Carcinogenesis is a multistep process, and the development of all human cancers appears to require the accumulation of multiple genetic changes.
Carcinogenesis is a multistep process, and development of all human cancersappears to require the accumulation of multiple genetic changes. These changes can involve either inherited germline mutations or acquired mutations. Once a single severely mutated cell forms, monoclonal expansion of the cell’s line can cause a tumor. Most important mutations in tumorogenesis involve growth promoting genes (protooncogenes), growth inhibiting tumor suppressor genes, or the genes regulating apoptosis and senescence.
Activation of growth promoting oncogenes. Protooncogenes are normal cellulargenes involved with growth and cellular differentiation. Oncogenes are derived from protooncogenes by either a change in the gene sequence, resulting in a new gene product (oncoprotein), or a loss of gene regulation resulting in overexpression of the normal gene product. Mechanisms of oncogene activation include point mutations, chromosomal translocations, gene amplification, and insertional mutagenesis. Activated oncogenes lack regulatory control and are overexpressed, resulting in unregulated cellular proliferation.
Inactivation of tumor suppressor genes. Tumour suppressor genes encode proteins thatregulate and suppress cell proliferation by inhibiting progression of the cell through the cell cycle. The mechanism of action of tumor suppressor genes may vary. As exam-ples, p53 prevents a cell with damaged DNA from entering S-phase, while Rb prevents the cell from entering S-phase until the appropriate growth signals are present.
Knudson’s “two hit hypothesis” states that at least 2 tumor suppressor genesmust be inactivated for oncogenesis. In cancers arising in individuals with inherited germline mutations, the “first hit” is the inherited germline mutation and the “second hit” is an acquired somatic mutation. Examples of inherited germline mutations include familial retinoblastoma (in which germline muta-tion of RB1 on chromosome 13 is associated with a high rate of retinoblastoma and osteosarcoma) and Li-Fraumini syndrome (in which germline mutation of TP53 on chromosome 17 is associated with a high rate of many types of tumors).
Regulation of apoptosis.Tumour genesis related to changes in the regulation of apoptosis occurs in the follicular lymphomas that have the translocation t(14;18). Normally, Bcl-2 prevents apoptosis (programmed cell death). In the follicular lymphomas with this translocation, the Bcl-2 regulator of apoptosis is overexpressed, because the translocation connects the immunoglobulin heavy chain gene on chromosome 14 (which turns on easily in B lymphocytes) to the BCL2 gene on chromosome 18, thereby leading to a situation in which lymphocytes fail to die as expected and instead produce a tumour.
Other examples of apoptosis regulators include Bax, Bad, bcl-xS, and Bid; p53 pro-motes apoptosis in mutated cells by stimulating bax synthesis. The protein c-myc promotes cellular proliferation and when associated with p53 leads to apoptosis and when associated with Bcl-2 inhibits apoptosis.
Limitless replication is possible due in part to the upregulation of telomerase.
Sustained angiogenesis is possible due in part to the activation of the Notch signalling pathway.
Invasiveness/metastasis. Malignant cells must dissociate from tumours (loss of E-cadherin function) and degrade the extracellular matrix before spreading to distant sites. Cancer-associated glycans are being investigated for their role in cancer spread and as targets for therapy.