Understanding Epstein-Barr Virus and Mononucleosis

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Discover the history, structure, gene expression, pathogenesis, clinical manifestations, epidemiology, diagnosis, and treatment of Epstein-Barr virus (EBV) and mononucleosis. Learn about the identification of EBV as the cause of infectious mononucleosis in 1968, its association with various diseases, and the unique aspects of herpesviruses. Explore the kinetic classes of EBV genes and the lifelong latency of herpesviruses.


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  1. Epstein-Barr virus Shane C. McAllister, MD, PhD Pediatric Infectious Diseases Fellow Stony Brook Long Island Children s Hospital

  2. Overview History of EBV and mononucleosis EBV structure and gene expression Pathogenesis/Clinical manifestations Epidemiology Diagnosis Treatment Cases

  3. History of EBV and mononucleosis

  4. INTRODUCTION Infectious mononucleosis (IM) was first recognized in1920 however the etiology was unknown The heterophile test was discovered to be diagnostic for Infectious Mononucleosis in 1932 A viral cause of mononucleosis was suspected in the 1960s when a laboratory worker became ill while working with Burkitt lymphoma tissue samples

  5. INTRODUCTION In 1968, Epstein-Barr Virus was actually identified as the cause of Infectious Mononucleosis Since the initial discovery, EBV has been implicated in a wide variety of both benign and malignant diseases

  6. EBV structure and gene expression

  7. Herpesviruses 8 herpesviruses known to infect humans Strict species specificity Closely related rodent and non-human primate strains used as animal models

  8. Herpesviruses Large double-stranded DNA Viruses 84 different proteins Maintenance/replication of genome in host cell nucleus

  9. Herpesviruses Life-long latency with periodic lytic reactivation Control of infection requires cellular and humoral immunity

  10. Kinetic Classes of EBV Genes Latency LMP-1, EBNAs Immediate Early: initiate lytic cycle Zta, Rta Early: condition the host cell environment and synthesize viral DNA EA-D Late: structural components of capsids/mature virions gp350

  11. Pathogenesis/Clinical manifestations

  12. DISEASE ASSOCIATIONS Infectious Mononucleosis Chronic Infectious Mononucleosis Burkitt Lymphoma Nasopharyngeal carcinoma Hodgkin Lymphoma Lymphoproliferative disease X-linked Lymphoproliferative disease Oral Leukoplakia (AIDS)

  13. PATHOGENESIS EBV infection is considered immunopathologic rather than tissue destructive EBV initially infects and replicates in the oropharyngeal epithelial cells B-cells are subsequently infected Infected B-cells disseminate throughout the lymphoreticular system

  14. PATHOGENESIS EBV infection triggers an impressive but self-limited immune response Infected B-cells are transformed and secrete a diverse group of antibodies Heterophile antibodies Antibodies to specific EBV antigens Various auto-antibodies EBV induced polyclonal activation of B- cells also leads to an increase in serum immunoglobulins

  15. PATHOGENESIS Infected B-Lymphocytes induce T- Lymphocyte proliferation Manifested as Atypical Lymphocytosis Proliferation of reactive T-cells and infected B-cells leads to Lymphadenopathy Hepatosplenomegaly

  16. CLINICAL MANIFESTATIONS SYMPTOM % RANGE (%) SORE THROAT MALAISE HEADACHE ANOREXIA MYALGIAS CHILLS NAUSEA ABDOMINAL DISCOMFORT COUGH VOMITING ARTHRALGIAS 82 57 51 21 20 16 12 9 5 5 2 5 2 70 - 88 43 - 76 37 - 55 10 - 27 12 - 22 9 - 18 2 - 17 2 - 14 5

  17. CLINICAL MANIFESTATIONS SIGNS LYMPHADENOPATHY PHARYNGITIS FEVER SPLENOMEGALY HEPATOMEGALY PALATAL ENANTHEM JAUNDICE RASH % 94 84 76 52 12 11 9 10 RANGE (%) 93 - 100 69 - 91 63 - 100 50 - 63 6 - 14 5 - 13 4 - 10 0 - 15

  18. PHYSICAL FINDINGS EXUDATIVE PHARYNGITIS

  19. PHYSICAL FINDINGS TONSILLAR HYPERTROPHY

  20. EBV Physical Findings Rash and Antibiotics Nonspecific maculopapular eruption associated with administration of Ampicillin/Amoxil (50 100%) May be associated with other -lactam antibiotics (40 60%) Usually develops 7 10 days after the first dose Does not represent Penicillin allergy Mechanism is unclear Transient hypersensitivity reaction Immune complex production

  21. Complications of Primary EBV ORGAN/SYSTEM LIVER: COMPLICATIONS Abnormal Liver Function Tests (80 90%) Clinical jaundice (5%) Fulminant hepatitis (rare) RESPIRATORY: Airway Obstruction (<5%) Interstitial Pneumonitis (Rare) HEMATOLOGIC: Thrombocytopenia (25-50% Mild/Mod) Neutropenia (50 80% - Mild/Mod) Pancytopenia (Rare) Hemolytic Anemia (3%) Aplastic Anemia (Rare)

  22. Complications of Primary EBV ORGAN/SYSTEM SPLEEN: COMPLICATIONS Splenic rupture (0.1 0.5%) Splenic Infarction RENAL: Hematuria Interstitial nephritis Glomerulonephritis CARDIAC: Myocarditis Pericarditis Arrhythmias

  23. Complications of Primary EBV ORGAN/SYSTEM SECONDARY INFECTION: COMPLICATIONS Streptococcal pharyngitis Secondary sepsis due to neutropenia IMMUNOLOGIC: Depressed T-cell immunity NEUROLOGIC: Encephalitis Aseptic Meningitis Guillain-Barre Syndrome Cranial nerve palsies Transverse Myelitis Optic Neuritis Cerebellar Ataxia Brachial Plexus Neuropathy

  24. Neurologic Complications May be the first or sole manifestation of EBV mononucleosis Occurs in 1 5% of cases Prognosis is generally good with 85% complete recovery Most frequent cause of death related to EBV Infectious Mononucleosis Diagnosis is difficult Heterophile is negative Atypical lymphocytosis is minimal or absent

  25. Neurologic Complications Because EBV may present atypically and has been associated with a myriad of neurologic diseases, EBV should be considered in all acute neurologic illnesses of unknown etiology in the Pediatric population Connelly et al., Pediatr Neurol 1994; 10: 181-184

  26. INFECTIOUS MONO IN CHILDREN Compared with adolescents, young children more commonly had the following features: URI symptoms Rash Splenomegaly and/or Hepatomegaly Higher peak leukocyte counts with fewer Atypical Lymphocytes More frequent neutropenia

  27. Epidemiology

  28. EPIDEMIOLOGY Antibodies to EBV found in all populations Lower socioeconomic groups- higher prevalence By adulthood, 90 - 95% of most populations have demonstrable antibodies In the US, EBV seroconversion occurs before age 5 years in 50% of the population Second wave in the second decade of life No predilection for male or female

  29. EPIDEMIOLOGY In the US - 45.2 cases/100,000/year The incidence is highest in the 15 - 24 year-old age group College and military populations have the highest morbidity Not a reportable disease No clear seasonal pattern

  30. Diagnosis

  31. DIFFERENTIAL DIAGNOSIS OF MONO-LIKE SYNDROME Rubella virus Diphtheria HIV Malignancies Epstein-Barr virus Cytomegalovirus Toxoplasma gondii Adenovirus Human herpesvirus 6/7 Hepatitis A Influenza A and B

  32. DIFFERENTIAL DIAGNOSIS OF MONO-LIKE SYNDROME CMV mononucleosis is most frequently confused with EBV: Patients are generally older (Adults) Pharyngitis and lymphadenopathy less common Fever and malaise are the major manifestations Heterophile negative

  33. Atypical Lymphocytes Activated T cells responding to the EBV-infected B-cells Features of Atypical Lymphs: Larger than mature Lymphocytes Have vacuolated basophilic cytoplasm

  34. DIAGNOSIS ATYPICAL LYMPHOCYTES

  35. Heterophile Antibody Test Heterophile antibodies comprise a broad class of antibody characterized by ability to agglutinate antigens on RBCs from different mammalian species IM heterophile Ab (IgM) does not react with EBV- specific antigens characterized by its ability to react with beef, sheep and horse RBCs The antigen that stimulates this heterophile ab is unknown

  36. Heterophile Antibody Test Replaced by the monospot slide test (Antigen-coated beads on a slide) 15% of patients with IM may be initially heterophile negative and become positive within 2 3 weeks High false negative rate in children less than 4 years (>50%) False positive rate - 7% Remains positive for up to 9 months Sensitivity and specificity: 85%/97%

  37. MONOSPOT NEGATIVE POSITIVE

  38. Sumaya et al., Pediatrics 1985; 75: 1011 - 1019

  39. FALSE POSITIVE MONOSPOT Collagen Vascular diseases Leukemia/Lymphoma Malaria Pancreatic Carcinoma Viral Hepatitis Other

  40. EBV SEROLOGY The appearance of antibodies induced by EBV specific antigens correlates with the phase of replication IgM antibody to VCA appears at the onset of symptoms and typically disappears within 1 3 months IgG antibody to VCA begins to rise shortly after the onset of symptoms Peaks at 2 3 months Gradually decreases to a steady-state and persists for life

  41. EBV SEROLOGY Antibodies to EA are not always detectable IgG to EA begins to rise at the onset of symptoms Peak concentration occurs at 3 4 weeks Subsequently decreases and disappears Antibodies to EBNA appear during the convalescent period and persist for life along with anti-VCA IgG Past infection: No anti-VCA IgM (Potential for false-positives) No anti-EA IgG

  42. DIAGNOSIS

  43. Interpretation of EBV Serology INFECTION ANTI-VCA-IgM ANTI-VCA-IgG ANTI-EA ANTI-EBNA NONE NEGATIVE NEGATIVE NEGATIVE NEGATIVE ACUTE POSITIVE POSITIVE POS/NEG NEGATIVE RECENT POS/NEG POSITIVE POS/NEG POS/NEG PAST NEGATIVE POSITIVE NEGATIVE POSITIVE

  44. EBV SEROLOGY Effective lab diagnosis can be made on single acute phase serum sample Antibody response appears rapidly (onset of symptoms) Acute and Convalescent phase serum will not demonstrate a significant change in antibody titer

  45. EBV SEROLOGY Literature supports the general concern that there is considerable variation in the performance of serological test kits for EBV and other infectious agents VCA-IgM Cross-reactivity occurs Especially with other herpesviruses (CMV)

  46. EBV - DIAGNOSIS The ability of EBV to maintain lifelong latency with low levels of replication and viral shedding results in enduring antigen exposure and continued humoral immune response Variation of EBV antibody titers may be due to reactivation of latent virus due to infection with another virus and development of cross-reactive antibodies

  47. EBV - DIAGNOSIS Important to be aware of nuances of serologic testing as well as viral detection for latent viruses such as EBV Must be cautious with utilization of serologic testing/DNA detection as the sole means for establishing causal relationship between illness and EBV infection

  48. Treatment

  49. TREATMENT Supportive care Avoid contact sports Corticosteroids for selective complications Airway obstruction Massive splenomegaly Myocarditis Hemolytic Anemia/ITP Acyclovir No clearly documented benefit

  50. ANTIVIRAL TREATMENT 5 randomized clinical trials conducted to evaluate treatment of Infectious Mononucleosis with Acyclovir (339 patients) Studies showed no statistically significant benefit or clinical effectiveness Met-analysis also showed no significance No evidence that therapy shortens duration of symptoms or prevents complications

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