Lymphocyte genetics and clonal expansion of B cells Flashcards

Question 1

Q

What is the role of B cells in the immune system?

Answer

A

produce antibodies that can bind to any potential antigen.

Question 2

Q

How does the immune system achieve diversity in antibody production?

Answer

A

V(D)J recombination where variable (V), diversity (D), and joining (J) gene segments are randomly mixed in developing B cells, leading to a vast array of unique antibodies.

Question 3

Q

Do B cells require antigens for their initial development?

Answer

A

No, B cell development is antigen-independent. B cells undergo V(D)J recombination and develop in the bone marrow before they have encountered an antigen

Question 4

Q

How is the specificity of B cells determined?

Answer

A

defined by genetic rearrangement during its development. Each B cell produces a unique antibody that defines its specificity

Question 5

Q

What is clonal selection in the context of B cells?

Answer

A

natural process by which a B cell with an antibody that successfully binds to an antigen is selected for. This B cell then proliferates, producing a clone of cells that all produce the same antibody specific to the antigen.

Question 6

Q

What is the “one cell-one antibody” rule?

Answer

A

Each B cell produces only one type of antibody. Each B cell clone will target a specific antigen.

Question 7

Q

What determines the specificity of B cell antigen receptors?

Answer

A

unique genetic mechanism during lymphocyte development in the bone marrow, creating millions of different receptor gene variants.

Question 8

Q

clonal selection theory

Answer

A

B cell progenitor gives rise to many pre-B cells, each with a unique specificity. Self-reactive pre-B cells are removed by clonal deletion, while specific immature B cells proliferate and differentiate when activated.

Question 9

Q

How does the immune system deal with self-reactive B cells?

Answer

A

Self-reactive B cells are altered or eliminated through a process called clonal deletion to prevent autoimmunity.

Question 10

Q

What are the two stages of B cell development?

Answer

A

maturation phase, where stem cells become mature naïve B cells, and a differentiation phase, where mature B cells become plasma cells or memory B cells upon antigen activation

Question 11

Q

What are the three main goals of B cell development?

Answer

A

Generate a diverse array of antigen-binding receptors. 2. Alter or eliminate self-reactive B cells. 3. Promote the maturation of foreign-reactive B cells.

Question 12

Q

What happens to B cells after an antigen is eliminated?

Answer

A

specific B cells that were activated and proliferated form memory B cells, which remain in the body to provide a rapid response to future encounters with the same antigen.

Question 13

Q

How do B cells achieve diversity in their antigen receptors?

Answer

A

genetic rearrangement during their development in the bone marrow, a key part of clonal selection

Question 14

Q

What are the antigen-independent in B cell development?

Answer

A

occurs in the bone marrow during maturation.

Question 15

Q

What are the antigen-dependent phases

Answer

A

Occurs in peripheral lymphoid organs, where B cells differentiate after encountering an antigen.

Question 16

Q

What is shown in the maturation phase of the B cell development diagram?

Answer

A

transition from stem cell to mature naïve B cell, which is antigen-independent and occurs in the bone marrow.

Question 17

Q

What is the differentiation phase in B cell development?

Answer

A

antigen-dependent and occurs in the secondary lymphoid organs, where activated mature B cells become either antibody-secreting plasma cells or memory B cells.

Question 18

Q

Why is diversity in antigen receptors crucial for B cells?

Answer

A

BCR must recognize a vast array of potential antigens, so genetic rearrangements create a diverse pool of BCRs, each with a different specificity.

Question 19

Q

What is clonal deletion in the context of B cell development?

Answer

A

Clonal deletion is the process by which potentially self-reactive pre-B cells are removed to prevent the immune system from attacking the body’s own tissues.

Question 20

Q

What is clonal deletion in the context of B cell development?

Answer

A

process by which potentially self-reactive pre-B cells are removed to prevent the immune system from attacking the body’s own tissues.

Question 21

Q

When do specific immature B cells proliferate and differentiate?

Answer

A

Upon encountering their specific antigen and receiving necessary co-stimulatory signals, activated specific immature B cells proliferate and differentiate into effector cells.

Question 22

Q

What is the role of memory B cells?

Answer

A

persist after an antigen has been eliminated, providing a quicker and more robust response upon re-exposure to the same antigen.

Question 23

Q

What is the purpose of genetic rearrangement in B cells?

Answer

A

ensures that each B cell has a unique receptor, contributing to the immune system’s ability to recognize an immense variety of antigens.

Question 24

Q

How is the specificity of B cell receptors (BCRs) determined?

Answer

A

specificity of BCRs is defined by genetic rearrangements that occur during B cell development in the bone marrow.

Question 25

Q

What are the two main processes in B cell development?

Answer

A

maturation phase where B cells achieve immunocompetence, and differentiation phase where they become specialized effector cells.

Question 26

Q

What triggers the activation of naïve B cells?

Answer

A

when their receptors bind to a specific antigen and they receive co-stimulatory signals, leading to their proliferation and differentiation

Question 27

Q

SLO

Answer

A

secondary lymphoid organ

Question 28

Q

what is the maturation phase characterized by

Question 29

Q

What happens to naive B cells upon encountering an antigen?

Answer

A

enter the antigen-dependent phase (activation and differentiation), where they interact with T helper cells in peripheral lymphoid organs.

Question 30

Q

What are the possible outcomes for an activated B cell?

Answer

A

undergo class switching, affinity maturation, become plasma cells secreting antibodies, or develop into memory B cells.

Question 31

Q

What processes enhance B cell effectiveness?

Answer

A

Class switching changes the antibody isotype produced, and affinity maturation increases the antibody’s ability to bind to the antigen.

Question 32

Q

What percentage of activated B cells survive to become effector cells?

Answer

A

10% survive, with the majority (~90%) undergoing cell death if they do not successfully undergo class switching or affinity maturation.

Question 33

Q

What is the role of memory B cells after the elimination of an antigen?

Answer

A

provide long-term immunity by responding more quickly and effectively upon re-exposure to the same antigen.

Question 34

Q

What are the stages of B cell development in the bone marrow?

Answer

A

Stem cell, early pro-B cell, late pro-B cell, large pre-B cell, small pre-B cell, immature B cell.

Question 35

Q

What marks the successful development of B cells in the bone marrow?

Answer

A

The successful generation of functional B cell receptor (BCR) expression, specifically IgM.

Question 36

Q

The successful generation of functional B cell receptor (BCR) expression, specifically IgM.

Answer

A

Heavy chain (H-chain) and Light chain (L-chain) bonded together by disulfide bridges.

Question 37

Q

What are the two types of regions found in H-chains and L-chains?

Answer

A

Constant region and variable region

Question 38

Q

Constant region on H and L-chains

Answer

A

determines the antibody subclass

Question 39

Q

Variable region on H and L-chains

Answer

A

determines antigen-binding affinity

Question 40

Q

Describe the heavy chain loci

Answer

A

V, D, and J gene segments

Question 41

Q

Describe the light chain loci

Answer

A

κ locus includes V and J segments, and the λ locus has multiple V and J segments.

Question 42

Q

What is the V(D)J rearrangement process in B cells?

Answer

A

process of somatic recombination that creates the variable region of the immunoglobulin heavy and light chains, generating the unique antigen-binding site of each B cell’s receptor.

Question 43

Q

What happens during the D-J rearranging stage of B cell development?

Answer

A

DJ, gene segments of the heavy chain (H-chain) undergo recombination. This is the first step in the variable region gene rearrangement.

Question 44

Q

What is the V-DJ rearranging step in B cell development?

Answer

A

Following D-J recombination, a V gene segment is joined to the D-J complex in the late pro-B cell stage, completing the rearrangement for the heavy chain locus.

Question 45

Q

What indicates the completion of heavy chain rearrangement in B cell development?

Answer

A

successful VDJ recombination of the heavy chain genes is confirmed in the large pre-B cell stage, allowing for the expression of the μ chain as part of the pre-B cell receptor on the cell surface

Question 46

Q

After heavy chain rearrangement, what is the next step for the light chain genes?

Answer

A

light chain genes begin their rearrangement with the V to J joining in the small pre-B cell stage, preparing the light chains to pair with the heavy chain.

Question 47

Q

What completes the immunoglobulin light chain gene rearrangement?

Answer

A

completion of the VJ rearrangement allows for the full assembly of the light chain, which can then pair with the heavy chain to form a functional B cell receptor.

Question 48

Q

When is immunoglobulin first expressed on the B cell surface?

Answer

A

Once both heavy and light chain rearrangements are complete, the B cell receptor, primarily IgM, is expressed on the surface of the immature B cell, indicating readiness for antigen encounter.

Question 49

Q

Main IgG subclasses

Answer

A

IgA, IgG, IgM, IgE and IgD

Question 50

Q

IgD function

Answer

A

antigen receptor on B cells that have not been exposed to antigens.

Question 51

Q

IgE Function

Answer

A

Binds to allergens and triggers histamine release from mast cells and basophils, and is associated with allergy and defense against parasitic infections.

Question 52

Q

IgM

Answer

A

First antibody to be produced in response to an antigen, primary activator of the complement system.

Question 53

Q

IgA subclasses and functions

Answer

A

IgA1: (most abundant) found in various secretions such as saliva and tears.
IgA2: More resistant to proteases and predominant in mucosal areas like the gut.

Question 54

Q

IgG subclasses (1-2)

Answer

A

IgG1: Most abundant IgG subclass in serum, effective in opsonization and complement activation.
IgG2: Responds mainly to polysaccharide antigens.

Question 55

Q

IgG subclasses (3-4)

Answer

A

IgG3: Has a high affinity for antigens and can effectively activate complement.
IgG4: Does not activate complement and is involved in response to repeated exposure to antigens (e.g., allergies).

Question 56

Q

The μ (mu) chain (heavy chain)

Answer

A

pairs with a surrogate light chain (made up of VpreB and λ5 proteins) and the signaling components Igα and Igβ to form the pre-BCR.

Question 57

Q

Heavy chain functions

Answer

A

Large protein chains - contribute to antibody size and shape

Question 58

Q

Light chain function

Answer

A

Smaller protein chains

Question 59

Q

Constant regions in antibodies

Answer

A

decide antibody class and whether they are soluble or membrane-bound

Question 60

Q

Variable antibody region

Answer

A

antibody’s unique antigen-binding specificity

Question 61

Q

What processes contribute to the vast diversity of antibodies

Answer

A

Combinatorial diversity (VDJ),
Junctional diversity,
Pairing of different heavy and light chains,
Somatic hypermutation

Question 62

Q

Junctional diversity

Answer

A

Additional diversity is introduced at the junctions during the recombination process.

Question 63

Q

Somatic hypermutation

Answer

A

After antigen stimulation, mutations in the V regions can increase the affinity of the antibody for its antigen.

Question 64

Q

In what order do gene rearrangements occur for antibody production?

Answer

A

The heavy chain VDJ is rearranged first, located on chromosome 14.
Light chain rearrangement follows, with the kappa chain on chromosome 2 or the lambda chain on chromosome 22.
The first functional antibody produced is always IgM, expressed on the surface of immature B cells as part of the BCR.

Answer 64

A

kappa chain on chromosome 2, lambda chain on chromosome 22.

Answer 65

A

Pseudogenes= non-functional gene segments within immunoglobulin loci that cannot produce a protein. They reduce evolutionary pressure by providing a reservoir of genetic material that can potentially evolve new functions.

Answer 66

A

Conserved non-coding DNA sequences that guide the recombination of gene segments in antibody genes. They consist of a conserved heptamer, a non-conserved spacer, and a conserved nonamer, and are crucial for the correct joining of gene segments.

Answer 67

A

same=looping out and deletion of the intervening DNA occur. opposite orientations= the coiled region is retained in the DNA in an inverted orientation.

Answer 68

A

RAG1/RAG2 complex recognizes and binds to RSS.
Ku70:Ku80 forms a ring around the DNA, associating with the DNA-PKcs to form DNA-PK.
Artemis with nuclease activity cleaves DNA.
DNA ligase IV:XRCC4 joins the DNA ends.

Answer 69

A

Requirement that a 12-nucleotide spacer RSS can only be joined to a 23-nucleotide spacer RSS, ensuring diverse yet accurate recombination of immunoglobulin gene segments.

Answer 70

A

variable (V), diversity (D, for heavy chains only), and joining (J) gene segments come together.

Answer 71

A

RAG1 and RAG2

Answer 72

A

A variable length sequence of either 12 or 23 nucleotides (hence the 12/23 rule) that provides the physical space between the heptamer and nonamer.

Answer 73

A

9 nucleotides, providing a binding site for the RAG complex.

Answer 74

A

7 nucleotides, recognized by recombination activating genes (RAG) during V(D)J recombination

Answer 75

A

contribute to junctional diversity in the antigen-binding sit- more common in heavy-chain V-D and D-J junctions than in light-chain junctions.

Answer 76

A

terminal deoxynucleotidyl transferase (TdT)

Answer 77

A

L-chain genes can rearrange multiple times.
This flexibility allows B cells to try different light-chain combinations to express a functional BCR if the first rearrangement is nonproductive.

Answer 78

A

Combinatorial diversity arises from different V(D)J gene segment combinations.
Junctional diversity results from the addition of P and N nucleotides at gene segment junctions.

Answer 79

A

created when the hairpin structures at the coding ends of gene segments are opened during V(D)J recombination.

Answer 80

A

cells can fail to produce a functional receptor at both the heavy-chain and light-chain gene rearrangement stages.
Cells that fail to rearrange successfully are typically eliminated, ensuring only functional B cells proceed to maturation.

Answer 81

A

Rearrangements happen one chromosome at a time to prevent simultaneous productive rearrangements on both chromosomes, which would reduce diversity.
This sequential process ensures that if a productive rearrangement occurs, the other chromosome’s rearrangement is halted.

Answer 82

A

V(D)J recombination does not produce a viable coding sequence for BCR, rearrangement fails at L(less as is rearranged multiple times) or H-chain, B cells that produce a receptor that binds too strongly to “self” antigens.

Answer 83

A

process during B cell development where only B cells with correctly formed and non-self-reactive BCRs are allowed to mature and survive.

Answer 84

A

Eliminates B cells that have failed to produce a functional BCR or that react with self-antigens, preventing autoimmunity.

Answer 85

A

Ensures that B cells with functional, non-self-reactive BCRs continue their development into mature B cells.

Answer 86

A

stops further heavy-chain gene rearrangement and triggers the B cell to enter the cell cycle.
Ensuring allelic exclusion and progression to light-chain gene rearrangement.

Answer 87

A

Allelic exclusion ensures that each B cell expresses only one specificity of antibody, preventing the expression of different receptor types on the same cell, which would complicate antigen recognition.

Answer 88

A

Completed all V(D)J rearrangements and express surface IgM. They have a short lifespan and must check for autoreactivity before maturing and leaving the bone marrow.

Answer 89

A

Surface IgM+ B cells are an indication that the B cell has successfully produced a functional BCR. However, these cells are also tested for self-reactivity to prevent autoimmunity.

Answer 90

A

B cells are tested for binding to self-antigens. Those that bind strongly to self-antigens undergo apoptosis, a process known as negative selection, to prevent autoimmune reactions.

Answer 91

A

BCR binds with high affinity to a self-antigen present in the bone marrow, this signals that the B cell may be autoreactive = negative selection (apoptosis)

Answer 92

A

allowing self-reactive B cells to change their specificity by rearranging their light-chain genes, starting with the kappa (κ) locus and potentially moving to the lambda (λ) locus.

Answer 93

A

maturation in the bone marrow, where B cells express IgM as a signal to leave, and IgD to transition to secondary lymphoid organs (SLO). The V region of the B-cell receptor remains unchanged through these stages

Answer 94

A

B cells can produce IgM or IgD through alternative splicing of the primary transcript of the B-cell receptor gene. This process allows B cells to switch the type of antibody they express without changing the specificity for the antigen.

Answer 95

A

Newly produced B cells leave the bone marrow and enter the circulation to survey for antigens in secondary lymphoid organs (SLOs).

Answer 96

A

B cells can become low-affinity plasma cells producing IgM antibodies in a T cell-independent manner within a few days of antigen recognition

Answer 97

A

Isotype switching is a process that occurs after interaction with helper T cells, leading to the production of different classes of antibodies beyond IgM, typically within 1-2 weeks.

Answer 98

A

Isotype switching is a process that occurs 1-2 weeks after antigen recognition where B cells change the class of antibody they produce, such as from IgM to other isotypes like IgG, IgA, or IgE.

Answer 99

A

B cells undergo somatic mutation and affinity maturation over several weeks, leading to the production of high-affinity plasma cells and memory B cells.

Answer 100

A

These processes result in the selection of B cells that produce high-affinity antibodies, which are crucial for effectively neutralizing antigens and providing long-term immunity.

Answer 101

A

High-affinity plasma cells secrete large amounts of specific antibodies, while memory B cells persist in the body, providing a rapid and effective response upon re-exposure to their specific antigen

Answer 102

A

Somatic hypermutation is a high rate mutation process that occurs only after antigen activation and requires T cell signaling. It typically takes place in germinal centers.

Answer 103

A

T helper cells when CD40 ligand (CD40L) on the T cell binds to CD40 on the B cell.

Answer 104

A

IL4 and IL5, IFN y, TGF-B- they affect AID to induce mutations

Answer 105

A

This process can lead to the production of B cells with either improved antigen affinity, referred to as affinity maturation, or non-functional receptors due to random mutations.

Answer 106

A

expressed upon B cell activation and targets actively transcribed genes. It modifies cytidine bases to uridine in single-stranded DNA, which can then be processed by DNA repair mechanisms.

Answer 107

A

Class switching involves genetic rearrangement of the C-region of the H-chain, allowing B cells to produce different classes of antibodies (like IgG, IgA, etc.) instead of IgM.

Answer 108

A

aids B cells to undergo somatic hypermutation and class switching, essential for the maturation process and the generation of high-affinity antibodies.

Answer 109

A

Involved in class switching to IgA and IgG2b in mice, and has a regulatory role in the immune system.

Answer 110

A

Specific regions within the variable regions of Ig heavy and light chains that directly contact antigens. These regions show high variability, determining the unique specificity for antigens.

Answer 111

A

Complementarity Determining Regions

Answer 112

A

provide the structural support for the CDRs, helping to maintain the overall structure of the antibody’s variable regions.

Answer 113

A

refer to different classes of heavy or light chains within the same host (e.g., IgM, IgG), while allotypes are genetic variants within the constant regions of antibodies, differing between individuals of the same species.

Answer 114

A

Mismatch repair enzymes identify and repair the mismatches created by AID, which can result in additional mutations further diversifying the antibody genes.

Answer 115

A

ensuring that each B cell expresses an antibody with a unique specificity. Through gene rearrangement, only one allele of the heavy or light chain gene is productively rearranged and expressed, preventing the expression of the other allele.

Answer 116

A

The process by which B cells in the germinal centre of lymph nodes increase the affinity of their antibody for the antigen.

Answer 117

A

different classes of immunoglobulins (e.g., IgM, IgG) within the same species

Answer 118

A

genetic variants within the constant regions of antibodies among different individuals

Answer 119

A

unique antigen-binding sites determined by the variable regions of the antibodies.

Answer 120

A

In somatic hypermutation, AID converts cytosine to uracil in DNA. UNG removes the uracil, leaving an abasic site.

Answer 121

A

cuts the DNA at this site, creating a single-strand break.

Answer 122

A

initiates the error-prone repair process that introduces mutations into the variable regions of immunoglobulin genes, increasing antibody diversity.

Answer 123

A

After AID activity, mismatch repair enzymes recognize and repair the uracils paired incorrectly with other DNA bases, often introducing errors. These mutations can result in a variety of outcomes, including transitions or transversions. The process enhances the diversity of antibodies, enabling a more effective immune response.

Answer 124

A

purine replaced by another purine or a pyrimidine by another pyrimidine

Answer 125

A

purine replaced by a pyrimidine or vice versa

Answer 126

A

Class switching is initiated by the enzyme AID in response to signals from T helper cells, including CD40 ligand interaction and cytokines such as IFN-γ for IgG class switching, or IL-4 for IgE class switching.

Answer 127

A

repetitive DNA sequences located upstream of the constant regions of the heavy chain immunoglobulin genes. They are the sites where class switch recombination occurs, changing the antibody class that a B cell produces without altering the specificity for the antigen.

Answer 128

A

RNA-DNA hybrid structures formed during transcription of the immunoglobulin gene. They serve as substrates for AID, leading to mutations and recombination events necessary for class switching.

Answer 129

A

Allele, thereby producing antibodies with a single specificity. This process prevents the expression of immunoglobulin genes from both alleles of a chromosome, maintaining the monospecificity of antibodies.

Answer 130

A

Transcription through the switch region forms R-loop structures that expose single-stranded DNA, which serves as a substrate for AID. This leads to double-strand breaks in DNA, initiating the recombination process that results in class switching.

Answer 131

A

Enzymes like DNA-PK and others involved in DSBR are essential for re-joining the DNA ends after class switching, ensuring the integrity of the genome and the successful change of the antibody class.

Answer 132

A

double-strand break repair

Answer 133

A

RNA-DNA hybrid structures known as R-loops.

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Lymphocyte genetics and clonal expansion of B cells Flashcards

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