Antibody Structure and Function PDF

Summary

This document, titled "Antibody Structure and Function", Chapter 5, presents an overview of antibody structure, function, and related topics. It covers the preamble, chapter overview, antibodies, and mechanisms of antibody action, including complement fixation and neutralization.

Full Transcript

ANTIBODY STRUCTURE AND FUNCTION
CHAPTER 5
PREAMBLE

 PowerPoints are a general overview and are provided to help students take
notes over the video lecture ONLY.
 PowerPoints DO NOT cover the details needed for the Unit exam
 Each student is responsible for READING the TEXTBOOK for details to
answer the UNIT OBJECTIVES
 Unit Objectives are your study guide (not this PowerPoint)
 Test questions cover the details of UNIT OBJECTIVES found only in your
Textbook!
CHAPTER OVERVIEW

General
Structure of Immunologic
characteristics of Antibody classes
immunoglobulins memory
antibodies

Antibody
Immunoglobulin Monoclonal
specificity and
genes antibodies
diversity
ANTIBODIES

 Are immunoglobulins
 Glycoproteins found in the serum
 82% to 96% polypeptide and 2% to
14% carbohydrate
 Five major classes: IgG, IgM, IgA, IgD,
IgE
 Are the key element of the humoral
immune response
ANTIBODIES (CONTINUED)

 Appear primarily in the gamma (γ) globulin
band with serum electrophoresis at pH 8.6
 TETRAPEPTIDE STRUCTURE OF
IMMUNOGLOBULINS
 Basic four-chain
polypeptide
 Two large peptide chains =
heavy (H) chains
 Two small peptide chains =
light (L) chains
 Held together by
noncovalent forces and
disulfide interchain bridges
 Heavy chains

Denoted by Greek letters for each Ig
class (e.g., Gamma [g] for IgG)

HEAVY AND Light chains — two types
LIGHT Kappa (κ)
CHAINS Lambda (λ)
Have a molecular weight of ~22,000
daltons and differ by just a few amino
acids
Found in all five classes of Igs but only
one type is present in a single molecule
 TETRAPEPTIDE STRUCTURE OF
IMMUNOGLOBULINS (CONTINUED)

 Unique variable region (amino-
terminal end) allows for specific
binding to a particular antigen.
 Three to four constant regions
(carboxy-terminal end) are
responsible for biological functions
of antibody.
HINGE REGION
 Segment of H chain between
the CH1 and CH2 regions
 Allows for flexibility
 Two antigen-binding sites can
operate independently
 Assists in initiation of
complement cascade and Fc
receptor binding
CARBOHYDRATE
PORTION OF IGS

 Found in all classes of
immunoglobulins
 Localized between the CH2
domains of the two H chains
 Increases the solubility of
immunoglobulin
 Provides protection against
degradation
 Enhances functional activity of the
Fc domains
TREATMENT OF IG WITH PAPAIN

 Two Fab fragments
 One L chain plus one-half of an H chain held
together by S=S
 Contains antigen-binding sites
 One Fc fragment
 The carboxy-terminal halves of two H chains held
together by S=S
 Important in effector functions of Igs
TREATMENT OF IG WITH PEPSIN

 Pepsin cleaves the Ig above the set of
disulfide bonds that hold the heavy
chains together
 F(ab’)2 created
 Contains two antigen-binding sites held
together
 Fc’ portion in nonfunctional pieces
ISOTYPES, ALLOTYPES, AND IDIOTYPES

Amino acid sequences in immunoglobulins that are antigenic determinants

Can react with antibodies produced by immunization of heterologous species
ISOTYPES

 Unique amino acid sequences
common to all Igs of a given class
or subclass
 Identical in all individuals of a
species and differ between species
 Located in constant regions of
heavy chains and are denoted by
Greek letters for each Ig class: IgG:
γ chain, IgM: μ chain, IgA: α chain,
IgD: δ chain, IgE: ε chain
ALLOTYPES

 Minor variations of amino acid
sequences that are present in
some individuals of the same
species but not others
 Located in the constant regions
of the IgG subclasses, one IgA
subclass, and the l light chain
IDIOTYPES

 Variations in variable regions that
give individual antibody molecules
specificity
 Located in amino terminal regions of
heavy and light chains
THREE-DIMENSIONAL STRUCTURE OF
ANTIBODIES

 Peptides folded into compact globular
subunits stabilized by intrachain disulfide
bonds.
 Creates a cylindrical structure called an
immunoglobulin fold, which captures antigen.
 Antigen binds to hypervariable regions
containing CDRs.
MECHANISMS OF ANTIBODY ACTION

Complement fixation is the main mechanism used against
cellular antigens
Antibodies bound to cells change shape and expose
complement binding sites
This triggers complement fixation and cell lysis
Complement activation:
Enhances the inflammatory response
Uses a positive feedback cycle to promote phagocytosis
Enlists more and more defensive elements
MECHANISMS OF ANTIBODY ACTION

 Neutralization – antibodies bind to and block specific sites
on viruses or exotoxins, thus preventing these antigens from
binding to receptors on tissue cells
 Agglutination – antibodies bind the same determinant on
more than one antigen
 Makes antigen-antibody complexes that are cross-linked
into large lattices
 Cell-bound antigens are cross-linked, causing clumping
(agglutination)
 Precipitation – soluble molecules are cross-linked into large
insoluble complexes
Figure 20.13
IGG

Predominant immunoglobulin in humans (70%–75% of total serum
immunoglobulin)

Longest half-life of any immunoglobulin (23 days)

Monomer with a molecular weight of 150,000 daltons and a sedimentation
coefficient of 7S

Four subclasses: IgG1: 66%, IgG2: 23%, IgG3: 7%, IgG4: 4%
  Have slight differences in constant region amino acid
sequences
 Differ in number and position of disulfide bridges
between the γ chains
 Differ in functions
IGG
SUBCLASSES
IGG SUBCLASSES

IgG1 and IgG3
Produced in response to protein antigens

IgG3
Has the largest hinge region
Has the largest number of interchain disulfide bonds
Is the most efficient at binding complement
IgG2 and IgG4
Are involved in responses to polysaccharide antigens
Have shorter hinge segments
Are poor mediators of complement activation
MAJOR FUNCTIONS OF IGG

 Binding to complement
 Leads to inflammation and destruction of foreign cells
 IgG3 is most efficient, followed by IgG1
  Neutralization of
MAJOR toxins and viruses
FUNCTIONS  Only Ig that can cross
OF IGG the placenta – provides immunity to newborn
(CONTINUED)  Lab Testing: Precipitation and agglutination
MAJOR FUNCTIONS OF IGG

Providing Fixing Coating Neutralizing Participating

Providing immunity Fixing complement Coating antigen for Neutralizing toxins Participating in
for the newborn (important in enhanced and viruses agglutination and
(because IgG can Blood Bank) phagocytosis precipitation
cross the placenta) (opsonization) reactions
IGM

Known as a macroglobulin
Has a molecular weight of about 900,000 d
Accounts for 5% to 10% of all serum
immunoglobulins

Has half-life of 6 days (much shorter
than that of IgG)

Can exist as:
Monomer (on surface of B cells)
Pentamer (found in blood)
IGM (CONTINUED)

 Pentamer form
 Held together by a J chain, which
forms disulfide bonds that link ends of
adjacent monomers
 Has a star-like shape with 10 antigen-
binding sites
FUNCTIONS OF IGM

Complement fixation

Agglutination

Neutralization of bacterial toxins and viruses

Known as the primary response antibody

Appears first after antigenic stimulation and in the maturing infant
Synthesized only as long as antigen remains present and may be used to
diagnose acute infection
IGM: PRIMARY VERSUS SECONDARY RESPONSE
IGA

 Accounts for 10% to 15% of all circulating immunoglobulins in serum
 Serum IgA: A monomer with three constant regions and a molecular
weight of 160,000 d
 Two subclasses — IgA1 and IgA2

IgA1 IgA2

Acts as an anti-inflammatory agent Predominantly found in secretions
Downregulates IgG-mediated at mucosal surfaces along the
phagocytosis, chemotaxis, respiratory, urogenital, and intestinal
bactericidal activity, and cytokine tracts
release
 SECRETORY IGA

 Synthesized mainly by plasma cells in mucosal-
associated lymphoid tissue
 Released as a dimer held together by a J chain
 Contains a secretory component (SC) derived
from epithelial cells
 Secretory IgA patrols mucosal surfaces and acts as a first line of defense
 Neutralizes toxins produced by microorganisms
 Prevents bacteria from adhering to mucosal surfaces and penetrating farther into
body
 Passively transfers immunity to newborn during breastfeeding

 IgA can act as an opsonin.

 Aggregation of IgA immune complexes may trigger alternative pathway of
complement.

IGA FUNCTIONS
SECRETORY IGA FUNCTIONS

Neutrophils, monocytes, Binding to these sites Both forms of IgA can
and macrophages possess triggers a respiratory thus act as opsonins, or
specific receptors for burst and degranulation promoters of
serum and secretory IgA of the cells involved phagocytosis
IGD

 Extremely scarce in the serum
 Less than 0.001% of total
immunoglobulins
 A monomer with a molecular weight
of 180,000 d and an extended hinge
region
 More susceptible to proteolysis than
other immunoglobulins
 Has a short half-life (1 to 3 days)
 IgD in serum does not appear to serve
a protective function; it does not bind
complement, bind to neutrophils or
macrophages, or cross the placenta.
IGD
FUNCTIONS IgD is also found on the surface of
immunocompetent but unstimulated B
lymphocytes:

Appears second (after IgM)
May play a role in B-cell activation
IGE

 Normally 0.0005% of total serum immunoglobulins
 A monomer with a molecular weight of 190,000 daltons and a heavy chain with
four constant domains
 Binding of IgE to eosinophils results in release of enzymes that destroy large
antigens like parasitic worms that cannot be easily phagocytized
 Does not participate in complement
fixation, agglutination, or opsonization

Is incapable of crossing the placenta
IGE
Attaches to basophils, eosinophils and
tissue mast cells through high-affinity Fc ε
RI receptors
Eosinophils play a major part in the
destruction of large antigens, such as parasitic
worms, that cannot be easily phagocytized
IGE FUNCTION: ALLERGIC REACTIONS

 Two adjacent IgE molecules on a mast cell bind a specific antigen.
 Cascade of cellular events results in degranulation of mast cells and release of
vasoactive amines (such as histamine and heparin).
  Based on clonal selection and Ig genetics
ANTIBODY  1950s: Jerne and Burnet’s theory of
clonal selection for antibody formation:
SPECIFICITY AND Lymphocytes are genetically
preprogrammed to produce one type of
DIVERSITY immunoglobulin. A specific antigen finds
the particular cells capable of responding
to it, causing them to proliferate. Would
require a large number of genes.
 1965: Dryer and Bennett: Constant and
variable portions of immunoglobulin
chains are coded for by separate genes.
 1987: Susumu Tonegawa: Specific Ig gene
segments are selected and joined
together during B-cell maturation.
CLONAL SELECTION

 Each B cell has a BCR specific for a particular
antigen.
 When antigen enters the body, it binds only to the B
cells that possess BCRs specific for it.
 Only those B cells proliferate and differentiate into
antibody-producing plasma cells.
IMMUNOGLOBULIN GENES

 Chromosomes contain building blocks from which
genes can be assembled
 Human immunoglobulin genes are found in three
unlinked clusters:
 H chain genes on chromosome 14
 κ chain genes on chromosome 2
 λ chain genes on chromosome 22
 Rearrangement of genes is needed to produce
functional antibody molecules.
IMMUNOGLOBULIN GENES (CONTINUED_1)

More than one gene controls synthesis of a particular
immunoglobulin

H chains
Variable-region genes:VH, D, and J
Constant-region genes: set of C genes
L chains:VL, J, and C (lack a D region)

Through random selection during B-cell maturation, individual
segments are joined together, committing that B lymphocyte to
making antibody of a single specificity.
IMMUNOGLOBULIN GENES (CONTINUED_2)

 Heavy-chain gene
rearrangement
IMMUNOGLOBULIN GENES (CONTINUED_3)

 Light-chain gene rearrangement
ADDITIONAL SOURCES OF ANTIBODY
DIVERSITY

Different heavy chains
Somatic Immunoglobulin class
Junctional diversity can combine with
hypermutation switching
different light chains.
Joining of V, J, and D Genetic mutations
segments does not during the course of
always occur at a the immune
fixed position. response that result
in stronger binding
of antigen (affinity
maturation)
MONOCLONAL ANTIBODIES

Used for laboratory testing and therapy

Developed based on knowledge that each B cell is
genetically preprogrammed to synthesize a very specific
antibody

Derived from a hybrid cell line (“hybridoma”) generated
from a single antibody-producing B cell and a myeloma cell

Technique developed in 1975 by Georges Kohler and Cesar
Milstein
HYBRIDOMA PRODUCTION

 Immunize a mouse with a specific
antigen.
 Harvest spleen cells.
 Combine spleen cells with myeloma
cells in the presence of PEG.
 Select fused cells and screen for
presence of desired antibody.
 Grow positive cells in larger
quantities.
SUMMARY
The basic structural unit for all immunoglobulins is a
tetrapeptide composed of two heavy chains and two
light chains joined together by disulfide bonds.

The five classes of immunoglobulins are IgM, IgG, IgA,
IgD, and IgE.

Kappa and lambda light chains are found in all types of
immunoglobulins, but the heavy chains differ for each
immunoglobulin class and are denoted by Greek letters.
SUMMARY

Each Variable region determines the specificity of that molecule for
immunoglobulin a particular antigen and contains the antigen-binding sites.
molecule has
constant and
variable regions. Constant region is responsible for Ig functions, such as binding
to complement and binding to phagocytic cells.

The five
different types
of heavy chains
are called
isotypes (g, a, m,
d, e).
SUMMARY

Minor variations in a particular type of heavy chain are
called allotypes and can differ among individuals of the
same species.

The variable portion of heavy and light chains unique to
a particular immunoglobulin molecule is known as the
idiotype.

IgG is the predominant immunoglobulin in the serum. Its
functions include binding of complement, opsonization,
ADCC, and neutralization of toxins and viruses.
 SUMMARY
IgM is the largest Ig because it is a pentamer in structure. It excels at complement
fixation and agglutination of antigens. It is the primary response antibody: the first to
appear during an immune response and during development of the infant.

IgA is the major Ig in the body’s secretions, where it occurs as a dimer. It patrols
mucosal surfaces and prevents pathogens from further invading the body. It is also
present in breast milk and transfers immunity to the newborn infant.

IgD has no known function in the serum but can serve as a surface receptor for
antigen on the surface of B cells and plays a role in B-cell maturation.

IgE binds to mast cells and basophils to initiate an inflammatory reaction that
mediates allergic reactions and defense against large parasites.
SUMMARY

The primary antibody response is the host’s response
after the first exposure to an antigen. It takes 5 to 7
days before antibody can be detected due to the time
needed to activate the lymphocytes.

The secondary response to antigen is caused by the
action of memory cells after a repeated exposure to
the same antigen. It occurs more rapidly and produces a
higher antibody titer that persists for a longer time.
SUMMARY

Clonal selection is based on the fact that lymphocytes are
genetically programmed to respond to a specific antigen. Upon
entering the body, the antigen binds to a receptor on the
correctly programmed B lymphocyte, causing it to divide and
differentiate into antibody-producing plasma cells.
Several genes code for a particular immunoglobulin; through a
random selection process, these individual segments are joined
to make antibody of a single specificity.
SUMMARY

Monoclonal antibodies are made by hybridoma cells,
which are generated by fusing an antibody-
producing B cell with a malignant myeloma cell that
contributes the property of immortality.
Monoclonal antibodies are used as laboratory
reagents and as therapies for various diseases.
POSTAMBLE

 READ the TEXTBOOK for the details to answer the UNIT OBJECTIVES.

 USE THE UNIT OBJECTIVES AS A STUDY GUIDE

 All test questions come from detailed material found in the
TEXTBOOK (Not this PowerPoint) and relate back to the Unit
Objectives