Genetics of Cancer Cancer  Cancer is not a single disease - great variety of malignant tumors that are formed by the same basic process of uncontrolled growth.  Many aspects of cell function are controlled by a balance of positive and negative signals received from inside and outside the cell. In tumor, the balance between cell proliferation and cell death is lost.  Cancer has both genetic and environmental causes.  Nearly all cancers are caused by abnormalities in the genetic material of the transformed cell.  In order for a normal cell to transform into a cancer cell , genes which regulate cell growth and differentiation must be altered. When normal regulation is altered, uncontrolled growth is initiated and a malignant tumor develop. The Genetic Nature of Cancer Causes of cancer  Carcinogens, such as tobacco smoke, radiation, chemicals, or infectious agents (Viruses are involved in cancers) .  Randomly acquired through errors in DNA replication or  Inherited and thus present in all cells from birth. There are two basic kinds of genetic mutations  Germline mutations are mutations that are inherited (usually require second somatic mutation), also called familial (occurring in families) cancer.  Sporadic cancer or somatic mutation. Most cancers are caused by a series of mutations that develop during a person's lifetime called acquired mutations. These mutations are not in every cell of the body and are not passed from parent to child. Microscopic Appearance of Cancer Cells Genes That play a Role in Cancer  Oncogenes  Tumor suppressor genes  DNA repair genes. These are genes that fix any mistakes made when DNA is replicated (copied). Mistakes that aren't fixed become mutations, which may eventually lead to cancer. The two types have opposite effects in carcinogenesis. tumorfacilitate malignant transformation, whereasOncogenes , block tumor development by regulating genessuppressor genes involved in cell growth. Proto-oncogene  proto-oncogene is a normal gene that can become an oncogene due to mutations or increased expression  Proto-oncogenes code for proteins that help to regulate cell growth and differentiation  often involved in signal transduction and execution of mitogenic signals e.g. myc ,abl, ras Activation of Proto-oncogene Tumor Suppressor Genes Tumor suppressor gene or anti oncogene: In contrast to oncogene, tumor suppressor genes are normal genes implicated in the control of cell cycle, repair DNA mistakes, and tell cells when to die (apoptosis or programmed cell death). When tumor suppressor genes don’t work properly, cells can grow out of control, which can lead to cancer. Types of Tumor Suppressor Genes  Genes that control cell division : Some tumor suppressor genes help control cell growth and reproduction, e.g. retinoblastoma (Rb1)  Genes that repair DNA:The genes responsible for HNPCC (hereditary nonpolyposis colon cancer) are examples of DNA repair gene defects. When these genes do not repair the errors in DNA, HNPCC can result.  Cell "suicide" genes : If there is too much damage to a cell’s DNA to be fixed by the DNA repair genes, the p53 tumor suppressor gene is responsible for destroying the cell by a process sometimes described as "cell suicide." Knudsen’s “two hit” hypothesis  Two mutations are required • One in each copy of the RB gene  For sporadic cases • Retinoblastoma is a result of two somatic mutations – unilateral form • 60% pacients, later manifestation (24 months)  For familial cases • Retinoblastoma is inherited as an autosomal recessive mutation • bilateral/multifocal form • 40% pacients, earlier development (8 months) • Followed by a somatic mutation in the normal allele. • The chance of a second somatic mutation is high • Creates a dominant “susceptibility” to cancer in the family retinoblastoma  Retinoblastoma (RB) is a malignant tumor of the developing retina of children, usually before the age of five years.  mutation in the gene RB1 located on chromosome 13  The gene is about 180 kb in length with 27 exons that code for a transcript of only 4.7 kb.  individual mutations are heterogeneous: 20% are deletions larger than 1kb; 30% are small deletions or insertions; 45% are point mutations.  localisation - 13q14.1-14.2  27 exons, >180kb genomic DNA  tumor-supressor activity Gene RB1 inactivation loss mutation RB1 gene retinoblastoma Deregulation of cell cycle Retinoblastoma protein (pRb) - function •Cell cycle „brake“ – control point for transition from G1 to S phase: - pRb in active form binds transcription factor E2F - CyklinD- and CyklinE-dependent kinases phosphorylate and inactivate pRb - inactive pRb releases E2F transcription factors,which stimulate expression of cyclins and other genes needed for DNA synthesis and transition to S phase - Described more than 500 mutations - Spread over whole coding region - Different forms of Rb1 inactivation lead to different penetration and expressivity and thus to various clinical manifestations of disease - Hereditary vs sporadic form Molecular genetic analysis of Rb1 gene Strategy of molecular analysis of RB1 gene cDNA sequencing DNA sequencing MLPA methylation analysis of promotor region Finding of sequence alteration (substitution, deletion, insertion) Wide deletion finding MLPA negative findings Tumour sample / peripheral blood RNA isolation DNA isolation RT-PCR Metylation analysis of promotor  Hypermetylation of CpG islands in promotor region lead to repression of transcription – gene silencing  In tumour supresor genes (RB1, BRCA1, p15, p16..) hypermetylation of promotors is one of mechanisms of oncogenesis p53  suppresses progression through the cell cycle in response to DNA damage  initiates apoptosis if the damage to the cell is severe  acts as a tumour suppressor  is a transcription factor, represses transcription of one set of genes (several of which are involved in stimulating cell growth) while stimulating expression of other genes involved in cell cycle control  Determines if a cell has repaired DNA damage  If damage cannot be repaired, p53 can induce apoptosis  More that 50% of human cancers involve an abnormal p53 gene Inherited Abnormalities of Tumor Suppressor Genes - in several cancers that tend to run in families.  p53, RB1, genes involved in HNPCC  APC gene causes familial polyposis – colon polyps  BRCA - breast cancers. Non-inherited mutations of tumor suppressor genes : Acquired mutations (those which happen during a person’s life). The p53 gene is believed to be among the most frequently mutated genes in human cancer.