Pathology
Cards (55)
- CancerA collection of diseases with the common feature of an uncontrolled increase in cell number leading to invasion of the surrounding tissues and spread to other parts of the body (metastasis)
- Cancer is a disease where we lose control over our own cells
- Hallmarks of cancer
- Self-sufficiency in growth signals
- Limitless replicative potential
- Insensitivity to antigrowth signals
- Resistance to apoptosis
- Angiogenesis
- Invasion and metastasis
- Immune avoidance
- Hallmark 1: Self-sufficiency in growth signals
- Cells receive signals to proliferate
- In the absence of these signals cells are not able to proliferate
- These signals are commonly called growth factors
- Hallmark 1: Self-sufficiency in growth signals1. In the presence of growth signals, proteins are switched on and become active, starting with the receptor for the growth factor2. A sequence of these switches ultimately leads to changes in gene expression leading to cell proliferation3. Cell division
- Removing the growth factor signalLeads to all the proteins being switched off and cell proliferation stops
- OncogeneGenes which, when mutated or overexpressed, can cause cancer
- Mutations in proto-oncogenes lead to a gain of function
- Examples of oncogenes
- Ras
- Bcr-Abl
- myc
- Src
- PI3 kinase
- Oncogenes
- Have increased activity and lead to increased cell proliferation in the absence of specific growth signals (i.e. Self-sufficiency)
- Oncogenes represent an important drug target for future cancer therapies and blocking their function should stop the proliferation of cancer cells
- Hallmark 2: Limitless replicative potential
- With telomerase (stem cells & cancer)
- Without telomerase (normal)
- Telomere shortening following cell division limits the number of times a cell divides (40-60 cell divisions)
- Tumour cells are effectively immortal and can rebuild their telomeres using the enzyme telomerase
- Tumour suppressor genesPerform the opposite function to oncogenes in that they stop tumours from forming
- In many cases two-hits are required to inactivate a tumour suppressor gene
- Examples of tumour suppressor genes
- p53
- BRCA
- Mutations in tumour suppressor genesLead to loss of function
- p53 is the most common mutated gene in cancer - found in 50% of all human cancers
- Hallmark 4: Resistance to apoptosisApoptosis can be triggered in cells by DNA damage and viral infection, two things which can lead to the development of cancer
- Bcl-2 family of proteinsControls the sensitivity of the cell to apoptosis
- Pro-survival members of the Bcl-2 familyAre commonly over-expressed in cancer (gain of function)
- Pro-apoptotic members of the Bcl-2 familyAre commonly mutated and non-functional in cancer (loss of function)
- With no blood supply, tumour mass is restricted to ~10^6 cells (2 mm diameter)
- 90% of cancer deaths are due to the spread of cancer to distant sites – a process called metastasis
- Malignant cancer cellsAcquire the ability to move and start to break away from the main tumour
- The most common sites of metastasis are the lung, liver, brain and bone
- New hallmark: Immune avoidance
- Acquiring the hallmarks of cancer requires lots of mutations
- Some of these mutations change the structure of the protein to make it look non-self
- These mutated proteins provoke an immune response leading to destruction of the mutated cancer cells
- Tumours therefore need to learn how to avoid or inactivate the immune response
- DNA in a typical cell is damaged around 10,000 times per day
- Most of this DNA damage is repaired, but the DNA repair mechanisms are not perfect and some damage is occasionally missed leading to a mutation
- Mutations occur randomly throughout the genome
- Where these mutations occur in key genes such as proto-oncogenes or tumour suppressor genes, they can lead to cancer
- Types of DNA mutation
- Point mutations
- Small insertions/deletions
- Alterations in transcription/splicing
- Amplifications/deletions of chromosomal regions
- Chromosomal translocations
- Gains and losses of whole chromosomes
- Changes in DNA modification, e.g., DNA methylation
- What causes DNA mutations?
- UV and other types of radiation
- Viruses
- Chemicals (smoking, asbestos, food etc)
- Free radicals produced during metabolic processes
- Copying / repair errors (sometimes inherited)
- In cancer accumulated mutations can lead to genome instability and an increased likelihood of further mutations
- A single mutation leading to a single acquired property such as increased proliferation is not enough to lead to cancer
- A single cell has to be able to acquire (usually after multiple mutations) most or all of the hallmarks in order to progress to cancer
- This takes time!
- This study sequenced the genome of lung cancer and compared it with a normal genome to look for mutations and their causes
- Found 23,000 mutations in the lung cancer genome