low few susceptible hosts high virulence rapid host recovery
Horizontal transmission
transmitting within one generation between unrelated individuals.
Influenza Pandemic 1918-1919
unusually severe and deadly strain. 50-100m deaths worldwide. more killed than WWI.
Retrovirus
uses own reverse transcriptase enzyme to produce DNA from RNA genome new DNA incorporated into host cell genome by integrase enzyme Host cell treats viral DNA as part of own genome, translating and transcribing viral genes along with cell's own genes
Pathogen
usually thought of as smaller than parasites pathogen
Smallpox
variola virus new world bioterrorism (Aztecs, Delaware) eliminated worldwide through vaccination since 1979 but cultures exist in laboratories
Cytoplasmic vertical transmission
vector borne diseases in the vector (west nile, lyme )
VTD
vector transmitted diseases Relation to density complex: 1. Contacts increase 2. Contacts stay constant- vector search compensates for changes in host density 3. Vectors numbers per host declines and so do contacts "dilution effect" Pollinator transmitted disease: anther smut
Vector transmission
vectors may be passive or biological
Excision
virus "jumps out" and lyses cell
Lysogenic
virus in this stage is called prophage replicates with bacterial host integrated in host genome
spatial modelling
capture local spread of disease
Stochastic
capture random nature of transmission
Life cycle truncation
-rare or missing host hypothesis -environmental instability hypothesis (inconsistency of hosts over time) -developmental time hypothesis (can't wait) -cannibalism hypothesis (adults eat babies of same species) -latitudinal gradient hypothesis (expanded range)
Transmission conclusions
-vertical or horizontal -vertical not efficient, may lead to modifications of sex ratio - horizontal transmission may be expected to be different between ordinary, sexual and vector transmitted -frequency dependence and density dependence transmission
Viral replication
1. Adsorption 2. Entry 3. Uncoating 4. Transcription/mRNA production 5.Synthesis of virus components 6. Virion assembly 7. Release (liberation stage
Endogenous origin of lethal disease Inheritance???
1) late onset of disease (post-reproduction) 2) Recessive allel encoding misfolding Selection is less efficient, esp if there's a selective advantage of allele in early life 3) Heterozygote advantage, Homozygous is deleterious but heterozygous is helpful
Fungal disease
Ascomycetes: Trichopyhton (ring worm) , Entomophaga (summit disease of insects) Basidiomycetes: Puccinia (wheat rust) Cryptococcus (meningitis/pneumonia in humans), Microbotryum (anther smut
Recombination
DNA viruses can undergo recombination using cell's enzymes and generates variation if multiple infections within same host RNA viruses can't use cell's enzymes to recombine sporadic cases of recombination reported in some -ssRNA
Mutation/Errors during replication
DNA viruses: DNA polymerase has error repair. lower mutation rate. 1 x 10-9 RNA viruses: replicate either by RNA replicase or by generating DNA by reverse transcriptase. No error repair. Mutation rate: 1x 10-4 bp
Fracostoro
De Contagione first accurate description of contagion/infection.
Controlling epidemic spread
Isolation quarantine Ring vaccination Culling
Cholera
LARGE complex genome wide range of plasmids and integraded phages Virulent: CTXf intense diarrhea, loss of body fluids, loss of electrolytes 6 vibrio species associated with cholera-like symptoms V. cholerae is very variable ca.180 serotypes -transmitted mainly through water -incubation period 1-3 days -bacteria adhere to intestinal wall -secretes toxin stimulating hyperproduction of water and salt -diarrhea: water loss of 10-15 liters during infection antibiotic resistant plasmid- up to 7 on single plamid. Not easily treatable with antibiotics
Germ theory accepted
Pasteur- microorganisms responsible for fermentation MIcro-organisms not spontaneously generated but from reproduction of pre-existing micro organisms Microbes responsible for specific diseases
John Snow
Mapped the occurrence of cholera in London, water source
Enveloped vs. non-enveloped viruses
Membrane from host cell coating - enveloped viruses need more intimate contact in order to infect a host cell, but they are able to change their outside appearance more easily without causing problems for the virus itself allowing it to evade the immune surveillance - non-enveloped viruses are sturdies and can survive longer outside the host, so they can invade easier, but they are limited in their ability to change outside appearance and thus are more recognizable by immune system
Anther-Smut disease
Microbotryum spores carried from flower to flower by pollinators Host: white campion Smutted flowers- XY and have stamens. Diseased females develop stamen from normally XX but get stamens for more infection
Hemagglutinin
One of the enzymes found on the surface of the Influenza virus. It is responsible for binding the virus to the cell that is being infected.
capsid
Outer protein coat of a virus
Gram negative
Red stain, many pathogenic stains in phylum Proteobacteria, no peptidogylcan cell wall constituents
Syphilis
Small genome, plasmid like no known conjugation/sex in spirochaetes rare bacteriophage multi-gene family. Sensitive to penicillin sexually transmitted, can't be cultured in vitro lesions- local allergic hypersensitivity rxns tertiary stage effects largely result of body rxns to pathogen dementia
Simple microparasite model
SIR. useful for translating individual-level events to population-level processes Epidemilogists: measure and model disease changes over time and space
Human evidence of contagion
Semmelweis- childhood fever can be prevented by physicians washing hands Snow- cholera waterborn Lister- antiseptics
Same agent can cause different diseases
Varicella-Zoster Virus= Human Herpes Virus 3; Prions
Etiology
cause of disease
Damped oscillations
births/deaths leads to endemic state
Why do complex life cycle parasites exist?
break out of growth/reproduction trade off
Measles
can e explained by simple mechanisms 1. SIR individuals 2. Seasonal transmission
Crown gall
cancerous like disease of plants, infects wide range. Agrobacterium tumefasciens Inserts piece of Tumor inducing plasmid region into plant cell Cell produces opalines (amino-acid like) that only bacterium can metabolize.
Trophic transmission
cannibalism or feeding on intermediate hosts
correlative vs mechanistic
where do we find species? where else is similar to where we find it? how does its physiology work? where would we expect it?
Soil borne transmission
with or without long lived resting stages