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Tumor (really “GROWTH”) suppressor genes

Tumor (really “GROWTH”) suppressor genes. TGF- β  COLON E- cadherin  STOMACH NF-1,2  NEURAL TUMORS APC/ β - cadherin  GI, MELANOMA SMADs  GI RB  RETINOBLASTOMA P53  EVERYTHING!! WT-1  WILMS TUMOR p16 (INK4a)  GI, BREAST BRCA-1,2  BREAST KLF6  PROSTATE.

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Tumor (really “GROWTH”) suppressor genes

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  1. Tumor (really “GROWTH”) suppressor genes • TGF-β COLON • E-cadherin STOMACH • NF-1,2 NEURAL TUMORS • APC/β-cadherin GI, MELANOMA • SMADs GI • RB RETINOBLASTOMA • P53 EVERYTHING!! • WT-1 WILMS TUMOR • p16 (INK4a)  GI, BREAST • BRCA-1,2  BREAST • KLF6  PROSTATE

  2. TRANSFORMATION & PROGRESSION • Self-sufficiency in growth signals • Insensitivity to growth-inhibiting signals • Evasion of apoptosis • Limitless replicative potential: Telomerase • Angiogenesis • Invasive ability • Metastatic ability • Defects in DNA repair: “Spell checker”

  3. Evasion of APOPTOSIS • BCL-2 Overexpression • Seen in B-cell lymphomas of follicular type t(14;18)(q32;q21),dominant with IgH genes and overexpression of BCL-2 protein • P53 (Pro-apoptic gene) - Directly activates Bax (Bcl-2 protein) • Reduced levels of CD95/Fas • FLIP protein – Inhibits Caspase 8 • Loss of APAF1(Apoptosis activating factor-1) • Increased IAP (inhibitors of apoptosis)

  4. LIMITLESS REPLICATIVE POTENTIAL • TELOMERES determine the limited number of duplications a cell will have! • TELOMERASE, present in >90% of human cancers, changes telomeres so they will have UNLIMITED replicative potential

  5. TUMOR ANGIOGENESIS • Q: How close to a blood vessel must a cell be? • A: 1-2 mm • Activation of VEGF and FGF-b • Tumor size is regulated (allowed) by angiogenesis/anti-angiogenesis balance

  6. Proteases of tumors can induce production of angiogenic factors and inhibitors • Proteases act on ECM components (E.g. Collagen) releasing bFGF and VEGF • VEGF triggers the NOTCH Pathway

  7. INVADE & METASTASIS • 1. Invasion of Extracellular Matrix • 2. Vascular Dissemination • Invading the Extracellular matrix requires breaching the basement membrane  Intersitial Connective Tissue  Vascular Basement Membrane 

  8. Invasion of ECM • 1. Detachment ("loosening up") of the tumor cells from each other • Down-regulation of E-cadherin and Beta-catenin reducing cell’s adherance to each other

  9. Invasion of ECM • 2. Degradation of ECM, e.g., collagenase, etc. • Break down the basement membrane • Proteases – MMP (matrix metalloproteinases) • Releasing growth factors (e.g. VEGF) and angiogenic, growth promoting effects with cleavage of Type IV collagen for example • 3. Attachment to matrix components • Breakdown by MMP allows tumor cell receptors to bind ECM proteins and stimulate migration • E.g. MMP2 cleaves laminin and MMP9 cleaves collagen IV  Change in tumor cell receptor attachment to ECM proteins  Stimulates Migration

  10. Invasion of ECM • Migration of tumor cells • Cytokines ( autocrine factors) • Cleavage of the ECM components (Laminin, collagen) and growth factors (IGF I, II) that have chemotactic activity • Stromal cells around tumor also producehepatocyte growth factor-scatter factor promoting motility

  11. TRANSFORMATIONGROWTHBM INVASIONANGIOGENESISINTRAVASATIONEMBOLIZATIONADHESIONEXTRAVASATIONMETASTATIC GROWTHetc.

  12. Vascular Dissemination • Following intravasation, clumps of platelet-tumor aggregates are formed • Extravastion of this tumor emboli at distant sites  Attachment to the endothelium  Exits through the basement membrane • Followed by migration to lymphoid tissue using the CD44 adhesion molecule (expressed on T cells) • CD44 binds to hyaluronate allowing migration and towards metastic spread • *Most metastases occur in the first capillary bed available to tumor

  13. Other possible mechanisms explaining metastasis: • 1. Tumor cell adhesion molecule ligandsare expressed on the endothelial cell of target tissue • Target organ variation in endothelial cell expression of adhesion molecule ligands • 2. Chemokinereceptors are expressed in cancer cells that allowing binding of chemokines expressed at specific tissues • E.g. CXCR4 and CCR7 receptors expressed in breast cancer cells • 3. Chemoattractants – E.g. IGF 1, II, can be expressed at target tissues

  14. Breast cancer cells, how do they adapt and make their environment habitable? • - Osteolytic behavior in bone by osteoclasts • Tumor cells  PTHRP (parathyroid hormone-related protein)  Osteoblasts  RANK ligand  Osteoclasts • Osteoclasts break down the matrix releasing growth factors

  15. Development of Metastasis • One hypothesis suggest why only some tumors metastasize? • “Metastasis Signature”  Multiple abnormalities taking place in the early stage of development • Intrinsic properties, microenvironment (stroma), angiogenesis, resistance to immune defenders, and local invasiveness • Other hypothesis  Rare clonal variation that develop metastasis

  16. DEFECTS IN DNA REPAIR • 1. Mismatch Repair • 2. Nucleotide Excision Repair • 3. Recombination Repair

  17. DNA REPAIR GENE DEFECTS • DNA repair is like a spell checker • HNPCC (Hereditary Non-Polyposis Colon Cancer [Lynch]): TGF-β, β-catenin, BAX • XerodermaPigmentosum: UV fixing gene • Ataxia Telangiectasia: ATM gene • Bloom Syndrome: defective helicase • Fanconi anemia

  18. Hereditary Non-PolyposisColon Cancer • Mismatch Repair • Proofreaders disabled • Microsatellite fragments  1 to 6 nucleotide repeats • Creates instability • Dna mismatch repair gene affect cell growth indirectly, through mutations in other genes  TGF-beta, beta-catenin, Bax

  19. XerodermaPigmentosum • UV radiation exposure • Pyrimidinedimers • DNA damage with defect in nucleotide excision repair

  20. Autosomal Recessive Disorders • Defect in DNA repair by Homologous Recombination • Ataxia – Telangiactasia– neurological degenerative disorder, exposure to Ionizing radiation • Defective ATM gene • Bloom Syndrome - Ionizing radiation resulting in developmental defects • Defect in gene of chromosme 15  encodes helicase  dna repair through homologus recombination • Fanconi anemia – Chemotherapeutic agents causing damage • Bone-marrow aplasia BRCA1 and BRCA 2  Proteins take part in homologous recombination repair pathway • Mutation of BRCA2 gene  chromosomal breaks & aneuploidy

  21. STROMAL MICROENVIRONMENT • “Cross-Talk” between the tumor cells and ECM • E.g. Laminin degradation by MMP2  Stimulates tumor cell motility • E.g. Type IV collagen degradation by MMP9  Release of VEGF • Storage of inactive growth factors in ECM, proteases release the active form (E.g. PDGF, TGF-beta, bFGF)

  22. STROMAL MICROENVIRONMENT • Inflammatory Cells and fibroblasts • Cytokines released during inflammation  Induce survival and progression of tumor cells • Chemokines Chemotactic properties • Fibroblasts  Important role in tumor cells • Desmoplastic response, highly fibrotic , promoting growth

  23. Metabolism of Tumors

  24. WARBURG EFFECT • Otto Warburg, Nobel Prize discovery on the metabolism of turmors • Cancer cells rely on Aerobic Glycolysis, Warburg Effect, instead of the mitochondrial oxidative phosphorylation • Several Hypothesis – • 1. During angiogenesis, vessels are poorly formed, activation of H1F1alpha due to hypoxia  increases expression of enzymes of glycolysis, and vasculature • 2. Exposure to state of continous hypoxia and normoxia • 3. Mutations in oncogene and tumor supressors (p53, RAS, PTEN) stimulate metabolic changes

  25. Metabolic Alterations • In addition, tumor cells need to build and maintain its membrane, proteins, and organelles --- Anabolic Pathway • Lipid, nucleotide, proteins (amino acids), glucose (carbon) • Glutamine  Both glycolytic and anabolic pathway

  26. PI3K/AKT/Mtor pathway • Important in regulating normal cell functions including amino acid, glucose uptake • In tumors, mutation of tumor supressors and oncogenes --- Abnormality in pathway can occur favoring survival and proliferation of tumor cells • E.g. PTEN has a negative regulation of this pathway,

  27. Other tumor supressors that supress this pathway:- • Peutz-Jegher syndrome mutated gene LKB1 ( Liver kinase B1) • – Limits or regulates cell growth by AMP-dependent protein kinasemechanism – Negative regulator of mTOR pathway • Supression of LKBI (also called STK11)  Increase in anabolic metabolism of cancer cells • TuberousSclerosis mutated genes (TSC1 and TSC2) ----- Negative regulation of mTOR

  28. CHROMOSOME CHANGES in CANCER • TRANSLOCATIONS and INVERSIONS • Occur in MOST Lymphomas/Leukemias • Occur in MANY (and growing numbers) of NON-hematologic malignancies also

  29. Translocations ------------- Activate Proto-Oncogenes • 2 common mechanism of translocation: • A) Lymphoid Tumors --- Swapping or movement of segment of chromosome to another chromosome • B) Hematopoietic tumors --- Two chromosomes recombine to form hybrid fusion genes for production of chimeric proteins

  30. Burkitt Lymphoma:- t(8:14) (q24;q32) • Translocation at chromosome 8 (c-MYC) and 14 ( IGH gene) • MYC containing segment of chromosome 8 movement to to chromosome 14q32 at IGH gene • Overexpression of MYC

  31. Follicular Lymphomas:- t(14:18) (q32:q21) • Translocation at chromosome 14 (IGH gene) and 18 (BCL2) • Activation of BCL2

  32. Chronic Myeloid Leukemia (CML):- t(9;22) (q34;q11) • Translocation at chromosome 9 (ABL gene) and 22 (BCR gene)

  33. What is the Philadelphia chromosome? • Chromosome 22 that exchanges portion (reciprocal translocation) of the chromosome with Chromosome 9 • Fusion of two genesBCR-ABL producing protein with tyrosine kinase activity • Found in both CML & ALL (Acute Lymphoblastic Leukemia)

  34. Ewing Sarcoma • Also known as PNET (Primitive neuroectodermal tumor) • T(11:22) (q24;q12) FLI 1 gene and EWSR1 gene • Chimeric protein EWS-FLI 1 • Fusion of most genes encode for transcription factors

  35. GENE AMPLIFICATION • Amplification of particular chromosomal regions that contain the oncogenic sequence • Hallmark Features:- • Double minutes ---- Small, centric structures or chromatin bodies of extrachromosomaldna • Homogenous staining regions • Once a gene is amplified, these amplified regions can be inserted into new choromsome • Lack a normal banding pattern and appear homogenous (G-banded karyotype)

  36. Gene Amplification • N-MYC ---- Neuroblastoma • ERBB2 --- Breast Cancers • C-myc, L-myc, N-myc --- Small cell lung cancer • **Greater the amplification, poorer the prognosis

  37. Epigenetic Changes • Heritable changes in gene expression without changing the DNA sequences • Post-translational modfications of histones+ DNA methylation ===== Gene Expression • Cancer cells --- Hypermethylation within promoter regions and global DNA Hypomethylation • Tumor supressor genes --- hypermethlation --- Silenced • E.g. BRCA1, VHL, MLH1

  38. Epigenetic Changes • Genomic Imprinting: • Maternal or paternal allele of a gene or chromosome is modified by methylation and inactivated

  39. miRNAs • Non-coding, single stranded RNA • RNA-induced silencing complex • Post-transcriptional gene silencing • Downregulate gene expression by translational repression, and deadnylation • In cancer cells, increase oncogene expression or reduce tumor supression gene expression

  40. miRNAs • 1. Reduced miRNA (Inhibitor of oncogene translation) --------------- Overproductin of oncogene • 2. miRNA reduces tumor supressor gene

  41. Molecular Basis of Carcinogenesis

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