Immune Response and Immunity Envr 133 Mark D. Sobsey Antigens Any foreign substance that elicits an immune response when introduced into the tissues of.
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Immune Response and Immunity
Envr 133 Mark D. Sobsey
Antigens
Any foreign substance that elicits an immune response when introduced into the tissues of a susceptible animal and capable of combining with the specific antibodies formed. Generally high molecular weight Typically, proteins or polysaccharides. Polypeptides, lipids, nucleic acids and many other materials also can also function as antigens Microbes are antigenic and they contain and produce many antigens Antigens have specific sites that bind to antibodies called “epitopes ”
Immunity and Immune Response
• •
Made up of two cellular systems: Humoral or circulating antibody system
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B cells
Cell mediated immunity
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T cells
Immunity and Immune Response
• •
Immune system identifies antigens (foreign proteins or polysaccharides)
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Components of microbes or their partially degraded byproducts and
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Other foreign proteins and polysaccharides (including nucleic acids) Host (human or animal) antigens not made by the individual are also antigens
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Result: in graft, transplant rejection
The Immune System
• Human immune system begins to develop in the embryo. • Starts with hematopoietic (from Greek, "blood-making")
stem cells.
• Stem cells differentiate into major cells in the immune
system
– granulocytes, monocytes, and lymphocytes • Stems cells also differentiate into cells in the blood that are
not involved in immune function, such as erythrocytes (red blood cells) and megakaryocytes (for blood clotting).
• Stem cells continue to be produced and differentiate
throughout ones lifetime.
Components of Human Immune System
The Immune System
Immunity and the Immune Response System
Immunity and the Immune Response System
Clonal Selection of B Cells is Due to Antigenic Stimulation
Classes of Antibodies (Immunoghlobulins)
Humoral Immune Response to Antigen
Humoral Immune Response to Antigen
• First exposure to antigen "A”: – begin to make low levels of antibody in about a week • Second exposure to antigen "A”: – produces a much faster response, and – several orders of magnitude higher levels of antibody. – Ability of antibody to bind antigen also increases
dramatically in the secondary response.
• Injecting a new antigen "B” with "A" – Elicits only a primary response – Shows that a memory or prior exposure is required for
the accelerated response
.
Humoral or B-Cell Mediated Immune Response
• • • • •
Produces secreted antibodies (proteins) Bind to antigens and identify the antigen complex for destruction. Antibodies act on antigens in the serum and lymph B-cell produced antibodies may be
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attached to B-cell membranes or
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Free in the serum and lymph. Each B lymphocyte makes a unique antibody molecule (immunoglobulin or Ig) Over a million different B lymphocytes are produced in each individual
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So, each individual can recognize more than a million different antigens
Immuoglobulin G (IgG)
Immunoglobulin and Reaction with Antigen
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IgG antibody molecule
– –
Composed of 2 copies of 2 different proteins Two copies of a heavy chain
•
>400 amino acids long
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Two copies of a light chain -
•
>200 amino acids long each IgG antibody molecule can bind 2 antigens at one time
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A single antibody molecule can bind to 2 antigens (e.g., viruses, bacateria or other particle), which leads to clumping
Effect of Antigen Size on Humoral Immunity
Fate of Antigen-Antibody Complexes
• Ag-Ab complexes engulfed into the B-cell and partially
digested
• Antigen is displayed on the B-cell surface by a special
receptor protein (MHC II) fo recognition by helper T-cells
• B-cell is activated by the helper T-cell to divide and
produce secreted antibodies
– Abs circulate in the serum and lymph • Some B-cells become memory cells to produce antibody at
a low rate for a long time (long term immunity)
– They respond quickly when the antigen is encountered
again
– the response is regulated by a class of T-cells called
suppressor T-cells
Cell-Mediated Immunity and T Cells
• T cell receptors are cell surface receptors that bind nonself substances on the surface of other cells • Major histocompatibility complex (MHC) proteins protrude from the surfaces of most cells in mammals – They help to distinguish self from nonself – They coordinate interactions among lymphocytes and macrophages • Cytokines are soluble signal proteins released by T cells – They bind and alter the behavior of their target cells
• • •
Cell Mediated Immune System: T lymphocytes
T-cells mature in the thymus (thus the name T-cell) Act on antigens appearing on the surface of individual cells.
Over a million different kinds of T-cells
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Each produces a different receptor in the cell membrane
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Each receptor is composed of 1 molecule each of two different proteins
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Each receptor binds a specific antigen but has only one binding site
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Receptor only recognizes antigens which are "presented" to it within another membrane protein of the MHC type (major histocompatibility complex)
•
Recognizes specific antigens bound to the antigen presenting structures on the surface of the presenting cell.
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Recognizes antigens presented by B-cells, macrophages, or any other cell type
T Cells and their Functions
• • •
Have a specific receptor for a fragment of antigen Cytotoxic T-cells:
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Contain a surface protein called CD8
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Destroy pathogen infected cells, cancer cells, and foreign cells (transplanted organs) Helper T-cells:
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Contain a surface protein called CD4
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Regulate both cellular and humoral immune systems This regulation reduces autoimmunity.
Autoimmune disease
• •
Self immunity Some examples:
– rheumatic fever – rheumatoid arthritis – ulcerative colitis – myasthenia gravis – Lyme disease (microbial etiology) – Guillan-Barre syndrome (microbial etiology) – Reiter’s syndrome or reactive arthritis (microbial etiology) – Insulin dependent diabetes mellitus (IDDM) (microbial etiology?)
Interactions of the Components of The Immune Response
• • • • •
T-cells, B-cells, and macrophages use MHC-II receptors for presentation; All other cells use MCH-I
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(responsible for most of tissue graft rejection) When a T-cell is presented with an antigen:
– –
its receptor binds to the antigen and it is stimulated to divide and produce helper T-cells
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activate B-cells with bound antigen suppressor T-cells
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regulate the overall response Cytotoxic "killer" T-cells
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kill cells with antigen bound in MHC-I
Role of Immunity in Infections Localized Infections:
• Immunity to infection is usually short-term and transient – Mucosal (secretory or IgA) immunity in the gut or
respiratory tract wanes over time
• Proof of concept: live, oral rotavirus vaccine: – immunity declines over time and reinfection with “wild”
type rotaviruses occurs
• Repeated localized (e.g., gastrointestinal) re-infection is
possible. Examples:
– Viruses: rotaviruses, noroviruses, adenoviruses and some
enteroviruses.
– Salmonella spp, Shigella spp., Campylobacter spp, and E. coli spp.
cause localized infections
– Giardia lamblia and Cryptosporidium parvum
Role of Immunity in Infections: Generalized/Systemic/Disseminated Infections
• Immunity against generalized/systemic/disseminated
infection is usually lifelong, unless immune system is severely compromised
• Localized (e.g., gastrointestinal) re-infection is possible • Hepatitis A and E and many enteroviruses are viruses
causing systemic/generalized/disseminated infections
• Salmonella typhi is a bacterium causing systemic infection • Typically, immunity against severe illness is long-term and
probably lifelong
– Proof of concept: live, oral poliovirus vaccine and poliomyelitis
eradication; susceptibles are newborns and infants
• Antigenic changes in microbes may overcome long-term
immunity and increase risks of re-infection or illness
Role of Selection of New Microbial Strains in Susceptibility to Infection and Illness • Antigenic changes in microbes overcome immunity,
increasing risks of re-infection or illness
– Antigenically different strains of microbes appear and are
selected for over time and space
– Constant selection of new strains (by antigenic shift and drift) – Partly driven by “herd” immunity and genetic recombination,
reassortment , bacterial conjugation, bacteriophage infection and point mutations
• Antigenic Shift: – Major change in virus genetic composition by gene substitution
or replacement (e.g., reassortment)
• Antigenic Drift: – Minor changes in virus genetic composition, often by mutation
involving specific codons in existing genes (point mutations)
• A single point mutation can greatly alter microbial
virulence