1_ NK CELLS AND BRIDGE TO ADAPTIVE_OVERVIEW OF ADAPTIVE .pptx

Transcript

WELCOME!
BMS 545 IMMUNOLOGY
SEPTEMBER 16, 2024
ANNOUNCEMENT
S
 Office Hours
 Tuesday 4-5 pm
(virtual)
 Thursday 4-5 pm
(316J)
 DITKI due
Wednesday by 12:59
pm
 Adaptive Immunity-
Cellular WITH QUIZ
 RE-VIEW Thymus,
Spleen, & Lymph
Nodes (NO QUIZ)
WHY SHOULD
YOU CARE?

 https://www.healio.com/n
ews/hematology-oncolog
y/20220119/fda-grants-f
ast-track-designation-to-
natural-killer-cell-therapy
-for-gi-cancers
 OBJECTIVES
 State where you would expect to find receptors of the adaptive immune system within the
context of the cell and correlate the ligands and receptors of the two types of immune cells
with their signaling outcomes (more on this later too, but today it’s KIR & KAR)
 Compare and contrast NK & NKT cells
 Describe how NK cells can work with macrophages & dendritic cells to bring about an
immune response
 Outline the movement of lymphocytes throughout the body and key anatomical features
 Describe how adaptive immune system differs from innate & unique features of the
adaptive immune system
 Recognize & describe the microenvironments where adaptive immune cells mature & the
adaptive immune response develops
 Identify the primary & secondary immune organs in vertebrates & describe their function
in relation to the adaptive immune system
 REFRESHER: INTERFERON RESPONSE TO INTRACELLULAR
MICROBIAL INVASION
 Interferon- family of cytokines that act specifically to induce
cells to resist viral infections
 Rapidly produced when viral PAMPs interact with PRRs
 Main interferons are IFN-α & IFN-β (type 1 interferons) and
produced by a variety of cells
 Induce cells to activate antiviral defenses like RNA-dependent
protein kinase pathway & apoptotic (programmed cell death)
pathway
 IFN-γ (type II interferon)- structurally & functionally unrelated
to type I interferons, but produced by activated lymphocytes
like CD4 T cells, CD8 T Cells, NK Cells, & ILCs.
 Acts principally to activate macrophages in both innate and
adaptive immunity
Don’t mix-up Type I interferons with Type 1 immunity
Type 1 immunity protects against intracellular microbes through
activation of mononuclear phagocytes; mediate autoimmune
INTERFERON
RESPONSE TO
INTRACELLULAR
MICROBIAL
INVASION
Inflammation, innate immunity, and lymphoid
cells
3-20 NK cells are circulating lymphocytes of the innate immune
response & provide an early response to viral infections
Figure 3.44 NK cells circulate between blood and tissues

HEV = high endothelial
venule
 NK & NKT CELLS True NK cell on left, NKT on
 Kill certain virally infected cells & tumor cells without prior right
sensitization such as:
 some virus-infected cells
 cells covered with antibody
 cells that do not express normal levels of class I MHC
 Play a role in both innate AND adaptive even though they are
descended from CLP
 Similar to Innate Lymphoid Cells (ILCs) & Lymphoid tissue
inducer (LTi)
 Lymphoid cells that function in innate immune system
 (*NEW*) Natural Killer T cell (NKT)- a unique subset of T cells
develop within thymus & express a rearranged TCR of extremely
limited repertoire
 Unlike T cells, NKT respond to lipids, glycolipids, or hydrophobic
peptides presented by a specialized, nonclassical MHC class I
molecule (CD1d), & secrete large amounts of cytokines, especially
IL-4
 Inflammation, innate immunity, and lymphoid
cells
3-22 NK-cell cytotoxicity is activated at sites of virus infection

Activation by type I interferon induces NK-cell proliferation & differentiation
into cytotoxic effector cells
KILLER ACTIVATION RECEPTORS & KILLER INHIBITION
RECEPTORS
 NK cells don’t have extremely variable antigen-specific
receptors like other lymphoid lineage cells
 Killer activation receptors (KARs)- recognize presence of
stress-related molecules (called MICA & MICB molecules in
humans) expressed by host cells that are unhealthy or
infected
 Binding of MICA or MICB molecules by NK cell’s KARs induces NK
cell to attach & destroy the targeted (e.g., infected) host cell
 Killer inhibition receptors (KIRs)- monitor major
histocompatibility complex (MHC) class I molecules normally
displayed on cell surfaces of all nucleated cells in the body
 Determine normality of host cells; cancer & viruses decrease MHC
class I
 Once bound to a target cell via its KARs, KIRs assess expression
of MHC class I molecules on that cell
 If subnormal MHC I= target cell killed

 Inflammation, innate immunity, and lymphoid
cells
3-23 NK cells and macrophages activate each other at sites of infection

Interaction between an NK cell & macrophage induces NK-cell proliferation & differentiation
 INTERACTIONS BETWEEN
DENDRITIC CELLS & NK
CELLS INFLUENCE THE
IMMUNE RESPONSE

 Left- In virus-infected tissue, an immature
dendritic cell expressing viral antigens
can activate NK cells & drive their
differentiation into effector cells (kill!)
 Center- When activated cytotoxic NK
cells are abundant & innate immunity is
overcoming infection, NK cells kill
dendritic cells & prevent their activation
of adaptive immunity
 Right- When NK cells are scarce & innate
immunity cannot control infection, NK
cells induce dendritic cells to differentiate
into a form that migrates to secondary
lymphoid tissue & initiates the adaptive
immune response
 Inflammation, innate immunity, and lymphoid
cells
3-25 The NK-cell population retains a memory of its encounters with
pathogens

For example: Time
course of the NK-
cell response to
human
cytomegalovirus
(CMV)
 r e
i c tu
g P
B i
 WHY SHOULD YOU CARE?
 The immune system must be able to distinguish its own molecules, cells, & organs (self) from those
of foreign origin (nonself)
 Innate immune system does this by expressing germline-encoded pattern recognition receptors
(PRRs) on the surface of its cells that recognize structures on potentially invasive organisms
 Adaptive immune system uses somatically generated epitope-specific T-cell and B-cell receptors
(TCRs & BCRs)

No two individuals, even
identical twins, have
identical adaptive
TWO BRANCHES OF THE IMMUNE SYSTEM
INNATE VS.
ADAPTIVE
IMMUNITY
  Primary lymphoid organs- where
immune cells develop
 Bone Marrow

THE  Thymus
 Secondary lymphoid organs- where
LYMPHATIC immune response is initiated
 Lymph Nodes
SYSTEM  Spleen
 Barrier tissues
 Tertiary lymphoid organs- also
organize & maintain an immune
response
Figure 1.21 Location of lymphoid tissues in the human body

Please review DITKI
lymph node, spleen, and
bone marrow- you could
see questions related to
this on Exam 2
Figure 1.22 Lymphocyte recirculation

1.Circulating
lymphocytes
leave in efferent
lymph
2.Return to blood in
left subclavian
vein
3.Enter lymph node
through walls of
fine capillaries in
secondary
Figure 1.23 Recirculating lymphocytes meet lymph-borne pathogens in draining
lymph nodes

Lymphocytes activated
by specific antigen stay
in LN to divide &
differentiate into effector
cells
With B cells, this is
how we get germinal
centers

Lymphocytes not
activated by specific
antigen leave LN in
efferent lymph & are
carried by lymphatics to
 Elements of the Immune System and Their
Roles in Defense
1-12 Adaptive immunity is initiated in secondary lymphoid tissues
Figure 1.24 Architecture of the lymph node, the site where blood-borne
lymphocytes respond to lymph-borne pathogens
 SECONDARY LYMPHOID TISSUE- LYMPH NODES
 Lymph nodes are responsible for filtering &
processing antigens present in lymphatic fluid
as it travels from Afferent to Efferent vessels
 Activation into effector cells takes place in
follicles of secondary lymphoid organs
 T lymphocytes
 CD4+ helper T cells assist in B-cell
activation
 CD8+ cytotoxic T cells that attack &
destroy virally infected cells
 B lymphocytes further mature in germinal
centers
 Antigen affinity is increased
 Class switching can take place
 Both B & T lymphocytes will develop into long
Figure 1.25 Activation of adaptive immunity in a draining lymph node
1. Pathogens & antigens (& dendritic cells carrying pathogens & antigens)
arrive at a lymph node in afferent lymph draining the infected tissue
2. Pathogens & debris are removed by macrophages
3. Dendritic cells become residents & move to T-cell areas, where they
encounter small lymphocytes that have entered LN from blood (green)
4. Dendritic cells orchestrate division & differentiation of small pathogen-
specific lymphocytes into effector cells (blue)
 Some helper & cytotoxic T cells leave in efferent lymph & travel to
infected tissue
 Other helper T cells stay in LN to stimulate division of pathogen-specific
B cells & their differentiation into plasma cells (yellow) (B cell follicles →
germinal centers)
5. Plasma cells move into medulla of lymph node, where they secrete
pathogen-specific antibodies
 Other plasma cells leave LN & travel to bone marrow, where they secrete
pathogen-specific antibody in quantity
6. Antibodies travel to infected tissue by efferent lymph & blood
 SECONDARY LYMPHOID TISSUE-SPLEEN
 Spleen is first line of defense
against blood-borne
pathogens
 Consists of two different
tissues:
 Red pulp- where old and
damaged red blood cells
are removed from
circulation
 Most of spleen is red pulp
 White Pulp- where white
blood cells reside
 A specialized region of
macrophages & B cells
known as the marginal
zone borders white pulp &
separates it from red pulp
Figure 1.26 The spleen has organized aggregations of lymphocytes like those
present in lymph nodes
 Situated in upper left part of the abdomen,
the spleen weighs ~150 g & is larger than
any lymph node
 Upper diagram depicts a section of spleen
in which nodules of white pulp are
scattered within the more extensive red
pulp.
 Lower diagram shows a nodule of white
pulp in transverse section
 Comprises a sheath of lymphocytes
surrounding a central arteriole
 In the periarteriolar lymphoid sheath
(PALS), the lymphocytes near the arteriole
are mostly T cells (blue region), whereas
B cells (yellow regions) are situated
peripherally
 Lymphoid follicles comprise a germinal
center, a B-cell corona, and a marginal
zone containing macrophages &
differentiating B cells
 Perifollicular zone- contains erythrocytes,
macrophages, T cells, & B cells
 ALSO A SCIENTIST
 Viki Male, PhD
 “Quite recently, it turned out that
there is a special kind of NK cell that
is only found in the liver, and my
group showed that these special NK
cells can’t ever leave the liver – they
are liver-resident. The thing is, we
still don’t know what they do. There
is some evidence that they could act
as an early warning system for
certain viruses that particularly
infect the liver, but I think they
might also do something important
in the healthy liver.”
 https://thefemalescientist.com/portr
ait/viki-male/1670/meet-viki-male-an
 ALSO A SCIENTIST
 Amintinder “Miti” Kaur, MD
 Professor of Microbiology and Immunology
 Chair, Division of Immunology, Tulane National
Primate Research Center
 Immunomodulatory role of Natural Killer T cells
 First characterization of natural killer T (NKT)
cells in sooty mangabeys and the novel finding
that mangabeys differ from other species
including mice, humans and macaques, in
lacking CD4+ NKT cells. As a result, SIV-infected
mangabeys are protected from NKT cell
depletion and dysfunction.
 We are currently investigating the
immunoregulatory functions of NKT cells in
modulating the immunogenicity and efficacy of
candidate AIDS vaccines and affecting the
outcome of SIV infection