Immunity
Human Health and Disease: Immunity
Immunity
Immunity — Innate, Adaptive, Antibodies, and Vaccines
What you'll learn
- Difference between innate (non-specific) and adaptive (specific) immunity
- How B cells produce antibodies (humoral immunity) and T cells kill infected cells (cell-mediated immunity)
- Structure and classes of antibodies (IgG, IgM, IgA, IgE, IgD)
- MHC I vs MHC II — what they present, to whom, and on which cells
- How vaccines exploit immunological memory
- Complement system, interferons, and monoclonal antibodies (hybridoma technology)
Key concepts
Level 1 — Foundations
Innate Immunity (Non-specific, present from birth)
- Physical barriers: skin (keratinized), mucous membranes, cilia (sweep pathogens out)
- Chemical barriers: lysozyme in tears/saliva (cleaves bacterial peptidoglycan), HCl in stomach (pH 2), defensins in skin
- Cellular: neutrophils (first responders, phagocytosis), macrophages (phagocytosis + antigen presentation), NK cells (kill virus-infected/tumor cells without MHC recognition), mast cells (release histamine in inflammation)
- Inflammatory response: vasodilation, increased vascular permeability, recruitment of neutrophils; cardinal signs — redness, heat, swelling, pain
- Fever: pyrogens (LPS, IL-1, IL-6, TNF-α) act on hypothalamus → prostaglandin E2 → reset thermostat
Adaptive Immunity (Specific, acquired)
- Requires exposure to antigen; has memory; takes 1–2 weeks on first exposure (primary response), days on re-exposure (secondary response)
- Two arms:
- Humoral immunity: B lymphocytes → plasma cells → antibodies; effective against extracellular pathogens
- Cell-mediated immunity (CMI): T lymphocytes; effective against intracellular pathogens, fungi, transplant rejection, tumors
B Cells and Antibodies
- B cells mature in bone marrow; each carries unique B-cell receptor (surface immunoglobulin)
- On antigen binding (+ T-helper cell signal) → clonal expansion → plasma cells (antibody factories) + memory B cells
- Antibody classes:
- IgG: most abundant in serum, crosses placenta (passive immunity to fetus), opsonization, complement activation; 4 subclasses
- IgM: pentamer, first antibody produced in primary response; most efficient at complement activation; ABO blood group antibodies
- IgA: dimer in secretions (saliva, breast milk, tears, gut lumen) as secretory IgA (sIgA); first line in mucosal immunity
- IgE: lowest concentration; binds mast cells and basophils via Fc receptor → degranulation with allergen cross-linking → allergy/anaphylaxis; also anti-parasitic
- IgD: mainly on surface of naive B cells; function not fully understood; may play role in B-cell activation
T Cells
- Mature in thymus; CD4+ helper T cells and CD8+ cytotoxic T cells
- CD4+ T helper cells: recognize antigen on MHC II; help B cells (Th2) or activate macrophages (Th1); secrete cytokines (IL-2, IL-4, IL-5, IFN-γ)
- CD8+ cytotoxic T cells (CTL): recognize antigen on MHC I; kill infected/tumor cells by releasing perforin (pores) + granzymes (apoptosis) or Fas ligand → Fas pathway
Active vs Passive Immunity
| Feature | Active | Passive |
|---|---|---|
| Source | Self-generated antibodies | Pre-formed antibodies from another source |
| Onset | Slow (weeks) | Immediate |
| Duration | Long-lasting (years to lifetime) | Short (weeks to months) |
| Memory | Yes | No |
| Examples | Natural infection, vaccination | Maternal IgG (transplacental), colostrum (IgA), anti-snake venom, anti-rabies immunoglobulin |
Vaccines
- Exploit the secondary immune response (faster, stronger, due to memory cells)
- Types: live attenuated (MMR, OPV, BCG), inactivated (IPV, hepatitis A), subunit (hepatitis B — recombinant HBsAg), toxoid (tetanus, diphtheria — formaldehyde-inactivated toxins), mRNA (COVID-19 — Pfizer/Moderna)
- Herd immunity threshold: depends on basic reproduction number R₀; for measles (R₀ ~15), need ~95% coverage
Level 2 — JEE / NEET depth
MHC I vs MHC II
| Feature | MHC Class I | MHC Class II |
|---|---|---|
| Expressed on | All nucleated cells (not RBCs) | APCs only: dendritic cells, macrophages, B cells |
| Presents | Endogenous antigens (viral peptides made inside cell, 8–10 aa) | Exogenous antigens (phagocytosed, 13–25 aa) |
| Presents to | CD8+ cytotoxic T cells | CD4+ helper T cells |
| Co-receptor | CD8 | CD4 |
| Pathway | Proteasome cleaves protein → TAP transporter → ER → loaded onto MHC I | Lysosome degrades phagocytosed antigen → endosome → CLIP removed → antigen loaded → expressed on surface |
| Gene loci (HLA) | HLA-A, HLA-B, HLA-C | HLA-DR, HLA-DP, HLA-DQ |
Clonal Selection Theory (Burnet, 1957)
- Each lymphocyte is pre-committed to one antigen specificity (clonally selected)
- Antigen selects and activates the matching clone → proliferation (clonal expansion)
- Most daughter cells = effector cells; some = long-lived memory cells
- Explains immunological memory and tolerance (self-reactive clones deleted in thymus/bone marrow = clonal deletion)
Antibody Structure
- Monomer: 2 heavy chains + 2 light chains (κ or λ) linked by disulfide bonds; Y-shaped
- Variable region (Fab — Fragment antigen-binding): N-terminal, hypervariable complementarity-determining regions (CDRs) contact antigen
- Constant region (Fc — Fragment crystallizable): C-terminal of heavy chains; binds Fc receptors on phagocytes (opsonization), activates complement (classical pathway — IgG and IgM), determines antibody class
- Valency: IgG monomer = 2 binding sites; IgM pentamer = 10 binding sites (but steric hindrance reduces effective valency)
Complement System
- Three pathways: classical (IgG/IgM-antigen complex), lectin (mannose-binding lectin), alternative (direct pathogen surfaces) — all converge at C3 convertase → C3b (opsonization) → C5 convertase → C5b → Membrane Attack Complex (MAC): C5b-6-7-8-9 → transmembrane pore → osmotic lysis of bacteria/enveloped viruses
- C3a and C5a: anaphylatoxins → mast cell degranulation → inflammation
Interferons
- Type I (IFN-α, IFN-β): produced by virus-infected cells; signal neighboring cells to upregulate antiviral proteins (2-5A synthetase/RNase L system degrades viral RNA; PKR phosphorylates eIF2α → halts translation); also upregulate MHC I
- Type II (IFN-γ): produced by Th1 and NK cells; activates macrophages (classical activation → enhanced killing via reactive oxygen/nitrogen species); upregulates MHC I and II; key in defense against intracellular bacteria (Mycobacterium, Listeria)
- Type III (IFN-λ): primarily at mucosal surfaces
Monoclonal Antibodies (Hybridoma Technology — Köhler and Milstein, 1975)
- Immunize mouse with antigen → B cells from spleen
- Fuse B cells with immortal myeloma cells (PEG or electrofusion) → hybridomas
- Select in HAT medium (hypoxanthine-aminopterin-thymidine): unfused myeloma cells die (aminopterin blocks de novo purine synthesis; myeloma lacks HGPRT for salvage pathway); unfused B cells die naturally
- Screen hybridoma clones for desired antibody by ELISA
- Expand single clone → monoclonal antibody (mAb)
- Applications: Herceptin (trastuzumab — anti-HER2 for breast cancer), Rituximab (anti-CD20 for B-cell lymphoma), adalimumab (anti-TNF-α for rheumatoid arthritis), COVID-19 neutralizing antibodies, diagnostic pregnancy tests (hCG detection), ELISA
Colostrum and Passive Immunity
- Colostrum (first 2–3 days of lactation): rich in secretory IgA, IgG, lysozyme, lactoferrin, cytokines, growth factors
- sIgA in colostrum/breast milk: protects newborn gut mucosa from pathogens; not absorbed into blood (local mucosal immunity)
- Maternal IgG crosses placenta via FcRn (neonatal Fc receptor) from ~28 weeks gestation → systemic passive immunity in newborn (lasts ~6 months)
Worked example
Trace the immune response when influenza virus enters the respiratory tract:
Step 1 — INNATE RESPONSE (0–4 hours)
Virus enters respiratory epithelium → epithelial cells detect via pattern
recognition receptors (PRRs): TLR3 (dsRNA), TLR7/8 (ssRNA), RIG-I (cytosolic)
→ NF-κB activation → production of Type I interferons (IFN-α/β) + TNF-α + IL-6
Step 2 — INNATE CELLULAR (4–96 hours)
Infected cells upregulate MHC I → NK cells survey and kill cells with
downregulated MHC I (missing-self recognition)
Alveolar macrophages phagocytose virus → produce IL-12 (activates NK cells),
IL-1β, IL-6, TNF-α → fever, acute phase response
Dendritic cells (DCs) phagocytose virus in tissue → migrate to draining lymph
node (mediastinal) → mature DC upregulates CCR7, MHC II, CD80, CD86 (co-stimulatory)
Step 3 — ADAPTIVE INITIATION (day 4–7)
In lymph node, mature DC presents viral peptide (e.g., hemagglutinin peptide)
on MHC II → activates CD4+ Th cell bearing matching TCR (+ CD28-CD80 co-stimulus)
→ CD4+ T cell proliferates → Th1 subset secretes IFN-γ, IL-2
Same DC presents endogenous viral peptide on MHC I → activates CD8+ CTL
Step 4 — HUMORAL ARM
Th2-polarized CD4+ cells help influenza-specific B cells (recognize native HA
surface protein) → B cell class switches (IgM → IgG) via IL-4/IL-13
→ Plasma cells produced → secrete anti-HA IgG antibodies
Antibodies: (a) neutralize virus (block HA binding to sialic acid receptors)
(b) opsonize virions for macrophage phagocytosis (c) activate complement → MAC
Step 5 — CELL-MEDIATED ARM
Activated CD8+ CTLs traffic to lung → recognize HA/NP peptide:MHC I on
infected cells → release perforin (pore) + granzyme B (activate caspases)
→ infected cell undergoes apoptosis → virus cannot replicate further
Step 6 — RESOLUTION AND MEMORY (week 2–3)
>90% effector cells die by apoptosis (contraction phase) — mediated by FasL, TNF,
withdrawal of survival signals (IL-2)
Surviving ~5–10% = memory T cells (CD45RO+, CD62L+, long-lived, self-renewing)
Long-lived plasma cells migrate to bone marrow → secrete IgG for years
Memory B cells recirculate; on re-exposure respond within 1–3 days (secondary
response: 10–100× more antibody, faster, predominantly IgG, higher affinity
due to affinity maturation in germinal centers)
Common mistakes
| Mistake | Why it happens | Fix |
|---|---|---|
| Thinking IgE causes all allergies and is the most abundant antibody | IgE is memorable for allergies so students overstate its role | IgG is most abundant in serum; IgE is lowest in concentration; IgE causes type I hypersensitivity only |
| Confusing template strand direction with mRNA direction in transcription — same error pattern here: confusing MHC I (endogenous) with MHC II (exogenous) | The names don't hint at which antigen type | MHC I = Intracellular antigens → CD8 (I = Inside, 8 = ate); MHC II = External antigens → CD4 |
| Saying B cells mature in thymus | T cells mature in Thymus is the correct fact | B cells mature in Bone marrow; T cells in Thymus |
| Stating that passive immunity gives long-lasting protection | Students assume all immunity = long-lasting | Passive immunity has no memory cells; duration is weeks to months (half-life of IgG ~21 days) |
| Calling all T cells "cytotoxic" | Students see T cells and assume killing function | CD4+ = helper (orchestrates response); CD8+ = cytotoxic (directly kills); both are T cells |
| Saying colostrum gives systemic antibodies to newborn via gut absorption | Mixing up IgG (transplacental, systemic) with sIgA in colostrum | sIgA in colostrum acts locally in gut lumen; systemic immunity comes from transplacental IgG |
| Thinking primary and secondary immune responses are equally fast | Students memorize both without timing | Primary response: peak IgM day 7–10, then IgG; Secondary: IgG rises within 2–3 days, much higher titer |
Board exam drill
- Draw and label the structure of an antibody molecule showing Fab, Fc, heavy chain, light chain, variable region, disulfide bonds
- Name the five classes of immunoglobulins and state one unique functional feature of each
- Distinguish between active and passive immunity with two examples of each
- Explain why the secondary immune response is faster and stronger than the primary response
- State the cell types involved in cell-mediated immunity and describe how a cytotoxic T cell kills a virus-infected cell
- Write the steps of hybridoma technology for monoclonal antibody production
- Why does IgM form a pentamer and what functional advantage does this give?
- Explain the role of interferons in antiviral defense
NCERT diagrams to know
- Figure 8.1: Human body showing physical and physiological barriers (skin, mucus, cilia, stomach acid, lysozyme)
- Figure 8.2: Types of immunity (innate/acquired, active/passive) — flowchart
- Figure 8.3: Structure of an antibody (Fab, Fc, heavy/light chains, variable/constant regions)
- Figure 8.4: Primary and secondary immune response graph (IgM peak first, then IgG; secondary response higher and faster)
- Vaccination and immunization examples: BCG, OPV, DPT schedules from NCERT text
Quick check
- Which immunoglobulin is found in colostrum as a dimer?
- Name two cells that express MHC Class II on their surface
- What is the role of the Fc region of an antibody?
- Which type of T cell is activated by MHC I-presented antigens?
- IgM is a ___-mer with a valency of ___
- What enzyme does lysozyme target in bacteria?
- Name the experiment that proved clonal selection theory was correct (hint: Burnet's theory supported by...)
- Stretch: Why are people with HIV/AIDS susceptible to opportunistic infections — connect to CD4+ T cell count and specific immune functions lost
NCERT Chapter 8 link: Human Health and Disease — Class 12 Biology Exam connections: NEET questions routinely ask antibody class properties, MHC I/II distinction, active vs passive immunity, and steps of hybridoma technology. 2–3 questions per year on average. Study strategy: Draw the antibody structure from memory daily for 5 days. Make a table of all 5 Ig classes with one unique fact each. Practice the primary/secondary response graph — draw it without looking.
Interactive Exploration Suggestions (Drishti Live Worlds)
- Use the platform-native live simulation or PhET-style tool for this topic (number line, Venn, physics playground, molecule builder, sensor dashboard, etc.).
- Mirror / body / home activity: physically do the concept (count objects, measure, role-play) and photograph or describe for portfolio.
- Voice or text reflection with AI Mentor: explain the concept to a younger student or family member.
AI Mentor Prompts (Socratic, Board-Adaptive)
- "Explain this concept to a Class 6 student using one real example from an Indian home, school, market, or festival."
- "What is one common mistake students make here, and how would you catch yourself making it?"
- Stretch: "How does this connect to coding, robotics, money, health, environment, or a future career?"
Gamification, Portfolio & Parent Visibility
- Complete the core practice + one extension activity (photo, table, short reflection, or mini-project) for base XP + topic badge.
- 5-7 day streak or family discussion note = multiplier + visible artifact in parent/principal dashboard.
- Best real-world application stories (anonymised) featured on class or national leaderboard.
Robotics, STEM & Future Skills Bridges
- One hands-on project or measurement using the Drishti kit or household items that makes the concept physical.
- Direct link to at least one Future Skill track (Money Management, Green Tech, Cyber Defenders, Micro-Entrepreneurship, AI Mastery, Sustainable Living, Personality Development).
- Coding extension where relevant (simple script, simulation, or data logging).
NEP 2020 & Full Education OS Alignment
This material emphasises experiential "learning by doing", competency (apply/create/analyse), vocational exposure, critical thinking, and multidisciplinary connections. Designed to feed live worlds, AI Mentor (with memory), gamification, robotics, parent analytics, and future skills — not just exam prep.
Portfolio Evidence Idea: Your photo/table/reflection/project + one sentence on "How this helps me in real life or a possible future path."
Open the Practice tab for aligned questions (easy/medium/hard + case-based) with full AI scaffolding.
See curriculum for cross-links and the full future-skills/robotics chapters.
Key Takeaways (TL;DR)
- What you'll learn
- Key concepts
- Worked example
- Common mistakes
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