Lec 4: Basics of Cell-to-Cell communication

Question 1

How do immune cells communicate at a distance

Answer 1

Secretion fo proteins, hormones. Note here that concept of diffusion applies

Question 2

Classes of Cytokine effects

Answer 2

soluble secreted proteins that act in an autocrine or paracrine manner

Pleiotrophy

Redundancy

Synergy

Antagonism

Question 3

Pleiotrophy

Answer 3

induced varied responses in the target cell

Question 4

Redundancy

Answer 4

different cytokines induce the same response

Question 5

Synegry

Answer 5

cytokines cooperate in inducing a specific response

IFN for example (multiple can converge and boost a given signal)

Question 6

Antagonism

Answer 6

cytokine blocks the activity of another cytokine

Question 7

Why is the diversity of cytokine folds important

Answer 7

many conformations implies

different diffusion rates

different specificities

different regulators

Question 8

what do cytokines depend on

Answer 8

transcription factors, signalling protiens present and epigenetic effects

Question 9

why are cytokines benificial

Answer 9

for modulation of the immune response

Question 10

Why is the redundancy of cytokines important

Answer 10

incase on cytokine does not work, we can maintain and immune response even with a partial loss

can boost a given signal (this is a synergistic effect and coordination)

cross talk

Question 11

Why is antagonism important

Answer 11

what to dampen the signal at the end

also allows different tissues to react in different ways (reversal of immune response)

Question 12

Can a single cytokine bind to multiple receptors

Answer 12

yes

Question 13

what are the 5 classes of cytokine receptors

Answer 13

Ig-type ectodomain

TNF homotrimeric ectodomain

Cytokine Type 1 receptors (core ectodomain), can have other domains

Cytokine TYpe 2 receptors (core ectodomain), can have other domains

Chemokine receptors (typical and atypical)

Question 14

Paracrine vs autocrine

Answer 14

Paracrine signaling: a cell targets a nearby cell (one not attached by gap junctions). The image shows a signaling molecule produced by one cell diffusing a short distance to a neighboring cell. Autocrine signaling: a cell targets itself, releasing a signal that can bind to receptors on its own surface.

Question 15

Paracrine vs Autocrine

Answer 15

Paracrine signaling: a cell targets a nearby cell (one not attached by gap junctions). The image shows a signaling molecule produced by one cell diffusing a short distance to a neighboring cell. Autocrine signaling: a cell targets itself, releasing a signal that can bind to receptors on its own surface.

Question 16

IL2 and IL15

Answer 16

IL2 and IL15 are essential cytokines mediating cell proliferation (IL2 is especially important in clonal expansion)

Question 17

STAT5

Answer 17

STAT5 binds genes associated with cell proliferation, apoptosis, differentiation and inflamation

big driver of proliferation and apoptosis

Question 18

How do antigen presenting cells change the flavour// activate a given T-cell

Answer 18

In this order

MHC
CO-stimulation (additional signal cascades)
Cytokine secretion

Question 19

How are chemokines classified

Answer 19

divided into subfamilies on the basis of the presence of as conserved cysteine motif in their mature sequenses

are folded together by cysteine bridges

Question 20

Pleiotrophic effects of chemokines

Answer 20

Extensive ligand promiscuity in the chemokine receptor family, and many chemokines can bind to multiple receptors

Question 21

classes of chemokines

Answer 21

C
CC
CXC
CX3C

see slides for diagram

Question 22

Typical chemokine receptors

Answer 22

containing a seven-transmembrane domain

G protein-coupled chemotactic receptors

conserved DRYLAIV motif (AA sequence)

cell migration

Question 23

Atypical chemokine receptors (ACKRs)

Answer 23

predicted seven transmembrane domain structure

do not signal through G proteins and lack chemotactic activity

substitutions in the DRYLAIV domain

Signalling via beta-arrestin leads to chemokine internalization

Question 24

What is the purpose of beta-arrestin signaling

Answer 24

Signaling via beta-arrestin leads to chemokine internalization = ANTAGONISM

ligand scavenging and degredations

chemokine trafficking

control inflammatory and immune responses

Question 25

nomenclature for typical chemokines receptors

Answer 25

CCL and CXCL

Question 26

nomenclature for Atypical chemokines receptors

Answer 26

ACKR

Question 27

how do atypical chemokine receptors help control infammation

Answer 27

they help to trap excess chemokine

erythrocytes can act as a buffer for excess serum chemokines

protection against excessive cytokine storms or chronic inflammation

Question 28

Viruses can usurp cytokine signalling

Answer 28

some viruses encode protiens that mimic host cytokines, chemokines and their receptors

Viral mimics do not have sequence similarity to host proteins, yet possess similar function

Question 29

what do you notice about the types of chemokines herpesviruse mimics

Answer 29

immunosupression

IL6 reduces the inflammatory response and chemokine signalling

Question 30

Viralkines

Answer 30

Mimics cytokine, chemokine, or chemokine receptors

interupt, mimic or distrupt host signalling cascades

Ep-barr secretion of IL10 to suppress adaptive and innate immune responses

Question 31

What kind of extracellular signals do cells use do communicate

Answer 31

Secretion of cytokines// proteins as well as hormones to induce immunocompetent (diffuses into cells)

The can also secrete exosomes

Question 32

Extracellular vesicles

Answer 32

delivery of bioactive macromolecules

enclosed in a lipid bilayer, variable composition

can enhance or supress immune activites

Question 33

Why are extracellular vesicles so important when it comes to cell signalling

Answer 33

They contain a ton of information abot the cell that secreted them

Surface markers, DNA, proteasome etc…

Question 34

What are the two types of extracellular vesicles

Answer 34

exosomes and microvesicles

Question 35

How does loss of integrety// secreation// membrane blebbing occur?

Answer 35

increase in temperature, and infection, toxins high osmotic stress etc

Question 36

Necrosis// Necrotic Cell Death

Answer 36

aka cell lysis NOT apoptosis (dis is more violent)

membrane rupture makes apoptotic blebbs which are little packets that may be degraded

huge inflamatory response

Question 37

Apoptotic bodies

Answer 37

Small little fragments to be eaten by macrophages

Cell contents not released, no inflamatory response

contain valuable information about the cells death

Question 38

Biogeneisis of exosomes

Answer 38

A modified endosome, the intracellular components of these can be controlled

Derived from MBV (multivesicular bodies) which fuse with the plasma membrane and release intraluminal vesicles as exosomes

30-100nm

Question 39

Biogenesis of microvesicles

Answer 39

generated from budding from the plasma membrane

lil scoops of a sample of the cytoplasm

30-2000nm

Question 40

Dendridic cells and Extracellular vesicles

Answer 40

Dendritic cells may engulf important anitgens or signalling moleucles then secreate them in extracellular vesicles to a variety of immune cells

may lead to inflammatory responses and or immune cell activation

Question 41

Diffusion of PRR to other cell types

Answer 41

activation of other non-infected cells

super important in exosomes

Question 42

Exosome secretion during infection

Answer 42

exosomes containing antigens derived from pathogens can helpp activate the imune system through PAMPs and cross-priming DC antigen presentation

also can have immunosuppressive effects

Question 43

Group cytokines and chemokines based on their strucutre and receptors

Answer 43

Chemokines:
cysteine bridges in 4 groups, C, CC, CXC and CX3C chemokines which can bind to either typical or atypical receptors. Chemokines exhibit extreme promiscuity when it comes to their receptors (they can often bind many)

Cytokines:
Conformationally very different which lead to variations of specificity, difffusion and regulation. They bind to 5 different types of receptors (Ig-type, TNF homotrimeric, Cytokine type 1, cytokine type 2, chemokine). Usually again, a given cytokine can bind multiple receptors

Question 44

Compare and contrast the actions of cytokines and chemokines

Answer 44

A chemokine is a cytokine that specificaally induces motility towards a site of inflamation

Question 45

Explain the importance of Cytokine-based communication in terms of pleiotrophy

Answer 45

here communication is important because pleiotrophy of target cell means different cells with respond differently to a given cytokine.

This is due top variations of a cells given receptors, epigenetics, proteasome, transcription factors, and constituents of the signal transduction cascade

Question 46

Explain the importance of Cytokine-based communication in terms of redundacy

Answer 46

Redundancy is important because just incase their is a mutation, or infection or simply the cell doesn’t have a given receptor the end result will still get triggered

issa good back up plan

Question 47

Explain the importance of Cytokine-based communication in terms of Synergy

Answer 47

Coordination, and cooperation and crosstalk to boost signals

for example, IFN signals boost each other

Question 48

Explain the importance of Cytokine-based communication in terms of antagonism

Answer 48

Imporant when you want to silence a cascade before it gets out of control or simply because you dont what that signal in a given cell type or tissue

Question 49

What is the importance of extracellular vesicles in immune communication and signalling

Answer 49

Allows a “controlled” diffusion of lysed cell components among the blood stream or lymph to activate immune cells (this is jsut one example = a dendritic cell).

membrane vesicles give a good idea of what happened at a given site of infection.

Question 50

MAPK

Answer 50

A mitogen-activated protein kinase is a type of protein kinase that is specific to the amino acids serine and threonine. MAPKs are involved in directing cellular responses to a diverse array of stimuli, such as mitogens, osmotic stress, heat shock and proinflammatory cytokines