3_ ANTIGEN PRESENTATION (PART 1 OF 2).pptx

Transcript

WELCOME!
BMS 545
IMMUNOLOG
Y
SEPTEMBER 20, 2024
ANNOUNCEMENTS

 Office Hours
 Tuesday- 4-5 pm
virtual
 Thursday 4-5 pm in-
person

 No more homework
until Module 3!!!!!
 OBJECTIVES
 Identify & explain antigen processing & presentation (basics- why
is it important?)
 Differentiate professional APCs from atypical/amateur APCs, esp.
how they present, and what types of antigens. What cell types
are they found on?
 Identify & explain the locations & functions of MHC molecules
 Compare & Contrast MHC I & MHC II molecules including
structure, formation, function, type of peptide, cells they present
to, etc.
 Describe the importance of MHC restriction
 Describe the “Sweaty T-Shirt” Study (Your “Also A Scientist”)
WHY SHOULD YOU CARE? (“FUN” SCIENCE STUDY)
The Sweaty T-Shirt Study
https://www.youtube.com/watch?v=qgeZnuevxnA
 ANTIGEN PROCESSING, PRESENTATION & RECOGNITION
 T cell activation must be tightly regulated- difficult to slow down cell-mediated
immune response once started
 Immune system has system of checks & balances that prevent T-cells from deciding on
their own what antigens to destroy (limits risk of autoimmunity)
 Therefore, it is NECESSARY for other cells to process & then present foreign antigens
to T cells with additional signals required for recognition & full activation of the cell-
mediated response
 Antigen processing and presentation
5-5 T-cell receptors recognize peptide antigens bound to MHC
molecules

peptide (red)+ MHC
(yellow) = pMHC
Figure 5.8 Antigen processing and presentation

antigen:MHC =
pMHC

 A pathogen & its proteins can be synthesized by an infected human cell or be taken up
from extracellular environment
 All human cells have housekeeping mechanisms that serve to remove damaged or
unwanted proteins
 These mechanisms degrade proteins into small peptides & are used to produce the
pathogen-derived peptides that are bound by MHC molecules, displayed on cell
surface, & presented to T cells
TYPES OF ANTIGEN PRESENTING CELLS (APCS)
PROFESSIONAL
VS.
AMATEUR
ANTIGEN
PRESENTATION
MAJOR HISTOCOMPATIBILITY COMPLEXES
 Major Histocompatibility Complex (MHC)-
membrane bound protein that displays antigen peptides
to T-cells
 MHC proteins encoded by genes from both parents to
increase diversity of MHC molecules
 Each MHC gene has multiple alleles (polymorphic) so
that each person has unique MHC pattern (except
identical twins)
 Ability to fight infection varies between people, as
every person’s adaptive immune system responds
slightly differently to microbes
 These genes are found in all mammals, but not in
microorganisms. Consequently, the immune system
uses these MHC proteins to recognize cells in body as
“self"
 Human MHC molecule is located on chromosome 6
 Class I gene complex contains 3 major loci, B, C & A
 Class II gene complex contains at least 3 loci, DP, DQ
& DR
 Aka human leukocyte antigens (HLA)- important
in tissue typing to match transplant organs, etc.
The major histocompatibility complex
5-15 Human MHC diversity is
the product of gene
families & genetic
polymorphisms
The major histocompatibility complex
5-20 Human populations all maintain a diversity
of HLA class I and class II alleles

Without diversity of HLA class I & class II
allotypes humans would not survive
Figure 5.38 MHC heterozygosity delays the progression to AIDS in people infected
with HIV-1
 Antigen processing and presentation
5-12 All nucleated cells express MHC class I, whereas
MHC class II is mainly expressed by professional
antigen-presenting cells (APCs)

Tissue distribution of MHC molecules →

*Activated T cells have cell-surface MHC class II,
whereas resting T cells do not

†
Most cell types in the brain are MHC class II–
negative, but microglial cells, which are related
to macrophages, are MHC class II–positive.
 Antigen processing and presentation

5-7 MHC class I and class II molecules have MHC class
similar I- composed of a
structures
membrane-bound heavy chain (α) &
a soluble light chain called β2-
microglobulin (β2m)
 Heavy chain has 3 extracellular
domains, α1 & α2 domains that
form peptide-binding groove
 α3 domain & β2m are
immunoglobulin-like domains
with similar structure that
interact to support peptide-
binding groove (aka α1 & α2)
 MHC class II- composed of 2
structurally similar, membrane-
bound α & β chains that have an
amino-terminal domain resembling
the α1 & α2 domains of MHC class I
& an immunoglobulin-like domain
Figure 5.13 The MHC fold
 MHC CLASS I
 Co-dominantly expressed 45-kDa MHC class I molecules with β2
microglobulin (β2m) found on surface of ALL NUCLEATED cells
 MHC Class I three genetic loci, HLA-A, -B, & -C, are highly
polymorphic with more than 100 alleles at each locus
 MHC class I molecules (HLA-A, HLA-B, or HLA-C) together with β2
microglobulin (β2m) form a closed peptide cleft between α1 &
α2 domains that can noncovalently bind an 8-9 amino-acid
peptide
 Slight structural variations in the binding cleft (binding
groove) of different allelic forms = different peptides may
preferentially fit into clefts of some MHC class I molecules
better than others
 Additional “nonclassical” class I molecules (e.g., those
encoded by the HLA-E, -F, -G, -H loci) show limited variability &
tissue distribution & may function to present carbohydrate &
peptide fragments; CD1d is one of many examples
 MHC CLASS II

 Normally only expressed on surfaces of APCs, some
activated T cells, & some specialized epithelial cells in
thymus & intestine
 Co-dominantly expressed as noncovalent
heterodimers, a 32-38 kDa α chain & a 29-32 kDa β
chain form a binding groove (α1 & β1 domains) that can
accommodate 18-20 amino acid peptide
 Encoded within the HLA-DP, -DQ, & -DR regions with α
& β loci (DPα, DPβ, DQα, DQβ, etc.)
 After synthesis, MHC class II α & β chains combine
only with others encoded within same region (e.g.,
DPα associates only with DPβ but never with DQβ or
DRβ)
 Antigen processing and presentation
5-6 Two classes of MHC molecule present peptide antigens to two
types of T cell