Often, the multiple genetic changes which result in cancer may take many years to accumulate. During this time, the biological behavior of the pre-malignant cells slowly change from the properties of normal cells to cancer-like properties. Pre-malignant tissue can have a distinctive appearance under the microscope. Among the distinguishing traits are an increased number of dividing cells, variation in nuclear size and shape, variation in cell size and shape, loss of specialized cell features, and loss of normal tissue organization. Dysplasia is an abnormal type of excessive cell proliferation characterized by loss of normal tissue arrangement and cell structure in pre-malignant cells. These early neoplastic changes must be distinguished from hyperplasia, a reversible increase in cell division caused by an external stimulus, such as a hormonal imbalance or chronic irritation.
The most severe cases of dysplasia are referred to as "carcinoma in situ." In Latin, the term "in situ" means "in place", so carcinoma in situ refers to an uncontrolled growth of cells that remains in the original location and has not shown invasion into other tissues. Nevertheless, carcinoma in situ may develop into an invasive malignancy and is usually removed surgically, if possible.
Clonal evolution
The process of malignancy can be explained from an evolutionary perspective. Millions of years of biological evolution insure that the cellular metabolic changes that enable cancer to grow occur only very rarely. Most changes in cellular metabolism that allow cells to grow in a disorderly fashion lead to cell death. Cancer cells undergo a process analogous to natural selection, in that the few cells with new genetic changes that enhance their survival continue to multiply, and soon come to dominate the growing tumor, as cells with less favorable genetic change are outcompeted. This process is called clonal evolution. Tumors often continue to evolve in response to chemotherapy treatments, and on occasion aberrant cells may acquire resistance to particular anti-cancer pharmaceuticals.
Biological properties of cancer cells
In a 2000 article by Hanahan and Weinberg, the biological properties of malignant tumor cells were summarized as follows:
* Acquisition of self-sufficiency in growth signals, leading to unchecked growth.
* Loss of sensitivity to anti-growth signals, also leading to unchecked growth.
* Loss of capacity for apoptosis, in order to allow growth despite genetic errors and external anti-growth signals.
* Loss of capacity for senescence, leading to limitless replicative potential (immortality)
* Acquisition of sustained angiogenesis, allowing the tumor to grow beyond the limitations of passive nutrient diffusion.
* Acquisition of ability to invade neighbouring tissues, the defining property of invasive carcinoma.
* Acquisition of ability to build metastases at distant sites, the classical property of malignant tumors (carcinomas or others).
The completion of these multiple steps would be a very rare event without :
* Loss of capacity to repair genetic errors, leading to an increased mutation rate (genomic instability), thus accelerating all the other changes.
These biological changes are classical in carcinomas; other malignant tumor may not need all to achieve them all. For example, tissue invasion and displacement to distant sites are normal properties of leukocytes; these steps are not needed in the development of Leukemia. The different steps do not necessarily represent individual mutations. For example, inactivation of a single gene, coding for the P53 protein, will cause genomic instability, evasion of apoptosis and increased angiogenesis.
The most severe cases of dysplasia are referred to as "carcinoma in situ." In Latin, the term "in situ" means "in place", so carcinoma in situ refers to an uncontrolled growth of cells that remains in the original location and has not shown invasion into other tissues. Nevertheless, carcinoma in situ may develop into an invasive malignancy and is usually removed surgically, if possible.
Clonal evolution
The process of malignancy can be explained from an evolutionary perspective. Millions of years of biological evolution insure that the cellular metabolic changes that enable cancer to grow occur only very rarely. Most changes in cellular metabolism that allow cells to grow in a disorderly fashion lead to cell death. Cancer cells undergo a process analogous to natural selection, in that the few cells with new genetic changes that enhance their survival continue to multiply, and soon come to dominate the growing tumor, as cells with less favorable genetic change are outcompeted. This process is called clonal evolution. Tumors often continue to evolve in response to chemotherapy treatments, and on occasion aberrant cells may acquire resistance to particular anti-cancer pharmaceuticals.
Biological properties of cancer cells
In a 2000 article by Hanahan and Weinberg, the biological properties of malignant tumor cells were summarized as follows:
* Acquisition of self-sufficiency in growth signals, leading to unchecked growth.
* Loss of sensitivity to anti-growth signals, also leading to unchecked growth.
* Loss of capacity for apoptosis, in order to allow growth despite genetic errors and external anti-growth signals.
* Loss of capacity for senescence, leading to limitless replicative potential (immortality)
* Acquisition of sustained angiogenesis, allowing the tumor to grow beyond the limitations of passive nutrient diffusion.
* Acquisition of ability to invade neighbouring tissues, the defining property of invasive carcinoma.
* Acquisition of ability to build metastases at distant sites, the classical property of malignant tumors (carcinomas or others).
The completion of these multiple steps would be a very rare event without :
* Loss of capacity to repair genetic errors, leading to an increased mutation rate (genomic instability), thus accelerating all the other changes.
These biological changes are classical in carcinomas; other malignant tumor may not need all to achieve them all. For example, tissue invasion and displacement to distant sites are normal properties of leukocytes; these steps are not needed in the development of Leukemia. The different steps do not necessarily represent individual mutations. For example, inactivation of a single gene, coding for the P53 protein, will cause genomic instability, evasion of apoptosis and increased angiogenesis.