B Cell Development Pt 2 PDF

Summary

This document is a set of lecture notes or an outline on B cell development, discussing different types of B-cells, their properties, and the process of B-cell maturation in the bone marrow. Some figures and diagrams are included.

Full Transcript

WELCOME!
BMS 545 IMMUNOLOGY
OCTOBER 28, 2024
ANNOUNCEMENTS

 Any shift in exam material/course
structure will be posted to Canvas!
 OBJECTIVES

 Compare and contrast B1 & B2 lineages, their roles, functions, locations, etc.
 Compare and contrast subtypes of T and B cells in terms of development, roles, activation, etc.
 Describe what happens with B cell negative & positive selection & the consequences of “passing” or “failing” each
 Compare and contrast T & B cell positive and negative selection
 What is the significance of a B cell binding a multivalent vs. monovalent self antigen? Are there any corrective
measures?
 What is receptor editing?
 Describe the movement of B cells to secondary lymphoid tissue
 Outline the parts of secondary lymphoid tissue where B cells travel. What is the role of these areas?
 What happens to B cells that encounter their antigen? What happens to B cells that DON’T encounter their
antigen?
 The development of B cells in the bone marrow
6-9 B cells expressing the cell-surface protein CD5 have a distinctive
repertoire of receptors- These cells are known as B1 cells
Figure 6.14 Comparison of the properties of B-1 cells and B-2 cells

 A pool of self-renewing B-1 cells is
established & does not require the
microenvironment of BM for its
survival
 B-1 cells make antibodies that have
low diversity, weak binding, &
polyspecificity, properties suggesting
that B-1 cells produce simpler, less
adaptive immune responses than
those of B-2 cells
PARALLELS & DIFFERENCES OF TRANSITIONAL & ADAPTIVE B-CELL &
T-CELL LINEAGES
 B1 B-CELLS

 B-1 B cells- arise from fetal liver by 8th gestational week (early in embryogenesis)
 Described ~20 years ago, important in innate-related immunity & autoimmune dis.
 Possibly a transitional lymphocyte that bridges innate & adaptive immune
systems?
 Slight immunologic memory, limited isotype switching, & limited repertoire
 B-1 cell repertoire < B-2 cell repertoire
 BCRs & antibodies often directed against conserved microbial antigens (e.g. LPS)
 Found predominantly in tissues that are potential portals of microbial entry (e.g.,
the peritoneal cavity & respiratory tract) & are self-renewing
 Most (maybe all???) natural antibodies (e.g. IgMs directed against A & B blood
groups that exist in the absence of known immunization) are B-1 origin
 B2 CELLS

 B-2 cells (Conventional B cells) arise during & after the neonatal period, &
are widely distributed throughout lymphoid organs & tissues
 Continually replaced from the bone marrow throughout adult life
 Require interaction with T cells for activation & proliferation
 Range of epitopes that can be recognized by B-2 B cells is vast
 Upon repeated antigen exposure, B-2 B cells respond quickly with increased
antibody quantity & quality often by “fine-tuning” affinity of antibody
produced (aka affinity maturation)
 Responses are often accompanied by a change in immunoglobulin isotype
(aka isotype switching)
 All of these properties are hallmarks of immunologic memory
REVIEW OF LAST CLASS

 List the 6 phases of functional B cell development and what occurs during each phase
 Selection and further development of the B-cell repertoire
6-10 The immature B-cell population is purged of cells bearing self-
reactive B-cell receptors

T cell vs B cell Positive & Negative selection
T cells undergo positive selection, THEN negative selection, B cells undergo negative selection,
THEN positive

T cells are positively selected based on their ability to bind to self MHC molecules, while B
cells are positively selected based on their ability to bind antigen directly

T cells are negatively selected to remove those T cells that bind self MHC TOO strongly, while
B cells undergo negative selection to eliminate self-reactive cells
Figure 6.16 Immature B cells with specificity for multivalent self antigens are retained in the bone marrow

 Immature B cells that are not
specific for a self antigen in bone
marrow are permitted to continue
their maturation
 They have IgM AND IgD on their surface
& leave the bone marrow
 Immature B cells that recognize a
self antigen on bone marrow cells
are retained in the bone marrow
Selection and further development of the B-cell repertoire
6-11 The antigen receptors of autoreactive immature B cells can be
modified by receptor editing
Figure 6.17 Receptor editing rescues many self-reactive B cells by changing their antigen specificities (Part 1)

 Binding to a multivalent self antigen in bone marrow causes immature
B cell to continue light-chain gene rearrangements
 This deletes the gene encoding self-reactive light chain- creates
possibility of gaining a new light-chain rearrangement & a B-cell
receptor that does not react with a self antigen
 Successive rearrangements occur until either a new non-self-reactive
receptor is made OR the B cell exhausts its supply of light-chain V or J
gene segments
Figure 6.17 Receptor editing rescues many self-reactive B cells by changing their antigen specificities (Part 2)

 IF a light chain is made that does not confer self-reactivity, the B cell
is rescued & continues its development (lower right panels), but IF a
B cell runs out of rearrangements & is still self-reactive, it dies by
apoptosis (lower left panels)

 Receptor editing is unique to B cells
Selection and further development of the B-cell repertoire
6-12 Immature B cells that recognize monovalent self antigens are
made nonresponsive

Univalent = monovalent
REVIEW OF LAST CLASS

 List the 6 phases of functional B cell development and what occurs during each phase
Figure 6.23 Summary of the main stages in B-cell development (Part 2)
Selection and further development of the B-cell repertoire
6-13 Maturation and survival of B cells occurs in lymphoid follicles
Figure 6.19 The general route of B-cell circulation through a secondary lymphoid tissue

 B cells circulating in the blood enter the
lymph-node T-cell areas via a high
endothelial venule (HEV)
 Then they pass into a primary lymphoid
follicle
 IF the B cells do not encounter their
specific antigens, they leave the follicle &
exit from the lymph node in the efferent
lymph

 The circulation route is the same for
immature and mature B cells, which all
compete with each other to enter
primary follicles
Figure 6.20 Immature B cells must pass through a primary follicle in a secondary lymphoid tissue to become
mature B cells

 Immature B cells enter the secondary lymphoid tissue through the walls of high endothelial venules (HEVs), attracted by chemokines CCL21
& CCL19, & compete with other immature & mature B cells to enter a primary follicle (PF)
 Follicular dendritic cells (FDCs; turquoise) secrete chemokine CXCL13, which attracts B cells into the follicle
 Immature B cells that enter a follicle interact with cell-surface components of FDCs that can signal B cells’ final development into mature B
cells
 Immature B cells that fail to enter a follicle also continue in recirculation but soon die
 Mature B cells that do not encounter their specific antigens in follicle leave the lymph node & continue recirculating through secondary
lymphoid tissues via lymph & blood
 BAFF, B cell–activating factor in the TNF family; LT, lymphotoxin
Selection and further development of the B-cell repertoire
6-14 Encounter with antigen leads to the differentiation of activated B
cells into plasma cells and memory B cells
Figure 6.21 Antigen-mediated B-cell activation and differentiation in secondary lymphoid tissue

 A mature naive B cell enters the lymph node
through an HEV
 In the T-cell area of the lymph node, the B
cell encounters antigen delivered in the
afferent lymph draining from infected tissue
 At the boundary between a lymphoid follicle
& T-cell area, the B cell is activated by a CD4
helper T cell (blue) to form a primary focus
of dividing cells
 Some of these B cells migrate to the
medullary cords & differentiate into
antibody-secreting plasma cells; others
migrate to a primary follicle & form a
germinal center where they further divide &
differentiate
 B cells from germinal center migrate either
to the medullary cords OR to bone marrow
to complete maturation into plasma cells
 ALSO SCIENTIST
Deborah Doniach, MD FRCP
This
Photo
by
1912-2004, Professor of Clinical Immunology
Unknow
n Born in Geneva, Switzerland, on April 6th, 1912 to Russian Parents. After
Author
is having two children with her husband, she resumed her studies at the
license
d under
Royal Free Hospital Medical School in London, graduating in 1945.
CC BY-
NC-ND Dr. Doniach received additional training in Immunopathology and
Endocrinology, and joined the Department of Immunology at Middlesex
Hospital in the 1960s and eventually became Honorary Consultant
Immunopathologist. In 1974 she became Professor of Clinical
Immunology.
She partnered with chemist and immunologist Ivan Roitt and they
discovered that Hashimoto’s thyroiditis is an autoimmune disease in
which antibodies target thyroglobulin. They also found a separate
antibody cytotoxic to thyrocytes, which targets thyroid peroxidase.
Their new findings contradicted the current scientific belief at the time,
that antibodies targeted only nonself antigens. Thus, their work and
findings pioneered the field of research into thyroid autoimmunity and
autoimmune diseases.