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East Tennessee State University Quillen College of Medicine An Organ, A Disease and A Few Facts About Treatment. Kanishka Chakraborty, MD Assistant Professor Department of Internal Medicine Division of Medical Oncology/Hematology
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East Tennessee State University Quillen College of MedicineAn Organ, A Disease and A Few Facts About Treatment Kanishka Chakraborty, MD Assistant Professor Department of Internal Medicine Division of Medical Oncology/Hematology References in slide 61
“Hallmark of this organ’s absence will be seen in our blood” • Howell-Jolly bodies are round, purple staining nuclear fragments of DNA in the red blood cell.
Etiologies of Splenomegaly • Congestive: Cirrhosis, CHF and Thrombosis of portal, hepatic and splenic veins. • Malignancy: Lymphoma, Chronic Myeloid Leukemia, Essential Thrombocytosis, Polycythemia Vera, Primary Myelofibrosis, Metastatic tumors. • Infection: Infectious Mononucleosis, CMV, Hepatitis, Brucellosis, Tuberculosis, Malaria, Leishmaniasis and Infective Endocarditis. • Inflammation: SLE, Sarcoid and Felty syndrome • Infiltrative: Gaucher, Neimann-Pick, Glycogen storage disease and Amyloid • Hematological: -Hemolytic anemia, Sickle cell disease and Use of G-CSF
Presence of JAK2 or MPL AND Absence of BCR-ABL1 Differential diagnosis of PMF: -Metastatic cancer -Lymphoid malignancy -CML -MDS -CMML -AML Presence of monocytosis >1 x109/L directs toward CMML and Acute Megakaryoblastic leukemia can mimic PMF presentation Presence of +9 or 13q- favors PMF
Historical Perspective Galen (129-200 AD) • Recognized blood as one of the four 'humors' (the other three being phlegm, black and yellow bile). • Recognized plethora as an imbalance of the humors, where blood dominated over the others. • Phlebotomy was practiced to maintain humoral equilibrium and became a universal treatment for a variety of unrelated conditions till the 19th century. • Aggressive phlebotomy is believed to have contributed to the death of George Washington. • In 1628, William Harvey (1578-1657), • Demonstrated the circulatory nature of blood. • Disproved many of Galen's fallacies including the belief that blood stagnation causes illness. • This was the beginning of the end of phlebotomy as a remedy for all diseases.
Historical Perspective 1845:First report of CML entitled : 'Case of hypertrophy of the spleen and liver in which death took place from suppuration of the blood'. The clinical description of the patient was similar to other case by Rudolph Virchow. John Hughes Bennett 1879: 1st description of primary myelofibrosis: “Two cases of leukemia with peculiar blood and bone marrow findings”. • Described two young patients with massive splenomegaly, circulating nucleated red blood cells, and increased number of morphologically abnormal leukocytes. ‘Splenic-medullary leukemia' and 'pure splenic leukemia’. • Different from CML because of the presence of marrow • fibrosis and extensive extramedullary hematopoiesis. Gustav Heuck (1854-1940)
William Dameshek (1900-1969) • Founder of Blood, the prime core clinical journal of hematology, in 1946. • He is also credited with describing the concept of myeloproliferative diseases in 1951. -PV, ET, PMF and CML described by Dr. Dameshek as classic MPN -PV, ET and PMF known as bcr-abl negative MPN. • He participated in the first studies of nitrogen mustard in various hematological malignancies, widely considered the first uses of chemotherapy in malignant diseases. • Dr. Dameshekwas also the first one who described chronic lymphocytic leukemia (CLL), a common form of leukemia in adults.
Incidence: • PMF is least common among chronic Myeloproliferative disorders. • One study reported an estimated incidence of 1.5 per 100,000 per year in Olmsted County, Minnesota. • Occurs mainly in middle aged and elderly patients. • Median age at presentation is 67 years. • Approximately 5 and 17 percent of the patients are diagnosed before the age of 40 and 50 years
Clinical Presentation: • Most common presentation is with severe fatigue, 50 to 70 percent of patients. • 25 to 50 percent of patients present with Splenomegaly. • Weight loss . • Low-grade fever. • Night sweats. • Approximately 15 to 30 percent are asymptomaticand diagnosis is made during investigation for hepato-splenomegaly and/or abnormal blood indices.
Disease Features: • Pruritus, not correlated with overall survival, karyotype, risk category and plasma level of cytokines. • Splenomegaly. • Hepatomegaly. • Pulmonary hypertension, associated with reduced overall survival. • Thrombotic events: Both arterial and venous thrombosis happen. Incidence is similar to Essential thrombosis (ET) but lower than Polycythemia Vera (PV). Portal vein thrombosis is a well recognized complication. • Extramedullary Hematopoiesis: Beside Liver and Spleen, other common sites are thoracic vertebral column, Lymph node, retroperitoneum, Lungs, GI, skin and other sites. (Post Splenectomy, other EMH sites can enlarge, this may be particularly challenging in patients developing liver failure). • Bone and Joint involvement.
PMF, post-PV and post-ET MF include following laboratory features: • Anemia, 28% cases of PMF. • Leuko-erythroblastosis. • Dacrocytosis. • Leukocytosis/thrombocytosis. • Elevated LDH. • Increased blasts or CD34+. • Bone marrow fibrosis. • Osteosclerosis. • Angiogenesis.
Anemia: 50 percent of patients will have Hgb of <10.0 -Decreased in medullary hematopoietic sites. -Ineffective hematopoiesis in EMH sites. -Splenic sequestration. -Blood loss. -Autoimmune Hemolysis. -Dilutional. -MPL mutation. -PBS features (Anisocytosis, Polikilocytosis, Tear drop cells, nucleated red blood cell and Polychromasia).
Platelet and WBC: Variable abnormalities on presentation. 11-13 patients present with increased count and 8-26% with low count. • CD34+ cells: An Italian study showed 400 times increase compared to normal healthy subjects with an average of 92 CD34 cells/microL in PMF. Other abnormal blood parameters: • Elevated LDH, Uric acid, Leucocyte alkaline phosphatase, Alkaline phosphatase and B12. • Bone marrow aspiration and Biopsy: -“Dry" tap. -Neutrophilic and megakaryocytic hyperplasia. -Granulocytes with hyperlobulation -Erythroid precursors may be normal or increased. • Biopsy shows: -Bone marrow sinusoids are expanded and shows presence of intravascular hematopoiesis. -Fibrosis is typically extensive and visualized better with a silver stain (reticulin) or a trichrome stain (mature collagen)
“Classic ph -” MPN Common Characteristics: • Despite differentiation / maturation; they originate from a single progenitor cell. • Normal cellular maturation. • Striking overlap in clinical presentation. • Propensity to evolve into post PV or post ET MF. • Possibility to transform into AML. • PV,ET relatively indolent. Modest reduction of lifespan. • PMF has a severe course in most cases. Survival significantly affected.
PMF: (Pathogenesis) • Clonal myelo-proliferation (Chromosomal abnormality and JAK2/STAT pathway deregulation) and secondary inflammation. • Myeloid cell derived transforming growth factor-beta, PDGF, FGF-beta, VEGF mediate BM fibrosis, osteosclerosis and angiogenesis. • Abnormal cell-cell interaction leads to -Abnormal release of cytokines, chemokines and extracellular matrix metalloproteinase. -Also contributes to release of CD34 myeloid progenitors in peripheral circulation. • Elevated level of IL8, IL10, IL15 and IL2 associated with constitutional symptoms, cachexia, inferior overall survival and poor leukemia free survival
Molecular Basis of MPN • CML : BCR/ABL rearrangement. • Systemic Mastocytosis: kit mutations. • Information concerning molecular abnormalities of CLASSIC ph- MPN has been scanty until 2005. • In 2005 several independent groups used different approaches to identify a recurrent mutation in most MPN patients. • MPN, stem cell derived monoclonal or polyclonal hematological malignancies may have a genetic predisposition • Major mutation is JAK2V617F, other mutations are MPL, LNK, CBL, TET2, ASXL1, IDH, IKZF1 and EZH2 • Disease initiating mutation in MF is not known; also they are not disease specific and also can appear as secondary events
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JAK Family • One of 10 recognized families of non-receptor tyrosine kinases. • Mammals have four members of this family, JAK1, JAK2, JAK3 and Tyrosine Kinase 2 (TYK2) • Initially called Just Another Kinase, final publication used the term JAnusKinase. Proc NatlAcadSci U S A. 1989 March; 86(5): 1603–1607.
JAK Family • JANUS: Roman god with two faces, meaning ending and beginning, because they contain two symmetrical kinase-like domains.
JAK Family • JAK1: mediating the signaling of pro-inflammatory cytokines. JAK1 defective mice have defective lymphoid development and function. • JAK2 : JAK2 helps in transducing signals from several class I cytokine receptor (TpoR, EpoR and G-CSFR). Deficiency results in embryonic lethality at day 12 as a result of a failure in definitive erythropoiesis. • JAK3: Transmitting IL-2 signals. Defective mice have SCID • TYK2 : signaling of cytokines such as IL-12 and IL-23
In normal un-stimulated situation JAK2 is noncovalentlybound to class I receptors via N terminal FERM domain but it is in an inactive form. Binding of specific ligand like EPO to EpoR activates JAK2 signaling.
BCR-ABL negative MPN: • Direct or indirect dysregulation JAK2 by somatic acquired mutation. -Binding relieves negative regulation of catalytic activity imposed by JH2 domain -Activated JAK2 phosphorylates tyrosine residue on itself -This phosphorylated tyrosine residue works as a docking site for the recruitment and assembly of downstream signaling. -It results in activation of MAPK, PI3K and STAT proteins.
xx xx Protein tyrosine phosphatases, suppressors of cytokine signaling (SOCS), CBL (Casitas B lineage lymphoma) proteininhibitors of activated STATs (Signal Transducer and activator) etc provide negative feedback to this signaling.
Mutation that activates JAK2: • GT change in exon 14, that results in substitution of normal valine residue at position 617 by phenylalanine. • Mutation happens in JAK2 exon 12 too. • Constitutive activation of JAK2 in the absence of class I receptor stimulation. • Mutation takes of negative regulation imposed by JH2 domain. • Indirect mutation can happen due to activating mutation of MPL gene (It encodes TpoR) (Present in ET and MF but not in PV).
WHAT HAPPENS WITH JAK2 MUTATION: • Mutated JAK2 escapes negative regulation by SOCS3; even more it exploits SOCS3 to help in myeloproliferative activity. • SOCS3 is a strong negative regulator of EPO. • Mutated JAK2 hyperphosphorylates SOCS3 and stabilizes it. • Mutated JAK2 phosphorylates protein arginine methyltransferase 5 (PRMT5). Leading to inhibition of PRMT. • Promoting increased colony formation and leading to important contribution to the MPN phenotype.
Epigenetic Mutations: • TET2, IDH1, IDH2, ASXL1, EZH2. Cytogenetic mutation: • Gain of chromosome 9, deletions of 13q and 20q, trisomy 8 and partial trisomy of 1q Genetic Instability: • In Treated CML patients with residual ET found to have both JAK2V617F and BCR-ABL mutation. • Co-presence of JAK2 V617F mutation along with MPL W515, KIT D816V and JAK2 exon 12 mutation • V617F positive MPN may transform to V617F negative AML, suggesting transformation of stem cell that has not acquired JAK2 mutation proving in favor of genetic instability. • Presence of two different mutations in two different clones also suggest genetic instability.
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‘Bird’s eye view of PMF prognostic factors” • Unfavorable karyotype includes complex karyotype or trisomy 8, -7/7q-, i(17)q, -5/-5q, 12p- 0r 11q23 rearrangement. • Leukemic transformation is predicted by the presence of unfavorable karyotype or Platelet count <100x109 /L. • Presence or absence of JAK2. • Ten-Elevation Translocation-2 (TET2) • Isocitrate Dehydrogenase (IDH) • Nullizygosity for JAK2 46/1 haplotype • Low JAK2V617F • Increased plasma IL8, IL10, IL15 and IL2R No affect on survival or leukemic transformation in PMF Poor survival
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Treatment Options -Erythropoiesis stimulating agents -Corticosteroids -Androgen -Danazol -Thalidomide -Lenalidomide -Hydroxyurea -Cladribine -Splenectomy -Radiotherapy -Allogeneic SCT -Ruxolitinib -Pomalidomide -Other investigations agents (ATP mimetics, histone deacetylase inhibitors, hypomethylating agents, bevacizumab)
JAK Inhibitors/Phase I INCB018424 was associated with clinical benefits in patients with advanced myelofibrosis. A starting dose of 15 mg twice daily with individualized dose adjustment was found to be the most effective and safest dose . These durable improvements (median follow-up, >1 year) were independent of JAK2 mutational status or the cause of disease. The reduction in splenomegaly observed in most patients was not predicted, and it occurred without deterioration in hematologic variables or tumor-cell lysis
Phase III/ Ruxolitinib Controlled Myelofibrosis Study With Oral JAK Inhibitor Treatment I COMFORT I
COMFORT I • Randomized, double-blind, placebo-controlled Phase III study in patients with MF. • 9/09- 4/10. 89 sites in US, Australia and Canada. • Adults with PMF, post PV myelofibrosis, post ET myelofibrosis. Intermediate -2 or high risk. ECOG 3 or less. <10% peripheral blasts. Palpable spleen. Refractory, non-candidate or intolerant to available therapies. • 309 patients: 155 assigned to ruxolitinib (15 mg BID if PLT<200 or 20 mg BID if PLT>200). 154 received placebo. • Median follow-up 48 weeks.
COMFORT I Primary endpoint • Proportion of subjects achieving >35% reduction in spleen volume from baseline to Week 24 as measured by MRI or CT Secondary endpoints • Duration of the reduction from baseline in spleen volume. • Proportion of subjects with >50% reduction in total symptom score from baseline to Week 24 as measured by the modified MFSAF. • Overall survival.
COMFORT I Results: • The primary endpoint response rate was 41.9% vs 0.7% ( p<0.0001). • Mean reduction in spleen volume was 31.6% (8.1% increase in placebo). • In 67% of those achieving at least 35% decrease in size, this was maintained into for 48 weeks or more. • At least 50%symptom improvement at 24 weeks: 45.9% vs 5.3%. (mean improvement with ruxolitinib was 46.1% compared to mean worsening of 41.8%). • 13 deaths in ruxolitinib group (8.4%)vs 24 in placebo (15.6%) HR 0.5
COMFORT I Other facts: • Among patients in whom the study drug was interrupted, symptoms returned to baseline over about a week. • 2 patients in ruxolitinib group developed AML. • Reduction of JAK2V617F allele burden: 10.9% at week 24 and 21.5% at week 48. • Reduction in plasma levels of CRP and proinflammatory cytokines (TNFα and IL-6)
COMFORT II • 219 patients. Randomized, open-label Phase III study of ruxolitinib vs best available therapy in patients with MF. Primary endpoint: • Proportion of subjects achieving >35% reduction in spleen volume from baseline to Week 48 as measured by MRI Secondary endpoints : • Leukemia-free survival • Overall survival • Progression-free survival • Proportion of subjects achieving a >35% reduction of spleen volume from baseline to Week 24 as measured by MRI • Duration of maintenance of a >35% reduction from baseline in spleen volume . • Change in bone marrow histomorphology