1. CHRONIC GRANULOMATOUS DISEASE (CGD)��Pathogenesis and Diagnosis���Adel Almogren, BCLS, MS, PhD�Assistant Professor of Immunology
2. Topics to be considered Phagocytes & Pahgocytosis
Review of NADPH Oxidase Pathway
Mutations in CGD Patients
Pathogenesis in CGD and clinical characteristics
Diagnosis of CGD
Treatment of CGD
Case Study
3. Chronic Granulomatous Disease Rare (1/200,000) inherited disorder of the reduced nicotinamide dinucleotide phosphate oxidase complex (NADPH) - may be higher�
Phagocytes defective in production of microbicidal reactive oxidant superoxide anion and metabolites (hydrogen peroxide, hydroxyl anion, & hypohalous acid�
Patients suffer from life-threatening bacterial & fungal infections. Dramatic inflamatory response leads to granuloma formation
4. CGD - History First described in 1957 by Good et. al. As fatal granulomatous disease of childhood�
CGD granulomas had similarities to other granuloma forming diseases (Wegener granulomatosis, brucellosis, sarcoidosis, Hodgkin’s disease, etc.)�
Combination of recurrent suppurative and inflammatory complications in childhood recognized - distinct clinical syndrome�
Originally thought to be X-linked as only diagnosed in boys
5. History continued 1960’s CGD established as a disease of phagocytes
Neutrophils exhibit normal phagocytic activity
Bacteriocidal activity against S. aureus impaired�
1990’s to present - Actual defects elucidated
CGD genetically heterogeneous, caused by mutation in any one of four structural components of NADPH oxidase complex
Mouse knockout models created
Gene therapy trials now underway
9. Current Cellular Phenotype & Genotype in CGD
10. Mutations in CGD In X91 103 specific mutations identified in 13 exons of gp91phox CYBB gene
Approximately 90% come from X linked carriers
X linked CDG = Heterogeneous spectrum of mutations
Two-thirds of cases are X-linked, affecting the gp91 unit of cytochrome b558 (gene CYBB), mutations are unique to individual families.
Similar heterogeneity for the p22 phox gene CYBA and p67 phox CGD gene NCF2.
In contrast, p47 phox CGD - majority due to GT deletion (exon two in NCF1 gene) - frameshift yielding premature stop codon at amino acid 51.
12. Pathogens in CGD Recurrent infections with catalase producing pathogens (Staph. Aureus, Serratia marcescans, Nocardia Aspergillus sp. )
occurring at sites acting as environmental barriers:
Skin -Lymph nodes
Liver or spleen -Lungs
Gastrointestinal tract
Catalase negative pathogens can not degrade their own H2O2 providing exogenous source hypohalous acid formation
Other factors besides catalase
Not susceptible to all catalase + organisms
CGD knockout mice - Catalase-deletant strains of Aspergillus nidulans as virulent as wild type
13. Leucocyte Adhesion Def. Type1 Decreased or absence of CD11/CD18 expressionLeucocyte Adhesion Def. Type1 Decreased or absence of CD11/CD18 expression
14. Pathogens in CGD
15. Pathogens in CGD
18. Inflammatory Complications in CGD Chronic inflammation
skin ulceration, pneumonitis, inflammatory bowel disease.
Exuberant & persistent tissue granuloma formation
Mechanism of abnormal inflammation - largely unknown
Inability of CGD neutrophils to inactivate proinflammatory chemoattractants via reactive oxidants
19. Aspergillus pneumoina & liver abscessAspergillus pneumoina & liver abscess
20. Exuberant granuloma formation in chronic granulomatous disease (CGD). Wound dehiscence and impaired wound healing at surgical incision sites due to dysregulated inflammatory responses in an X-linked CGD patient.�Wounds take a very long time to heal in these patients. They must be constantly washed and cared for every day.
Exuberant granuloma formation in chronic granulomatous disease (CGD). Wound dehiscence and impaired wound healing at surgical incision sites due to dysregulated inflammatory responses in an X-linked CGD patient.Wounds take a very long time to heal in these patients. They must be constantly washed and cared for every day.
22. A)normal, B) carrier has both populations C) CGD pateintA)normal, B) carrier has both populations C) CGD pateint
23. CGD by Flow Cytometry Small whole blood sample is stimulated to undergo the oxidative burst with phorbol myristate acetate in the presence of Dye.
Dihydrorhodamine123 when oxidized is fluorescent.
Fluorescence is quantitated. Results expressed as ratio of Fl. Stimulated over Fl. Unstimulated.
CGD test by Flow Cytometry can detect CGD patients, carriers, and can suggest the genotype of the CGD patient.
24. Case Study
26. Treatment of CGD Prophylaxis with antibiotics
trimethoprim-sulfamethoxazole
itraconazole
Interferon-gamma
does not increase NADPH oxidase (1st yes, 2nd large NIH study - no)
Augmentation of oxidant-independent antimicrobial pathways
TNF, granule protein synthesis, MHC II expression, FC gamma receptors - all increased
27. Granulocyte transfusion
Has been used in life threatening infections
No prospective studies
Many possible adverse reactions
Bone marrow transplantation
Curative 60% of time
Due to morbidity and mortality - not routine use
May be revisited with stem cell transplantation
Treatment of CGD
28. Gene Therapy
Ideal candidate for hematopoietic stem cell gene therapy
engraftment of stable normal myeloid stem cell is curative
only 3-10% normal neutrophils required for normal protection Treatment of CGD
29. NIH Gene Therapy Clinical Trial
5 patients with p47phox deficient CGD
Autologous CD34 peripheral blood stem cells
transduced in vitro with retrovirus vector containing p47phox cDNA
Infused without bone marrow conditioning
.004 to .05% circulating corrected granulocytes
2 of 5 patients had detectable corrected granulocytes after 6 months
Treatment of CGD
