IMMUNO

Question 1

primary and secondary immune organs

Answer 1

Primary- phagocytes, complement system and barriers like skin
Secondary- T cells, B cells, lymphocytes, macrophages, dendritic cells

Question 2

the ways in which cell types are identified

Answer 2

by: histology (size, shape, stain, nucleus characteristics), enzymes and antibodies that recognize immune cells

Question 3

antibody and its Fc region

Answer 3

flexible specific adaptor due to a high affinity antigen binding site and Fc region in order to neutralize toxins (prevent binding to receptors) and aid in phagocytosis

*Fc regions: located on the opposite end of the antigen binding site and is a place where effector cells or proteins can bind to

Question 4

antibody and its Fc region

Answer 4

flexible specific adaptor due to a high affinity antigen binding site and Fc region in order to neutralize toxins and aid in phagocytosis

*Fc regions: located on the opposite end of the antigen binding site and is a place where effector cells or proteins can bind to

Question 5

opsonins

Answer 5

antibodies that are capable of forming a high affinity bridge to enhance phagocytosis of bacteria found in the extracellular space (opsonization)

Question 6

complement

Answer 6

serum protein that recognizes bound antibody molecules and can result in cell lysis

Question 7

CD

Answer 7

“Cluster of Differentiation”: notation system of antibodies that recognize immune cells

examples:
CD3–> mature T-cells
CD4–> T-helper/regulatory
CD8–> T-cytotoxic

Question 8

neutrophil

Answer 8

the end product of myeloid differentiation that will not divide and contains primary/azurophilic and secondary/specific granules (bactericidal and hydrolytic enzymes of the cell)

make up 60-70% of the circulating white cells (12hrs) and complete its life cycle at the site of inflammation when released from the bone marrow to fight off infection

Question 9

eosinophil

Answer 9

1-3% of the circulating leukocytes (30min half life and 12 day survival in tissues) with the ability to destroy parasitic worms by releasing granule contents due to Eosinophilic Basic Protein (EBP)

Question 10

macrophages-monocytes

Answer 10

derived in the bone marrow and function as effector cells at sites of inflammation phagocytosing bacteria (creating phagosomes and phagolysosomes once the bacteria is degraded) but can exist in a resting state when inflammation is not present

• intracellular killing: bacteria, yeast, parasites
• extracellular killing (in vitro): virally infected cells, larger parasites, tumor cells

**binding of bacterial components to signaling receptors induces the synthesis of inflammatory cytokines

Question 11

pathway of monocyte precursor to immune response initiation

Answer 11

monocyte (precursor)–> macrophage–> T-cell activation–> initiation of immune responses

Question 12

mast cell

Answer 12

expels parasites by releasing granules that contain active agents such as histamine

Question 13

lymphocytes

Answer 13

B-cells: expresses immunoglobulin producing antibodies when fully differentiated as a plasma cell (or can become memory cells) and is only able to express a single variable region (idiotype) with the highest affinity to the antigen that undergoes clonal expansion

T-cells (cytotoxic T-cells): helps B-cells through regulating the immune response and acting as an antigen specific effector cell restricted to killing cells with self and foreign antigen limiting target cell types to infected cells and tumor cells (prevents B-cells from attacking our own cells)

• *some can kill non-self cells associated with transplants
• *histology: no granules present in cytoplasm
• *pathogen-reactive lymphocytes proliferate

Question 14

lymphocytes

Answer 14

B-cells: expresses immunoglobulin producing antibodies when fully differentiated as a plasma cell

T-cells (cytotoxic T-cells): helps B-cells through regulating the immune response and acting as an antigen specific effector cell restricted to killing cells with self and foreign antigen limiting target cell types to infected cells and tumor cells

• *some can kill non-self cells associated with transplants
• *histology: no granules present in cytoplasm

Question 15

natural killer cells

Answer 15

granular lymphocytes that kill tumor and virally infected cells WITHOUT specificity

Question 16

what is the pathway that leads to the production of platelets?

Answer 16

hematopoietic stem cell–> myeloid precursor–> megakaryocyte–> platelets

Question 17

what do each end of immunoglobulin molecules do?

Answer 17

constant region binds to transmembrane surface and variable region has antigen-binding sites at its tips

Question 18

proteins that make up immunoglobulin molecules

Answer 18

heavy chains and light chains make up constant and variable regions which are attached by disulfide bonds at hinge region and contains carbohydrates

• variable region is located at Y tips and contains antigen-binding sites
• light chains are the outside of Y branches

Question 19

proteins that make up immunoglobulin molecules

Answer 19

heavy chains and light chains make up constant and variable regions which are attached by disulfide bonds at hinge region and contains carbohydrates

• variable region is located at Y tips and contains antigen-binding sites
• light chains are the outside of Y branches

Question 20

IgG

Answer 20

• most common
• longest half life
• transportation across placenta

Question 21

IgA

Answer 21

• one form is secreted (resists acid hydrolysis)
• highly glycosylated
• monomers/dimers/trimmers
• capable of transportation across epithelium
• opsonizing and agglutinating (sticks)

Question 22

IgM

Answer 22

• primitive
• potent complement fixation
• no opsonization-immune cells don’t have IgM receptors
• greatest molecular mass
• 4 heavy chain domains without a hinge region
• J chain

Question 23

IgE

Answer 23

• responds to parasites
• allergic reactions
• few in circulation–>binds to target/mast cells
• mediates release of granule contents from mast cells
• mediates changes in vascular permeability

Question 24

**proteolytic degradation of IgG

Answer 24

IgG –(protease cleavage)–> 1 Fc + 2 Fab fragments

Fc= crystallizable and made of constant region repeats
Fab= antigen binding with the variable region

• –not really important but in the notes—-
• papain digests hinge region
• pepsin degrades heavy chain beginning at carboxy terminal and ending at the region of interchain disulfide bonds

Question 25

proteolytic degradation of IgG

Answer 25

IgG –(protease)–> 1 Fc + 2 Fab fragments

Fc= crystallizable and made of constant region repeats
Fab= antigen binding with the variable region

Question 26

framework residues and hypervariable regions of the variable region of immunoglobulin molecules

Answer 26

framework residues: same between proteins and contribute to the folding of the V region producing the antigen binding site

hypervariable region: 3 in each heavy and light chain contributing to the specific antigen binding site and forming a continuous surface to complement a specific antigen; regions are distant in primary sequence (on two chains) but are close together in the antigen binding site

Question 27

monoclonal antibody

Answer 27

bound reversibly to an antigen and the affinity between the two is the sum of all of their interactions expressed by the law of mass action

K= [Ab Ag] / [Ab][Ag]

*have affinity but since they bind to the same epitope, there is no cooperativity and no increase in avidity

Question 28

why are immunoassays used and what are 4 examples?

Answer 28

a process of measuring specific proteins through their properties as antigens or antibodies

examples: ELISA, immunofluorescence, FACS and Western Immunoblot

Question 29

how do immunoassays work and when are they used?

Answer 29

?

Question 30

cross-reactivity

Answer 30

antiserum cross reacts with other antigens besides the specific antigen which may be due to impurities (already present antibody or antigenic contaminating proteins) or common/similar structures (homology) on antigens such as epitopes

could lead to: masking an expected result, false results, lowering of the effective sensitivity of the assay or could have no effect on immunoassay test results

Question 31

techniques used to eliminate cross reactivities

Answer 31

• absorbtion: using cross reacting material to remove the activity that causes the cross reaction
• affinity chromatography: a method used to purify antigens using an insoluble support (ex: agarose) and mild denaturant (ex: salt) to wash away unbound molecules and elute specifically bound molecules

Question 32

techniques used to eliminate cross reactivities

Answer 32

• absorbtion: using cross reacting material to remove the activity that causes the cross reaction
• affinity chromatography: a method used to purify antigens using an insoluble support and mild denaturant to wash away unbound molecules and elute specifically bound molecules

Question 33

*preparation of monoclonal antibodies

Answer 33

1. immunize an animal
2. isolate spleen cells (B-cells which can only live a few days without myeloma cells)
3. fuse cells to plasmacytoma tumor cells (unlimited growth)
4. select for hybrids of tumor cells and B-cells
5. clone hybridomas so each cell grows independently
6. select the individual clone with specificity you need

• production of a single clone of one B-cell
• no heterogeneity (population of antibody molecules identical with the same specificity)

Question 34

what happens when an immunization if to a specific protein?

Answer 34

the clones have individual specificities to all parts of the molecule (epitopes) and to other molecules that have contaminated the immunization preparation

Question 35

serum sickness

Answer 35

immune reaction (antibodies) to injected proteins causing a hypersensitivity reaction

*this is why you cannot use mouse monoclonals to treat humans unless B or T cells are eliminated

Question 36

chimeric monoclonal antibodies

Answer 36

constant regions: human
variable regions: from mouse monoclonal

“-ximab” drugs

Question 37

human monoclonal antibodies

Answer 37

totally made through molecular biology techniques

“-umab” drugs

Question 38

ELISA

Answer 38

*Enzyme-Linked InnumoSorbant Assay:

add an antibody to tube filled with antigen and incubate it, wash away unbound antibody, add second antibody with a covalently-bound enzyme and incubate it, wash away unbound antibody, detect amount of second antibody-enzyme complex by adding a chemical reagent that turns a certain color in its presence

Question 39

Immunofluorescence

Answer 39

used to identify a specific cell type, cellular structure or a pathogen through use of specific antisera, unbound antisera is washed away, a second antibody specific for the first antibody but with a fluorescent molecule is added and binds, the fluorescent molecule emits light when exposed to UV light which can be seen under a special microscope

Question 40

FACS

Answer 40

*Fluorescence Activated Cell Sorter- Flow Cytometry:

machine using lasers with multiple detectors that scan many cells for size and immunofluorescence detecting several antigens an creating a histogram (x-axis: intensity of fluorescence, y-axis: number of cells) and dot plot (top right: both positive, bottom left: both negative)

• cell sorters: analyzes and sorts based on amount of fluorescence
• flow cytometers: only analyze cells

Question 41

*Western Immunoblot

Answer 41

electrophoretical separation of mixtures of proteins which are bound to nitrocellulose paper, antibody binds to protein of interest, unbound antibodies are washed away, specific antibodies are detected like the ELISA assay providing information such as: amount of antigen (density of bands), molecular weight (how far bands travel), different forms of antigen

*quantitative and qualitative information

Question 42

Western Immunoblot

Answer 42

electrophoretically separated mixtures of proteins which are bound to nitrocellulose paper, antibody binds to protein of interest, unbound antibodies are washed away, specific antibodies are detected like the ELISA assay providing information such as: amount of antigen, molecular weight, different forms of antigen

Question 43

titer

Answer 43

how much you can dilute blood before loss of activity

Question 44

phases of antibody production in response to an antigen

Answer 44

1. lag/inductive/latent period
2. exponential increase in antibody concentration
3. steady state (peak antibody concentration is reached)
4. decay/decline: small amount of antibody is detected

Question 45

immunologic rememberance response

Answer 45

increase in affinity for IgG which persists in blood and response more quickly when the antigen presents itself again

Question 46

*toxin vs. toxoid

Answer 46

toxin: will kill you since the amount required for a response is lethal
toxoid: protein is chemically modified so it is antigenically the same but not lethal

Question 47

Hapten-Carrier

Answer 47

hapten: small molecule that cannot induce an antibody response on its own and is recognized by the B-cell
carrier protein: helps make hapten immunogenic and is recognized by the helper T-cell or B-cell

Question 48

Hapten-Carrier

Answer 48

hapten: small molecule that cannot induce an antibody response on its own and is recognized by the B-cell
carrier protein: helps make hapten immunogenic and is recognized by the helper T-cell or B-cell

Question 49

Antigen Presenting Cells (APC)

Answer 49

macrophages and dendritic cells which initiate the interaction with antigen by endocytosis or phagocytosis enhanced with a complement, pre-existing antibody or specific receptors through presentation of antigen as a small peptide (antigen/MHC complex) and a second/co-stimulatory signal (B7 antigen on presenting cell binds to CD28 on T-cell) critical for an immune response (B-cell or T-cell activation and proliferation)

Question 50

Antigen Presenting Cells (APC)

Answer 50

macrophages and dendritic cells which initiate the interaction with antigen by endocytosis or phagocytosis enhanced with a complement, pre-existing antibody or specific receptors through presentation of antigen as a small peptide

Question 51

what are two things essential for inducing immunity?

Answer 51

presentation of antigen AND co-stimulation

Question 52

what contributes to the loss of many T and B cell precursors

Answer 52

most rearranged genes won’t function which is the usual mechanism to bring about diversity in antigen receptors (rearrangement of small pieces of DNA)

Question 53

why does the concept of one gene one protein do not hold for immunoglobulin molecules?

Answer 53

they have a constant region and a variable region

• in the germ line, the constant regions are not next to the variable regions and there are different configurations for Ig gene material compared to the myeloma
• multiple Vs, Js and Ds (segments which proved that rearrangement occurs) are brought together by signal sequences from enzymes

Question 54

VJD segments of heavy vs. light chains

Answer 54

heavy chain: V (38-46), D (23), J (6)
light chain: V (34-38), J (5)

• of the two light chain possibilities (kappa and lambda), only one is kept active
• germline DNA undergoes somatic recombination for the segments to be joined (light- VJ joins; heavy- DJ then VDJ joins)

Question 55

how are V, D and J brought together?

Answer 55

enzymes (recombinase genes, RAG 1 and RAG 2) are induced in developing B-cells- signal sequences determine which segments can be joined through random, independent combinations

*RAG- grabs one end of the immunoglobulin and pulls it around and together causing a piece of DNA to be irreversibly discarded (section is cleaned and ligated)

Question 56

mechanism of the generation of junctional diversity (pay special attention to what TdT can do)

Answer 56

1. RAG complex cleaves the heptamer to yield DNA hairpins
2. RAG complex opens hairpins generating palindromic P-nucleotides
3. N-nucleotide additions by TdT/terminal deoxynucleotidyl transferase (random additions only in heavy chains of B-cells in the pro B stages until an overlap is achieved); repair enzymes repair
4. strands are paired
5. unpaired nucleotides are removed by an exonuclease
6. gaps are filled by DNA synthesis and ligation to form coding joint

***P (in all joining junctions) and N regions made at edit sites by the random additions by TdT may cause DNA to exceed reading frame and stop encoding for the correct AA (results in incorrect IgM which won’t be able to be inserted into the membrane)

Question 57

early pro-B cell to immature B cell

Answer 57

heavy chain rearrangement:
(early pro-B) D-J rearrangements on both chromosomes
(late pro-B) V-DJ rearrangement on first chromosome and if nonproductive, then on second chromosome and if nonproductive, then apoptosis

light chain rearrangement:
(pre-B) rearrange K gene on first chromosome and if nonproductive, then on second chromosome and if nonproductive, then lambda gene on first chromosome and if nonproductive, then on second chromosome and if nonproductive, then apoptosis (several changes to rearrange in light chain since heavy chain has already been successful in rearranging)

*immature B cell will express mu and K or mu and lambda signal when rearrangement has ended based on if a productive rearrangement was made with K or lambda gene in light chain rearrangement

Question 58

what causes the switch from IgM to IgD?

Answer 58

selective splicing of primary RNA transcripts made of both IgM and IgD constant regions

*splicing control also determines whether a cell synthesizes membrane bound Ig (2 extra exons) or secreted Ig

Question 59

**AID

Answer 59

*Activation-Induced Cytidine Deaminase

enzyme that attacks regions allowing for another editing inducing mutations and allowing section of DNA being cut and goes to gamma chain (causes mutations that produce antibody diversity)

• makes mutations DURING the immune response across DNA causing single base changes
• responsible for class switching and somatic hypermutation

Question 60

class switching

Answer 60

a variable region is joined to a new constant region (except in IgD) which brings about more diversity only with the help of T-cells and during an immune response

• since the variable region stays the same, class switching does not affect antigen specificity
• the antibody retains affinity for the same antigens, but can interact with different effector molecules
• daughter cells can produce antibodies of different isotypes

Question 61

somatic hypermutations

Answer 61

targets rearranged gene segments encoding the variable region (gives it the capability to respond to new threats- alters affinity)

*only in immune cells and not transmittable to offspring

Question 62

**B-cell vs. T-cell receptor formation

Answer 62

• most of the mechanisms for their formations are the same except T-cell receptor does not undergo somatic hypermutation
• also, T-cell will NOT change during the immune response

Question 63

regulation of T-cell proliferation in the thymus

Answer 63

T is selected for the elimination of strong self-reacting T-cells (tolerized to self antigens) which occurs in order to prevent autoimmune diseases (also related to transplantations)

• T-cells become MHC-restricted (peptide is presented by MHC molecule for TCR recognition) and lineage committed since the thymus provides the appropriate microenvironment
• selection occurs at several stages (positive and negative selection)

Question 64

what would a deficiency in RAG 1 or RAG 2 lead to?

Answer 64

inability to make T and B cells leading to immunodeficiency

Question 65

which MHC molecules do CD4 and CD8 lineage T ells recognize?

Answer 65

CD4- beta 2 of MHC II

CD8- alpha 3 of MHC I

Question 66

DiGeorge’s Syndrome

Answer 66

human T-cell immunodeficiency due to a loss of a TF required for thymic epithelial differentiation

Question 67

embryonic thymic development

Answer 67

thymus is formed from the fusion of the 3rd pair of pharyngeal pouch (endoderm) and the cleft (ectoderm)

Question 68

what are the major regions of the thymus and what happens with age?

Answer 68

regions: cortex, medulla and cortical-medullary junction

* function decreases as age increases

Question 69

migration of T-cells to and from the thymus

Answer 69

• T-cell precursors (prothymocytes which are not completely committed yet) leave the bone marrow and enter the thymus via blood vessels at the cortico-medullary junction
• mature T-cells leave the thymus and enter secondary lymphoid tissues (GALT, spleen, lymph node) through venules in the medulla
• chemokines and sphingosine 1-phosphate signal traffic for cell movement
• stage is identified by cell surface markers

Question 70

2 major lineages of T-cells

Answer 70

gamma:delta and alpha:beta

Question 71

fate of immature thymocytes

Answer 71

death by apoptosis if MHC is not recognized

Question 72

pre-T cell receptor

Answer 72

2 chains (heterodimer)–> heterodimer with itself (superdimer- more complex)–> signaling components (pre-T cell receptor)–> TCR

Question 73

synthesis of T-cell receptor alpha and beta chains

Answer 73

• alpha: alpha chain locus can sustain many attempts at a functional rearrangement (usage of upstream components to try and create a functional product)
• its rearrangement will always eliminate the linked delta-chain locus

-beta: two attempts can be made to achieve a productive rearrangement of the beta chain locus

Question 74

early T-cell development mechanism

Answer 74

progenitor cell–> proliferation–> double negative T cells commit to T lineage–> rearrange beta genes–(check-point for pre-TCR)–> proliferating double negative pre-T cells–> immature double-positive cells rearrange alpha genes–(checkpoint for TCR)–> mature double positive cells (FULLY FUNCTIONAL TCR)

*all steps occur in cortex except proliferation of progenitor cells which occurs in the medulla

Question 75

double positive thymocytes recognition of self peptides presented by MHC

Answer 75

receptor binds self-peptide:self-MHC class I--> CD8
receptor binds self-peptide:self-MHC class II--> CD4

Question 76

negative selection of alpha:beta T-cells

Answer 76

• by dendritic cells, macrophages and other cells in the thymus in which tight binding will initiate apoptosis and moderate binding allows the cell to live
• prevents too strong of a recognition

Question 77

ligands

Answer 77

self peptide/MHC complexes expressed on stromal and hematopoietic cells

• self peptides are derived from endogenous (self) sourcses
• Aire TF plays a key role in regulating the expression of some tissue specific antigens in medullary epithelial cells in the thymus

Question 78

engagement of the TCR by self-MHC:peptide complexes

Answer 78

can lead to either further maturation or to cell death

Question 79

Avidity model of T cell selection

Answer 79

depends on the affinity of the TCP-peptide/MHC interaction and the density of the peptide/MHC on the thymic epithelial cell

• avidity determines the total strength of signal delivered which dictates the outcome of the signaling event
• balance of avidity and signal intensity for positive selection whereas too much avidity= negative selection and too little will cause death by neglect

Question 80

**T-cell repertoire

Answer 80

sum of all of the specificities of the mature T cells produced by the thymus and this differs between individuals

*shaped by thymic selection and modified in the periphery throughout life by the encounters with antigens

Question 81

what is needed for suppression of autoreactive T cells by regulatory T cells?

Answer 81

interaction with the same antigen-presenting cell

*important for tissue tolerance

Question 82

what will activate the complement and classical pathways

Answer 82

pathogens–> complement

antibodies–> classical

Question 83

endotoxin

Answer 83

Structure: heat stable hydrophobic lipid rich end and hydrophilic polysaccharide rich end that is antigenic and is the determinant of the O antigen; epitope: 3-4 repeating monosaccharides

Function: produces the toxic LPS which resides in the Lipid A region (we know this since cleaving the polysaccharide from the lipid A will not affect the activity of the endotoxin) responsible for the body’s response to gram negative bacteria

Question 84

*gram negative sepsis

Answer 84

endotoxin shock/septic shock due to gram negative bacterial infection causing decreased BP and CO

• is the response to endotoxins
• high incidence of DIC (disseminated intravascular coagulation) causing thrombi (due to an enzyme cascade) and eventual depletion of coagulation factors which then causes hemorrhage and necrosis

Question 85

systemic introduction of LPS in low quantities and in high quantities

Answer 85

low: *fever, moderate immunostimulation which causes infiltration of neutrophils and macrophages along with increased vascular permeability and swelling
high: *fever, headache, vomiting, endotoxin shock (septic shock)

Question 86

acute respiratory distress syndrome

Answer 86

associated with septic shock or gram negative insult to the lungs

Question 87

why is LPS a pyrogen?

Answer 87

it causes fever

Question 88

assays used to make sure something is pyrogen-free

Answer 88

• USP rabbit pyrogen test

- LAL- Limulus Amebocyte Lysate

Question 89

pathway leading to survival after LOCAL infection with gram-negative bacteria

Answer 89

macrophages are activates and secrete TNF-alpha in tissue–> increased release of plasma proteins into tissue–> increased phagocyte and lymphocyte migration to tissue–> platelet adhesion to BV wall–> phagocytosis of bacterial–> vessel occlusion–> containment of infection–> antigens are carried to lymph nodes–> survival

Question 90

pathway leading to death after SYSTEMIC infection with gram negative bacteria (sepsis)

Answer 90

macrophages are activated in the liver and spleen to release TNF-alpha into blood–> systemic edema causes decreased blood volume, hypoproteinemia, neutropenia followed by neutrophilia–> decreased blood volume causes collapse of vessels–> organ failure/septic shock–> death

Question 91

mediators of the LPS response

Answer 91

outside the intact organism, LPS is not toxic

inside–> proteins (IL-1 and TNF-alpha) produced by LPS-stimulated macrophages serve as the endogenous mediator which induce blood vessels to become more permeable enabling effector cells and fluid containing soluble effector molecules to enter infected tissue causing inflammation at the site of infection

Question 92

cytokine effects

Answer 92

overlapping effects in the cell in which too much would be bad

Question 93

IL-1 beta and TNF-alpha

Answer 93

induce blood vessels to become more permeable enabling effector cells and fluid containing soluble effector molecules to enter infected tissue causing inflammation at the site of infection

Question 94

IL-6

Answer 94

makes heat by inducing fat and muscle cells to metabolize

Question 95

CXCL8

Answer 95

recruits neutrophils guiding them to infected tissue

Question 96

IL-12

Answer 96

activates NK cells that secrete cytokines strengthening the macophages’ response to infection

Question 97

tumor necrosis factor

Answer 97

induces intravascular coagulation and hemorrhage in the tumor serving as an immunoregulatory molecule while mediating inflammatory processes

*stimulates T and B cells along with inducing fevers just like IL-1

Question 98

anti-TNF-alpha antibodies

Answer 98

block the induction of shock induced by LPS

Question 99

TLR

Answer 99

toll-like receptors that bind signals inducing signal transduction pathways and production of cytokines

Question 100

what complex recognizes LPS?

Answer 100

the TLR4, MD2, CD14 complex which is them broken up by a cascade of P that then produces inflammatory cytokines

Question 101

what does TLR4 homodimer recognize?

Answer 101

gram-negative bacteria and is located on the plasma membrane of macrophages, dendritic cells, mast cells and eosinophils

Question 102

interleukin-1

Answer 102

cytokine that is secreted by activated and stimulated macrophages that is produces as a pro-cytokine and must be cleaved by caspase 1 (which is activated by the inflammasome) before being released

Question 103

inflammasome

Answer 103

inflammation sensitive complex that activates caspase 1

*target of anti-inflammatory drugs

Question 104

superantigen

Answer 104

binds to MHC class II and then T-cell receptor and CD28 in which activation occurs and the production of TNF alpha and IL 1 occur

Question 105

toxic shock syndrome

Answer 105

produced by staph aureus and causes fever, vomiting, diarrhea, shock and multi-organ dysfunction (due to mediators)