Secondary immune deficiencies and HIV-1 infection

Question 1

What are 7 causes of secondary immune deficiencies?

Answer 1

Malnutrition (commonest globally)

Infectious Diseases e.g. HIV

Environmental stress

Age Extremes: Prematurity + old age

Surgery + trauma, splenectomy

Immunosuppressive drugs

Genetic + metabolic diseases

Question 2

What are signs and symptoms of secondary immune deficiencies?

Answer 2

Infections: Severe, persistent, recurrent, unusual

Autoimmune conditions (cytopaenias) and allergic disease

Persistent inflammation

Cancer (viral associated EBV, HHV-8)

Question 3

Which small molecules can cause immune deficiencies?

Answer 3

• Glucocorticoids + mineralocorticoids
• Cytotoxic agents: Methotrexate, mycophenolate, cyclophosphamide + azathioprine.
• Calcineurin inhibitors: Cyclosporine + tacrolimus
• Antiepileptic drugs (phenytoin, carbamazepine, levetiracetam)
• DMARD (sulphasalazine, leflunomide)

Question 4

Which JAK inhibitors can cause immune deficiencies?

Answer 4

• Tofacitinib
• Upadacitinib
• Ruxolitinib

Being used in increasing no. diseases e.g. RA, GvHD

Can cause antibody deficiency

A/w increased risk of reactivation of herpes zoster

Question 5

Which drug class can cause TB reoccurance?

Answer 5

Anti-TNF agents

Screen for latent TB

If detected give TB prophylaxis

Question 6

Which cancers can present with secondary immune deficiencies?

Answer 6

B + plasma cell cancers (antibody deficiency syndromes are most common).

Chemotherapy, biological agents, + radiotherapy can leads to loss of immune cells + immune deficiency.

Question 7

Which specific B-cell lymphoproliferative disorders are associated with secondary immune deficiency?

Answer 7

Multiple myeloma

Chronic lymphocytic leukaemia

Non Hodgkin’s lymphoma

Monoclonal gammopathy of uncertain significance

Question 8

What is Good’s syndrome?

Answer 8

Thymoma + antibody deficiency

Combined T + B cell (absent) defect

Increased risk of CMV, PJP + muco-cutaneous candida

As thymus involved in control of central tolerance, increased risk of AI disease (Pure red cell aplasia, Myasthenia gravis, Lichen planus)

Question 9

What are appropriate investigations for secondary immune deficiencies?

Answer 9

FISH

FBC: Hb < 10g/L, Neutrophil, Lymphocyte + Platelet count

Immunoglobulins: IgG, IgA, IgM, IgE

Serum complement: C3, C4

HIV test: 18-80y

Question 10

What is serum protein electrophoresis?

Answer 10

Separation of serum proteins by charge

Detection of discrete bands: monoclonal identified by immunofixation with labelled IgG, IgA, IgM anti-sera

SPE can miss free light chain disease (seen in 20% multiple myeloma cases): hence measurement of free light chains is essential for work up of B cell LPD.

Question 11

What are second line investigations for secondary immune deficiencies?

Answer 11

Measure concentration of vaccine antibodies:

• Tetanus toxoid: Protein antigen
• Pneumovax vaccine: Carbohydrate antigen (all 23 serotypes or to individual pneumococcal serotypes)

Question 12

What are third line investigations for secondary immune deficiencies?

Answer 12

Analysis of naïve + memory T + B cell subsets

Assessment of IgG subclasses

Determination of anti-cytokine + complement antibodies

Genetics (whole exome or whole genome sequencing in cases where it is uncertain whether primary or secondary immune defect)

Question 13

What is the management of secondary immune deficiencies?

Answer 13

Treat underlying cause

Advise on measures to reduce exposure to infection

Immunisation against respiratory viruses + bacteria + offer vaccines to household contacts

Education to treat bacterial infections promptly: May require higher doses + longer courses (co-amoxiclav 625mg TDS for 10-14d rather than 375mg for 5-7d)

Prophylactic abx for confirmed recurrent bacterial infection (>,2/y)

Question 14

What type of immunodeficiency is more common?

Answer 14

Secondary immune deficiency

Question 15

Describe the secondary immune deficiency caused by measles

Answer 15

Immune defect lasts months-years

Increases morbidity + mortality esp. due to secondary bacterial infection/ unexplained diarrhoeal illness

Question 16

Describe the secondary immune deficiency caused by TB

Answer 16

Depresses cell mediated immune response- detected as failed Mantoux test

In tx their immune system reconstitutes, sees infections the patient has experienced + mounts an inflammatory response

Question 17

Describe the secondary immune deficiency caused by HIV

Answer 17

Residual immune dysfunction persists despite successful ART

Increased inflammation, cellular/ soluble markers of immune activation

Question 18

Give an example of a glucocorticoid causing immune deficiency

Answer 18

>10mg/day prednisolone linked to increased rate of antibody loss

Affects cellular + humoral immunity

Increased susceptibility to bacterial + viral infections

Question 19

How do calcineurin inhibitors cause immune deficiency?

Answer 19

Cause cellular immune deficiency

Target dendritic cells + CD4 follicular function

Impact on peoples ability to respond to vaccines

Question 20

Name a biologic/ cellular therapy that can cause immune deficiency

Answer 20

Rituximab (anti-CD20 antibodies)

Increases risk of antibody deficiency

Increased risk of secondary infection

Increased risk of fungal infection e.g. PCP, so give PCP prophylaxis

Question 21

What must be evaluated in history taking in a patient with suspected immune deficiency?

Answer 21

Clinical hx of infection + evidence: sputum cultures, response to abx

Alarm Sx for B cell malignancy

Hx for other illnesses: haematological malignancies, Hep B/C, TB

FH infection, AI, cancer

Medication hx

Vaccine hx

Question 22

What are the front line chemical investigations for immune deficiency?

Answer 22

Renal + liver profile

Calcium + bone profile

Total protein + Albumin

Urine protein/ Cr ratio

Serum protein electrophoresis

Serum free light chains

Question 23

What could cause isolated reduction in IgG?

Answer 23

Protein losing enteropathy

Prednisolone doses (cumulatively) >10mg/day

Question 24

What could cause a reduction in IgG and IgM?

Answer 24

B cell neoplasm

Hx of exposure to Rituximab

Question 25

What could cause a reduction in IgG and IgA?

Answer 25

Primary antibody deficiency

Question 26

What are monoclonal proteins associated with?

Answer 26

Multiple myeloma (IgG + IgA)

WMG (IgM)

NHL

MGUS

Question 27

How can SPE sometimes not detect multiple myeloma?

Answer 27

Some myeloma neoplasms just secrete light chains which are freely excreted into the urine so won’t be detected on SPE

SPE shows combination of heavy + light

Measurement of FLC in urine or serum essential

Question 28

If concentrations of vaccine antibodies are low, what should be done?

Answer 28

Offer test immunisation with Pneumovax II + tetanus

Failure to respond to vaccination is part of diagnostic criteria for numerous primary antibody deficiency syndromes + for receipt of IgG replacement therapy

Question 29

Why are vaccine antibody concentrations measured in the work up for immune deficiencies?

Answer 29

Tetanus: most of the UK have tetanus toxoid

Indirect marker of how well T cells speak to B cells to make antibodies

Pneumovax: T cell independent analysis of antibody production

Question 30

What is the criteria for IgG replacement therapy?

Answer 30

Underlying cause of hypogammaglobinaemia irreversible or CI

OR

Hypogammaglobinaemia a/w drugs, therapeutic monoclonal antibodies targeted at B cells + plasma cells, post-HSCT, NHL, CLL, MM

AND

Recurrent/ severe bacterial infection despite continuous oral prophylaxis for 6m

IgG <4

Failure of vaccine response to unconjugated pneumococcal vaccine challenge

Question 31

Give 4 features of HIV virology

Answer 31

4 lineages M, N, O, P (M most common)

Slow evolution

Double stranded RNA

Retrovirus

Question 32

Describe the replication of HIV virus

Answer 32

Binds to CD4 + then to chemokine co-receptor CCR5 or CXCR4

Replicates via a DNA intermediate

Integrates into host genome

HIV DNA transcribed to viral mRNA

Viral RNA translated to viral proteins

Packaging + release of mature virus

Question 33

Describe the natural history of HIV as defined by viral replication

Answer 33

Acute: Flu-like illness in 70%, viral load peaks then dips after 3-6m to a set point

Asymptomatic but progressive: Quiescent for 8-10y

AIDS: increase in viral replication as immune system collapses

Question 34

Describe the risk of transmission through the natural history of HIV

Answer 34

Directly proportional to amount of virus in blood

Lots of transmission often in acute phase

Risk of transmission declines in asymptomatic, though more people in this category

Risk increases again but when pt is v sick

Question 35

Why must combination therapy be used to treat HIV?

Answer 35

HIV not very good at replicating itself- huge no. of variants

Short generation time + long duration of infection

With progression of disease, get increased viral diversity so need to target different stages of the viral life cycle to reduce risk of drug resistance

Question 36

Why do patients with HIV need to take lifelong antivirals?

Answer 36

Integration of HIV provirus into memory CD4 T cells within 72h of infection leads to formation of long lived reservoir of latent infection which doesn’t respond to current ART

Question 37

Describe the T cell immunology in natural HIV infection

Answer 37

Dip in CD4 T cells in blood

Some partially recover

Slow decline 8-10y

Rapid decline when in AIDS phase

Question 38

Describe the CD4 T cell count in the mucosa in HIV infection

Answer 38

Profound depletion of CD4 T cells

Dont really receover

Dissociation between counts in blood vs tissues

Question 39

What is the immune deficiency often linked to in HIV?

Answer 39

Immune system not responding properly to immune activation

With acute infection get increase in immune activation- generating a pro-inflammatory response

Capacity to make new CD4 T cells reduces with progressive infection

Question 40

Describe the humoral immunology in HIV infection

Answer 40

Acute: IgM to envelope protein gp41 + Gag

Later ~12w: neutralising antibodies with capacity to prevent viral infection of that strain- but virus will have mutated

Question 41

Describe how viral load differs depending on humoral response to HIV infection

Answer 41

Good B cell response: antibodies inhibiting replication by phagocytosis, fixation of complement. Bring down viral load

Poor/ ineffective antibodies: have high viral load set point, doesn’t vary over asymptomatic phase. Make antibodies targeting conserved parts of the HIV envelope- broadly neutralising antibodies

Question 42

List 5 features of untreated HIV immunology

Answer 42

CD4 T cell depletion

Chronic immune activation

Impairment of CD4 + CD8 T cell function

Disruption of lymph node architecture + impaired ability to generate protective T + B cell immune responses

Loss of antigen-specific humoral immune responses: tetanus vaccine + alloimmune responses

Question 43

What happens to the immune system in acute HIV?

Answer 43

Significant increase in HIV viral load in blood

Significant risk of viral transmission

Transient reduction in blood CD4 T cells

Increase in CD8 T cell immune response coinciding with drop in VL

CD8 T cell activation

Induction of HIV specific antibodies

Question 44

What tests can be used to diagnose HIV?

Answer 44

4th gen combined antigen/ antibody tests: 1m post acquisition

Rapid POC: results in <20mins less sensitive

RNA tests when serological tests are -ve but high clinical suspicion of acute infection

RNA/ DNA tests for kids <18m

Question 45

What baseline investigations should be performed in HIV?

Answer 45

FBC

Renal, liver, bone, lipid profile, HbA1c

Sexual health screen

Screen for latent TB using IGRA

CXR + ECG
Toxoplasma serology

Question 46

Which HIV specific tests need to be performed?

Answer 46

HIV viral load

HIV genotype for ART drug resistance

HIV tropism test to confirm co-receptor use (potential for CCR5 antagonists)

HLA-B*5701 to avoid Abacavir + risk of hypersensitivity reaction SJS/TEN

CD4 T cell count + %

CD4: CD8 T cell ratio

Question 47

What is viral load set point correlated with? What is the magnitude influenced by?

Answer 47

Long term outcome

Viral genotype

CD8 T cell immune response

Host genetics (HLA + CCR5)

Immune activation

Question 48

Give examples of infections seen at different cell counts in HIV

Answer 48

500: bacterial/ fungal skin infection, HSV, HZV
400: Kaposi sarcoma
300: TB
200: PCP
100: Toxoplasmosis, CMV, EBV brain lymphoma
75: Mycobacterium avium complex (MAC)

Question 49

How does kaposi and TB infection differ depending ono cell count?

Answer 49

Good: Pulmonary TB

~400: Cutaneous Kaposi sarcoma

Low: Miliary TB

~50: Kaposi affecting lungs + GIT

Question 50

Which drugs can be used as part of antiretroviral therapy?

Answer 50

NRTI

NNRTI

Protease inhibitors

Integrase inhibitors

Question 51

How does ART work in HIV?

Answer 51

Prevents new cells being infected but can’t eliminate infection once HIV has integrated into hist DNA

Question 52

What happens if ART is stopped?

Answer 52

HIV replication re-commences + will be detectable in blood 2-3w later

Question 53

Does ART change chronic immune inflammation?

Answer 53

No, does not reverse chronic immune inflammation

This is a RF for cardiovascular, liver, bone + CNS disease

Question 54

What needs to be monitored in patients with HIV?

Answer 54

Compliance with drug therapy + any SEs

Viral load every 6m

Potential liver, renal, bone + lipid toxicity

Cardiovascular + osteoporosis risk

Sexual health + vaccine uptake

Question 55

What is the concept of the shock and kill strategy?

Answer 55

Shock: drugs reactivate latent HIV in CD4 infected T cells

Kill: activated NK or CD8 T cells eliminate HIV infected cells

Continue ART to prevent infection of new cells

Question 56

What are broadly neutralising antibodies?

Answer 56

Neutralise multiple strains: bind to conserved envelope epitopes

In 1-30% of patients

May also activate other immune cells to help destroy HIV infected cells