Exam 2

Question 1

somatic hypermutation

Answer 1

how entire V region is diversified after B cell activated by antigen, AID makes point mutations

Question 2

AID

Answer 2

activation-induced cytidine deaminase: converts cytosine to uracil and only active during B cell proliferation

Question 3

affinity maturation

Answer 3

when B cells that bind better to antigen are positively selected for

Question 4

IgM

Answer 4

first isotype made in primary immune response, secreted as a circular pentamer held by J Chain, strongly binds to antigen but limited in effector mechanisms thus need isotype switching

Question 5

switch regions

Answer 5

flanks the 5’ side of C genes

Question 6

isotype switching

Answer 6

involves recombination within cluster of C genes that removes a previously expressed C gene and brings a different one into its place

Question 7

Steps of Isotype Switching

Answer 7

1) initiation of transcription of C region
2) Targeting of AID of cytosines in switch region
3) Uracil is removed (abasic nucleotide)
4) endonuclease removes nucleotide and leaves a nick
5) nicks in both switch regions facilitate recombination
(takes place between u and any other C region or can happen sequentially)

Question 8

Hyper IgM immunodeficiency

Answer 8

patients lacking AID cannot undergo somatic hypermutation or isotype switching making them susceptible to pyogenic bacteria infection in sinuses, ears, lungs.

Question 9

Neutralizing antibodies

Answer 9

inactivate pathogen or toxin and prevent interaction with human cells

Question 10

Opsonizing antibodies

Answer 10

act as opsonins or complement activators - phagocytes have receptors for Fc component of antibody

Question 11

IgG

Answer 11

more flexible and can wave, rotate, wag, bend to increase chance of binding 2 antigens and effector molecules. Susceptible to proteolytic cleavage so there are subgroups that differ in hinge and heavy chain.

Question 12

IgG1

Answer 12

most protein antigen

Question 13

IgE

Answer 13

recruits effector functions of mast cells

Question 14

IgA

Answer 14

present at mucosal sufaces as dimeric form held together by J Chain. important in protecting mucosal surfaces and in total is most abundant antibody

Question 15

IgG2

Answer 15

repetitive carbohydrate antigens

Question 16

IgG3

Answer 16

best at complement activation

Question 17

IgG4

Answer 17

can exchange heavy-light chain dimer with another IgG4 (can only neutralize) - anti-inflammatory

Question 18

T Cell Receptors

Answer 18

beta chain like the heavy chain with VDJ and alpha chain like the light chain with VJ

Question 19

T Cell Receptor Function

Answer 19

only involved in antigen recognition, not effector function, mainly recognizes proteins.

Question 20

T Cell similarities to immunoglobulins

Answer 20

undergo rearrangement as well as junction diversity

Question 21

T Cell differences to immunoglobulins

Answer 21

there is only one C(alpha) and two functionally identical C(beta), never soluble

Question 22

Severe Combined Immunodeficiency Disease

Answer 22

rare disease where genetic defects result in absence of RAG proteins leading to lack of B and T lymphocytes. Babies die very quickly without immediate bone marrow transplant.

Question 23

Ommen Syndrome

Answer 23

missense mutation in RAG proteins that lowers activity

Question 24

Rage Genes and Evolution

Answer 24

Because RAG is essential in T and B development and without them babies die, RAG genes might be important in the evolution of adaptive immune systems. RAG genes don’t have introns and resemble the transposase gene of a transposon (mobile genetic element) which cleaves dsDNA

Question 25

Self vs Non Self

Answer 25

the power of adaptive immunity is from infinite possible binding sites on receptors but there is the potential to recognize self antigens

Question 26

Immunological Tolerance

Answer 26

when cells realize how to not attack the self - happens during lymphocyte development

Question 27

positive selection

Answer 27

T Cells are selected that have antigen receptors that work effectively with MHC class I and class II

Question 28

negative selection

Answer 28

T Cells that bind too strongly to self-MHC molecules die by apoptosis

Question 29

B Cell selection

Answer 29

B Cells are dependent of T cells for activation so negative selection still happens but isn’t as critical

Question 30

Regulatory T Cells

Answer 30

provide additional tolerance in peripheral tissues by being autoreactive to determine if other T cells are autoreactive

Question 31

Functional T-Cell Receptor

Answer 31

TCR must associate with four invariant proteins in order to make it to the cell surface (CD3 complex, zeta chain)

Question 32

CD3 complex

Answer 32

CDgamma, CDdelta, CDepsilon

Question 33

Invariant Protein Purpose

Answer 33

important in transmitting signal of antigen binding into the cells (similar to Igalpha and Igbeta in immunoglobulins)

Question 34

T Cell Receptor Classes

Answer 34

cand have alpha:beta or gamma:delta where a/g are similar and b/d are also similar.

Question 35

T Cell Receptor Classes Only One or Other

Answer 35

can have a:b T-cell receptors or g:d T-cell receptors, never both because the delta gene locus resides in the middle of the alpha chain locus so rearrangement of the alpha chain deletes the delta chain locus

Question 36

The enzyme responsible for both somatic hypermutation and aiding in isotype switching is

Answer 36

Activation-induced cytidine deaminase

Question 37

Antibodies that bind to a pathogen or toxin and inactivate the molecule preventing interaction with human cells are

Answer 37

neutralizing antibodies

Question 38

Each variable region of each T-Cell receptor subunit has how many hypervariable regions?

Answer 38

3

Question 39

Which of the following is not a component of the T Cell Receptor?

Answer 39

Ig(alpha)

Question 40

Which of the following is mismatched?

a. affinity maturation: isotype switching
b. surface immunoglobulin: B-cell antigen receptor
c. constant regions of antibodies: binding to complement proteins
d. activation-induced cytidine deaminase: somatic hypermuation
e. switch sequences: class switching

Answer 40

a) affinity maturation: isotype switching

Question 41

Which of the following is mismatched?

a. affinity maturation: isotype switching
b. surface immunoglobulin: B-cell antigen receptor
c. constant regions of antibodies: binding to complement proteins
d. activation-induced cytidine deaminase: somatic hypermuation
e. switch sequences: class switching

Answer 41

a)IgA

Question 42

Identify which of the following is not associated with activation-induced cytidine deaminase activity?

a) synthesized in prolifeating B cells during active immune responses
b) diversification of the Vh domain but not the Vl domain
c. somatic hypermutation
d. isotype switching
e. cytosine conversion to uracil

Answer 42

b) diversification of Vh domain but not the Vl domain

Question 43

In contrast to immunglobulins, T-cell receptors recognize epitopes present on antigens.

a. carbohydrate and protein
b. lipid
c. carbohydrate and lipid.
d. protein
e. carbohydrate

Answer 43

d. protain

Question 44

Which of the following characteristics is common to both T-cell receptors and immunoglobulins?

a. The antigen receptor is composed of two identical heavy chains and two identical light chains.
b. . Somatic recombination of V, D, and J segments is responsible for the diversity of antigen-binding sites
c. . Somatic hypermutation changes the affinity of antigen-binding sites and contributes to further diversification.
d. class switching enables a change in effector function
e. carbohydrate, lipid, and protein antigens are recognzied and stimulate a response

Answer 44

b. somatic recombination of V, D, and J segments is responsible for the diversity of antigen-binding sites

Question 45

How many hypervariable regions contribute to antigen-binding site in an intact T-cell receptor?

a. 12
b. 4
c. 6
d. 2
e. 3

Answer 45

c. 6

Question 46

In B cells, transport of immunoglobulin to the membrane is dependent on association with two invariant proteins, Ig and Ig. Which of the following invariant proteins provide this function for the T-cell receptor in T cells?

a. All of the given answers are correct
b. CD3gamma
c. CD3delta
d. CD3epsilon
e. zeta

Answer 46

all of them

Question 47

Antigen Processing and Presentation

Answer 47

TCR recognize peptide bound to MHC which requires antigen processing and antigen presentation

Question 48

Antigen Processing General

Answer 48

degradation of pathogen-derived proteins into peptides

Question 49

Antigen Presentation General

Answer 49

peptides are loaded onto MHC molecules and peptide:MHC complexes are displayed on cell surfaces where TCRs can recognize them

Question 50

MHC stands for

Answer 50

major histocompatibility complex

Question 51

MHC class 1 (general)

Answer 51

antigens from intracellular pathogens

Question 52

MHC class II (general)

Answer 52

antigens from extracellular pathogens

Question 53

Types of effector T cells

Answer 53

Cytotoxic T Cells and Helper T Cells

Question 54

Cytotoxic T Cells

Answer 54

intracellular infections, express CD8

Question 55

Helper T Cells

Answer 55

extracellular infections, express CD4

Question 56

T-Cell Co-Receptors

Answer 56

CD8 and CD4 allow effector T cells to recognize the correct MHC class molecules so T Cells will express a co-receptor but never both

Question 57

MHC class I cells

Answer 57

most cells express this because any cell can be infected

Question 58

MHC class II cells

Answer 58

only dendritic cells, macrophages, and B cells express this because they are professional phagocytes that attack extracellular pathogens

Question 59

CD8 on Cytotoxic T Cells

Answer 59

recognize MHC Class I presenting intracellular

Question 60

CD4 on Helper T Cells

Answer 60

recognize MHC class II presenting extracellular

Question 61

Cytotoxic T Cells funtion

Answer 61

main effector function is kill cells infected with pathogen

Question 62

Helper T cells function

Answer 62

main effector function is to help other cells respond to extracellular sources of infection (B cells and macrophages)

Question 63

MHC Class I Structure

Answer 63

transmembrane alpha chain, beta2-microglobulin (not encoded by gene in MHC)

Question 64

MHC Class II Structure

Answer 64

transmembrane alpha chain, transmembrane beta chain

Question 65

Peptide binding groove structure

Answer 65

peptide binding groove of both MHCs is formed by two immunoglobulin-like domains which are also important in co-receptor binding

Question 66

Promiscuous binding specificity

Answer 66

the peptide-binding site in an MHC can bind many different peptides

Question 67

MHC class 1 peptide binding groove constraints

Answer 67

MHC class I binds peptides of 8, 9, 10 amino acids and the last amino acid is usually hydrophobic or basic

Question 68

MHC class 2 peptide binding groove constraints

Answer 68

binds peptides of 13-25 amino acids (or longer)

Question 69

MHC class 1 Antigen Presentation General

Answer 69

1) intracellular pathogen produces proteins using cellular machinery
2) some proteins naturally degraded and transported to the ER where they can bind MHC class 1
3) MHC class 1 bearing peptide leaves the ER and moves to the cell surface
4) cytotoxic T cells that have the proper T cell receptor and CD8 can recognize the MHC class 1:peptide complex and kill the affected cell

Question 70

MHC class 1 Peptide Generation

Answer 70

intracellular pathogen uses cytoplasmic ribosomes to make protein but cells also have the proteasome. peptides are transported across ER membrane thought the protein TAP

Question 71

Proteasome

Answer 71

how normal cells break down cellular protein and if the cell is responding to INF-gamma, the proteasome will adopt a function of making MHC class 1 peptides

Question 72

TAP

Answer 72

transporter associated with antigen processing - lets MHC class 1 peptides into the ER

Question 73

MHC Class 1 Peptide Loading Complex

Answer 73

1) class I heavy chain is stabilized by calnexin until b2-microglobulin binds
2) calnexin is released. the heterodimer of class 1 heavy chain and b2m forms the peptide-loading complex with calreticulin, tapasin, TAP, and ERp57
3) a peptide delivered by TAP bind to the class 1 heavy chain forming the mature MHC class I molecule
4) the class I molecule dissociates from the peptide-loading complex, and is exported from the ER

Question 74

Calnexin

Answer 74

keeps MHC in ER until it is properly folded

Question 75

Peptide-loading complex

Answer 75

MHC class 1 binds b2m after calnexin and then incorporates with calreticulin, tapasin, TAP, and ERp57

Question 76

MHC Class 1 Peptide Trimming

Answer 76

1) MHC class 1 is loaded with peptide that is too long at the N terminus (but usually has correct carbody terminus)
2) ERAP removes N-terminal aa to give a peptide of 8-10
3) MHC class 1 molecule moves to Golgi and then plasma membrane

Question 77

ERAP

Answer 77

endoplasmic reticulum aminopeptidase

Question 78

Bare Lymphocyte Syndrome

Answer 78

non-functional TAP protein so antigen cannot get into the ER and there is a very poor CD8 responses

Question 79

Self-Peptides on MHC class I

Answer 79

These can also be presented but T Cell development prevents response

Question 80

MHC class II Antiger Presentation General

Answer 80

1) macrophage (or dendritic) engulfs and degrades bacterium, producing peptides
2) bacterial peptides bound by MHC class II in vesicles (endosome)
3) bound peptides transported by MHC class II to the cell surface
4) helper T cell recognizes complex of peptide antigen with MHC class II and activates macrophages

Question 81

Where MHC class II molecules are made

Answer 81

made in the secretory pathway, but they don’t meet antigen peptide until their vesicles from the Golgi fuse with endocytic vesicles

Question 82

Do MHC Class II get loaded in the ER?

Answer 82

NO but the MHC Class II molecules enter the secretory patheway and ER but don’t get loaded. Work through the invariant chain

Question 83

MHC class II molecules meeting antigen

Answer 83

1) MHC class 2 molecules are in ER
2) MHC class II alpha and beta chains associate with the invariant chain
3) invariant chain blacks binding of peptides to MHC class II molecules in the ER
4) In vesicles, invariant chain in cleaved, leaving the CLIP fragment
5) CLIP blocks binding of peptides to MHC class II in vesicles
6) HLA-DM facilitates release of CLIP, allowing peptides to bind

Question 84

CLIP

Answer 84

class II associated invariant chain peptide - cleaved from the invariant chain once the MHC class II moves to an endocytic vesicle from the ER

Question 85

HLA-DM

Answer 85

exchanges CLIP with a pathogenic peptide

Question 86

Cross-Presentation of Peptides

Answer 86

exogenous antigens can be presented via MHC class I molecules via cross-presentation

Question 87

Exogenous antigens

Answer 87

a forgein antigen like in allergy, transplant protein, taken in by breathing or eating etc

Question 88

When does Cross-presentation happen?

Answer 88

occurs when phagocytic cells engulf and infected and apoptotic cell and generated peptides are transproted to the ER but the mechanism is unknown.

1) phagocyte engulfs infected cell
2) phagolysosome produces antigens that go to the ER
3) present at class 1 but the vesicle also binds somehow

Question 89

How T Cells recognize the antigen on MHC

Answer 89

TCR makes contact with BOTH peptide and MHC molecule. The third hypervariable region of the TCR alpha and beta chains (most variable) make peptide contact while the first two hypervariable regions contact the MHC molecule

Question 90

Differential Expression of MHC Class I and Class II Molecules

Answer 90

virtually all cells express MHC class I (intracellular pathogens) but MHC class II are seen on cells of the immune system specialized for uptake, processing, and presentation of antigen (extracellular pathogen)

Question 91

The protein responsible for transporting intracellular pathogen peptides into the endoplasmic reticulum is:

a. CLIP
b. TAP
c. HLA-DA
d. ERAP

Answer 91

b. TAP

Question 92

CLIP, which binds to MHC class II molecule is derived from:

a. Calnexin
b. proteasome
c. HLA-DA
d. Invariant Chain

Answer 92

d. Invariant Chain

Question 93

Tapasin

Answer 93

a bringing protein that binds to both TAP and MHC class I molecules and facilitates the selection of peptides that bind tightly to MHC class I molecules

Question 94

The T-cell co-receptor CD4 interacts with bound to the surface of .

a. MHC Class II; antigen-presenting cells
b. MHC Class I; antigen-presenting cells
c. MHC Class I; T cells
d. MHC Class II; T cells
e. None of the answers given are correct

Answer 94

a. MHC Class II; antigen-presenting cells

Question 95

The degradation of pathogen proteins into smaller fragments called peptides is a process commonly referred to as:

a. antigen presentation
b. peptide loading
c. antigen processing
d. endocytosis
e. promiscuous processing

Answer 95

c. antigen processing

Question 96

Which of the following best describes the function of tapasin?

a. Tapasin is a bridging protein that binds to both TAP and MHC class I molecules and facilitates the selection of peptides that bind tightly to MHC class I molecules
b. Tapasin is an antagonist of HLA-DM and causes more significant increases in MHC class I than MHC class II on the cell surface
c. Tapasin is a lectin that binds to sugar residues on MHC class I molecules, T-cell receptors, and immunoglobulins and retains them in the ER until their subunits have adopted the correct conformation
d. Tapasin is a thiol-reductase that protects the disulfide bonds of MHC class I molecules
e. Tapasin participates in peptide editing by trimming the amino terminus of peptides to ensure that the fit between peptide and MHC class II molecules is appropriate

Answer 96

a. tapasin is a bridging protein that binds to both TAP and MHC class I molecules and facilitates the selection of peptides that bind tightly to MHC class I molecules

Question 97

Antigen processing involves the breakdown of protein antigens and the subsequent association of peptide fragments on the surface of antigen-presenting cells with

a. MHC class I or class II molecules
b. immunoglobulins
c. T-cell receptors
d. complement proteins
e. CD4

Answer 97

a. MHC class I or class II molecules

Question 98

Which of the following describes a ligand for an a:b T cell receptor?

a. peptide:MHC complex
b. carbohydrate:MHC complex
c. lipid:MHC complex
d. All of the complexes given are correct
e. None of the complexes given are correct

Answer 98

a. peptide:MHC complex

Question 99

MHC molecules have promiscuous binding specificity. This means that

a. a particular MHC molecule has the potential to bind to different peptides
b. when MHC molecules bind to peptides, they are degraded
c. peptides bind with low affinity to MHC molecules
d. None of the answers given describe promiscuous binding specificity

Answer 99

a. a particular MHC molecule has the potentail to bind to different peptides

Question 100

Which of the following removes CLIP from MHC class II molecules?

a. HLA-DM
b. HLA-DO
c. HLA-DP
d. HLA-DQ
e. HLA-DR

Answer 100

a. HLA-DM

Question 101

Human MHC

Answer 101

is called human leukocyte antigen complex (HLA) called HLA class I and HLA class II

Question 102

MHC Diversity Comes From?

Answer 102

Gene families and genetic polymorphism

Question 103

MHC gene families

Answer 103

multiple similar genes encoding the MHC chains

Question 104

MHC genetic polymorphisms

Answer 104

presence of multiple alternative forms of a gene in a population

Question 105

Isotype

Answer 105

product of different genes in MHC class I or II family

Question 106

Allele

Answer 106

different form of a gene

Question 107

Allotype

Answer 107

encoded protein from and allele

Question 108

MHC Class I Isotypes

Answer 108

HLA-A, HLA-B, HLA-C, HLA-E, HLA-G, HLA-F

Question 109

HLA-A, HLA-B, HLA-C

Answer 109

highly polymorphic, present antigen to CD8 T cells and are ligands for NK cells

Question 110

HLA-E and KLA-G

Answer 110

oligomorphic, ligands for NK cells

Question 111

HLA-F

Answer 111

unknown function but intracellular

Question 112

MHC Class II Isotypes

Answer 112

HLA-DP, HLA-DQ, HLA-DR, HLA-DM, HLA-DO

Question 113

HLA-DP, HLA-DQ, HLA-DR

Answer 113

highly polymorphic, present antigen to CD4 T Cells

Question 114

HLA-DM, HLA-DO

Answer 114

oligomorphic, involved in peptide loading of class II

Question 115

HLA Class II and I Gene Complex

Answer 115

Consists of about 4 million base paris on chromosome 6 with three regions in order Class II Region, Class III Region, Class I Region

Question 116

Class I Region

Answer 116

HLA class I genes and nonfunctional class I gene fragments

Question 117

Class II Region

Answer 117

HLA class II genes and nonfunctional class II gene fragments

Question 118

Class III Region

Answer 118

separates class I and Class II with other genes

Question 119

HLA Gene complex notation

Answer 119

Remember class II has and alpha and beta chain so genes are A and B (HLA-DMA or HLA-DMB). If there is more than one gene, and number is added to the end (HLA-DQA1 or HLA-DQA2)

Question 120

Haplotype

Answer 120

combination of HLA alleles - over human history HLA genes have been recombined to thousands of haplotypes - combination of different haplotypes through inheritance means that million of different HLA combinations are represented

Question 121

HLA-DR Subdivisions

Answer 121

There is one single HLA-DRA gene, but there are 4 different genes encoding the HLA-DR beta chains(DRB1, DRB3, DRB4, DRB5). So DRB1 is present on every chromosomes 6 and can be the only one expressed and there are 3 other types of chromosome 6 that carry either DRB3, DRB4, or DRB5 in addition in DRB1.

Question 122

HLA class II region genes

Answer 122

almost entirely dedicated to genes involved in antigen processing: HLA alpha and beta chains, TAP, subunits of proteasome that are induced by interferons

Question 123

Interferons

Answer 123

involved in coordinately regulating genes involved in antigen presentation and processing (HLA class I heavy chains, b2m, TAP, proteasome subunites)

Question 124

INF-gamma

Answer 124

coordinates expression of HLA class II genes and invariant chain genes through the action of the trascriptional acitvator C2TA

Question 125

C2TA

Answer 125

MHC class II transactivator

Question 126

Impaired C2TA

Answer 126

can lead to bare lymphocyte syndrome where class II molecules are not made and CD4 cells cannot function

Question 127

MHC Polymorphism

Answer 127

highly polymorphic can differ by 1-50 amino acids but substitutions are mainly in domains that bind peptide and interact with T cell receptor but not all contact residues are different

Question 128

Peptide binding groove variations

Answer 128

determines the type of peptide that can bind but certain positions, most have the same or similar amino acid (anchor residue)

Question 129

Peptide-binding motif

Answer 129

combinations of anchor residues that bind to a particular MHC isoform

Question 130

MHC Restriction

Answer 130

antigen-specific T Cell response is restricted by the MHC type. The most diverse aa in MHC molecules is located in the surfaces that the TCR bind. So both the MHC type and antigen have to match the TCR for binding to occur.

Question 131

MHC Diversity

Answer 131

driven by natural selection from pathogen infections. AA substitutions are concentrated at sites of peptide binding in a nonrandom way. Polymorphisms can provide different peptide-binding specificity

Question 132

Heterozygote advantage

Answer 132

high degree of polymorphism of HLA isotypes ensures that most of the population are heterozygotes since they can more pathogens

Question 133

balancing selection

Answer 133

processes that act to maintain a variety of MHC isoforms in a population where successive epidemics make homozygotes die

Question 134

directional selection

Answer 134

during a specific, epidemic disease exposure, certain MHC isoforms are selected for

Question 135

Generation of new MHC Alleles

Answer 135

quick rate of pathogen adaptation to MHC molecules, likely suggests rare MHC allels that have not been adapted for are selected for and new variants can form by point mutation, recombination, interallelic conversion

Question 136

Interallelic Conversion

Answer 136

recombination in which segment of one allele has been replaced by a homologus section of another

Question 137

HIV/AIDS

Answer 137

MHC heterozygosity has been shown to provide a selective advantage to AIDS progression in people infected with HIV

Question 138

Autologous

Answer 138

how self-MHC isoforms are described

Question 139

Allogenic

Answer 139

how foreign MHC isoforms are secribed

Question 140

Alloreactive T Cells

Answer 140

In every individual, these T cells can respond to peptide and allogeneic MHC molecules from cells of other healthy individuals which is a problem for transpants

Question 141

HLA Type

Answer 141

need to be similar or identical HLA alleles to avoid alloreaction

Question 142

Alloantibodies

Answer 142

made during pregnancy from natural alloreaction if the mother’s immune system is stimulated by the HLA molecules n the fetus from the father. Not a danger to fetus but cna be a problem is mom need transpalnt in future.

Question 143

The term used to describe the expressed protein of a certain gene is:

a. allele
b. allotype
c. haplotype
d. isotype

Answer 143

b. allotype

Question 144

Foreign MHC molecules are referred to as

a. autologous
b. interallelic
c. allogenic
d. haplotypes

Answer 144

c. allogenic

Question 145

Six Phases of B-Cell Development

Answer 145

Repertoire assembly (acquiring of functional immunoglobulins), negative selection, positive selection, circulation of mature B cells, B-Cell activation, B-Cell effector functions (stem cells make 60 billion new b cells a day)

Question 146

B-Cell Development in Bone Marrow

Answer 146

pluripotent hematopoitic stem cells have DC34, give rise to common lymphoid progenitor cell (CD34 and CD10), B-Cell Precursor (CD34, CD10, CD127), pro-b-cells are begining of B cell lineage (CD34, CD10, CD127, CD19)

Question 147

Pro-B-Cell Stage

Answer 147

rearrangement of the heavy-chains first occurs between D and J gene (early pro-b-cell stage) and then between V and the rearranged DJ (late pro-b-cell stage). Then transcription occurs through the u C-region gene making pre-b-cells

Question 148

Pre-B-Cell Stages

Answer 148

Large pre-b-cell (not yet rearranging light chain) and small pre-b-cell (rearranging of light chain has begun)

Question 149

Stromal Cells

Answer 149

stromal cells of the bone marrow provide a microenvironment for b-cell development by making specific contacts with developing B cells and produce growth factors that act on attached b cells (SCF and IL-7)

Question 150

Nonproductive Rearrangement

Answer 150

when rearrangment of the heavy chain in pro-b-cell is imprecise and ineffecience so the addition of N and P nucleotides can change the reading frame. If this happens from both heavy chain loci then the b cell will die.

Question 151

Productive Rearrangement

Answer 151

gives rise to function immunoglbulin chain from correct rearrangment of the heavy chain in pro-b-cells. Requires RAG1 and RAG2 which are activated by E2A and EBF trx factors

Question 152

surrogate light chain

Answer 152

VpreB and gamma5 produced by the b cell to act as a temporary light chain to test the functionality of the pro-b-cell u heavy chain

Question 153

Pre-B-Cell Receptor

Answer 153

in the ER the u heavy chain assembles with the surrogate light chain and Iga and Igb to make this. must be functional in order to transition to pre-b-cell stage

Question 154

Allelic Exclusion

Answer 154

ensure only one functional immunoglobulin in made for strong interactions with multivalent antigens. how pre-b-cell receptor prevent more than 1 u chain. once one is made RAG gene trx stops, RAG degrades, chromatin remodles to prevent gene rearragment

Question 155

Light Chain Rearrangment in Pre-B-Cells

Answer 155

large pre-b-cells divide into small pre-b-cells that don’t make b-cell receptor, RAG reactivate, rearragment of light happens one locus at a time between V and J, 4 loci (2 kappa 2 delta) 85% success, functional IgM shuts down further recombination.

Question 156

Checkpoints of B Cell Development

Answer 156

make sure functional heavy/light since recombo ineffective.
1) formation of pre-b-cell receptor
2) formation of functional b-cell receptor.
If no pass, apoptosis.

Question 157

What drives B Cell development?

Answer 157

Protein expression. RAG only active when rearrangement occurs. Tdt expressed during heavy chain rearrangment (why only 50% light chain genes have N nucleotide), Iga and Igb always expressed (important in allelic exclusion and functional IgM)

Question 158

How does protein expression change for B cell development?

Answer 158

Transcription factors! Required for rearrangement of RAGs, E2A EBF, Pax-5 (binds enhancer regions to begin trascription)

Question 159

B-Cell Tumors

Answer 159

Because there is lots of cutting, splicing, mutating DNA. Often from translocation of an immunoglobulin gene with a different chromosome

Question 160

Typical B-Cell Tumor Translocation

Answer 160

between immunoglobulin and proto-oncogene (MYC on chrom 8 and BCL2) Ig on Chrom 14

Question 161

CD5 Expression on B Cells

Answer 161

only on subset of B cells that arise during embryonic development and don’t go through these 6 phases of b cell development

Question 162

B Cells with CD5

Answer 162

B-1 cells or called CD5 B Cells (CD5 usually on T cells)

Question 163

Polyspecificty

Answer 163

allows antibodies produced by B-1 cells to be of lower affinity and thus binds multiple antigens that are typically specific to carbohydrate antigens

Question 164

Adult B-1

Answer 164

maintain population of B-1 cells through division as no new ones are made in bone marrow

Question 165

The surrogate light chain is made up of what two proteins?

a. VpreB and lambda5
b. CD34 and CD5
c. E2A and EBF
d. RAG-1 nad RAD-2

Answer 165

a. VpreB and lambda5

Question 166

What is the main function of pro-b cell development

a. expression of CD5
b. heavy chain rearrangement
c. isotype switching
d. light chain rearrangement

Answer 166

b. heavy chain rearragement

Question 167

Negative Selection of B Cells

Answer 167

repertoire assembly can make self reactive immunoglobulins that recognize self antigen and immature B cells are programmed to generate negative signals if bind to self antigen resulting in apoptosis or inactivation

Question 168

Beginning of Negative Selection

Answer 168

begins in bone marrow where multivalent self-antigens present on stromal cells, hematopoiteic cells, and blood plasma macromolecules prevent B cells from leaving the bone marrow

Question 169

B-Cell Receptor Editing

Answer 169

if immature B cell is multivalent self reactive IgM, IgM expression decreases while RAG continues to allow for further light chain rearrangment. If a new light chain occurs, it can assemble with the old heavy chain to hopefully make new, functional immunoglobulin. Then can leave bone.

Question 170

Clonal Detection

Answer 170

cell death by apoptosis if new light chains cannot rearrancge with nonfunctional heavy chains to make a good immunoglobulin in B cell

Question 171

B-Cell Anergy

Answer 171

inactivation of immature b cells with monovalent self-reactive IgM (doesn’t go through editing or apoptosis).

Question 172

Anergenic B Cells

Answer 172

make IgD and IgM but the IgM cannot assemble on cell surface and the IgD receptors don’t signal activation upon antigen binding. will circulate blood for 1-5 days (normal 40 day half life)

Question 173

Central Tolerance

Answer 173

Three ways B cells can become self-tolerant - receptor editig, death of multivalent self-reactive B cells by apoptosis, anergy of monovalent self-reactive B cells

Question 174

Peripheral Tolerance

Answer 174

Because not all self antigen is in bone marrow, b cells can also die by apoptosis or become anergic if they encounter self antigens in peripheral tissues

Question 175

Autoimmune Response

Answer 175

Caused by B cells that react to self antigens that are inaccessible to B cells (intracellular molecules)

Question 176

B Cell Maturation General

Answer 176

1) immature B cells produce high levels of IgM and low levels of IgD but that flops when mature
2) maturation requires immature b cells to migrate to secondary lypohid tissues
3) in lymphoid tissue, chemokines are secreted by stromal cells (CCL21) and dendritic cells (CCL19) to attract B cells
4) B cells migrate to primary lymphoid follicle that contains dendritic follicular cells (CXCL13)
5) in primary follicle, maturation of B cells occurs to produce naive B cells (not yet exposed to antigen)

Question 177

B Cell Differentiation

Answer 177

1) B cell encourters antigen keeps the b cell in the t-cell area of the lymphoid tissue to become activated by CD4 T Cells
2) B cell activation causes proliferation and some plasma cell differentiation (antibodies)
3) other activated b cells move to germinal cells to mature into centrocytes
4) centrocytes can migrate to other lymphoid tissue or marrow to become plasma cell (isotype switched antibodies)
5) come germinal center B cells will develop into memory b cells (isotype switch antibodies)

Question 178

centrocytes

Answer 178

dividing B cells that have undergone isotype switching and somatic hypermutation)

Question 179

B Cell Tumor Origin

Answer 179

every cell has an identical rearranged immunoglobulin so they divide from same ancestral cell, but tumors from different patients have different immunoglobulins

Question 180

B Cell Tumors and Development

Answer 180

Tumors corresponding to all stages of b cell development have been described and their location at defined sites in lymphoid tissue is maintained

Question 181

follicular center cell lymphoma

Answer 181

grow in follicles of lymph nodes

Question 182

myeloma

Answer 182

grow in bown marrow

Question 183

hodgkin’s disease

Answer 183

germinal center b cell origin

Question 184

The genetif recombination of immunoglobulins that produces a monovalent self-reactiv IgM causes what mechanism to be activated:

a. receptor editing
b. anergy
c. apoptosis
d. clonal deletion

Answer 184

b. anergy

Question 185

centrocytes are dividing B cells that:

a. immeduately produce soluble IgM and IgD antibodies
b. function as memory cells in a secondary immune response
c. are self-reactive and need to be inactivated through anergy
d. produce antibodies that have matured through isotype switching and somatic hypermutation

Answer 185

d

Question 186

T Cell Precursor

Answer 186

what a:b and g:d T cells develop from in the thymus

Question 187

Thymocytes

Answer 187

immature T cells - develop among epithelial cells known as the thymic stroma

Question 188

Thymus Development

Answer 188

Fully developed before birth and starts to degrade at 1 years old but this nor a thymectomy grossly affects T Cell immunity because repertoire of T cells is long lived and or self-renewing

Question 189

Thymocyte development

Answer 189

progenitor cells that enter thymus not yet committed, needs interaction with thymic stromal cells to cause division and differentiation. After 1 week prodenitors express CD2 and are committed thymocytes

Question 190

Double-negative (DN) thymocytes

Answer 190

thymocytes that express CD2 and are committed to becoming T cells, but do not express TCR or a co-receptor

Question 191

Notch 1

Answer 191

cell-surface receptor on thymocytes that interacts with thransmembrane ligands on thymic epithelial cells and keeps thymocytes on road to T cell

Question 192

Notch 1 Activity

Answer 192

it is inactive when bound to membrane, binding of the extracellular domain causes cleavage, release of intracellular domain, which acts as trascription factor in nucleus.

Question 193

T Cell Lineages

Answer 193

either a:b or g:d and happens through complex process where b,g,d all start to rearrange at the same time and there is a competition.

Question 194

Double-positive (DP) thymocytes

Answer 194

occurs when functional b is made first and incorporated into a pre-t-cell receptor and rearrangment stops so both co-receptors are expressed. Race between g, d, and a begins.

Question 195

pTalpha

Answer 195

The surrogate chain to test if productive or nonproductive rearrangment of b chain happened.

Question 196

if g:d t cell rearranges frist

Answer 196

the g:d dimer forms and assembles with CD3 to form a functional receptor and b chain rearrangement stops

Question 197

productive b chain in T-cell

Answer 197

if b can bind to pTalpha, it complexes with CD3 and zeta to form pre-t-cell-receptor which acts as superdimer)

Question 198

superdimer

Answer 198

both a receptor and ligand

Question 199

Pre-T Cell

Answer 199

thymocytes that make functional pre-t-cell receptor that is a superdimer that activates signals to move through checkpoint

Question 200

rearrangement of alpha chian gene

Answer 200

pre-T-cell receptor stops rearrangement by suppressing RAG, allelic exlusion at the b chain locus, pre-t cell proliferates and expressed CD4 and CD8 makeing DP Thymocytes, large DP proliferate into small DP, rearrangment reactivates to target a, g, d. alpha chain has multiple attmepts.

Question 201

Delta Locus

Answer 201

situated in the middle of the alpha locus, will be deleted after alpha chain rearrangement thus stopping g:d rearrangment

Question 202

Gene expression during T Cell Development

Answer 202

First part of a:b development includes CD4, CD8, T-cell receptor. RAGs only expressed during b and a rearrangments.

Question 203

ZAP-70 and Lck

Answer 203

important signaling molecules that are expressed for most of T cell development

Question 204

Trascription factors in T cell development

Answer 204

Ikaros and GATA-3 which are expressed through whole development. Th-POK is needed fo rCD4 T Cell development and is activated later.