The
HER2 gene (also known as
HER2/neu and
ErbB2 gene) is amplified in 20–30% of early-stage
breast cancers. The HER2 pathway promotes cell growth and division when it is functioning normally; however, when it is overexpressed, cell growth accelerates beyond its normal limits. In some types of cancer, the pathway is exploited to promote rapid cell growth and proliferation and hence tumor formation. The EGF pathway includes the receptors
HER1 (EGFR), HER2,
HER3, and
HER4; the binding of ligands (e.g. EGF etc.) to HER receptors is required to activate the pathway. In cancer cells the HER2 protein can be expressed up to 100 times more than in normal cells (2 million versus 20,000 per cell). The HER receptors are proteins that are embedded in the cell membrane and communicate molecular signals from outside the cell (molecules called
EGFs) to inside the cell, and turn genes on and off. The
HER (human epidermal growth factor receptor) protein, binds to human epidermal growth factor, and stimulates cell proliferation. In some cancers, notably certain types of breast cancer, HER2 is over-expressed and causes cancer cells to reproduce uncontrollably. HER2 is localized at the cell surface, and carries signals from outside the cell to the inside. Signaling compounds called
mitogens (specifically EGF in this case) arrive at the cell membrane, and bind to the extracellular domain of the HER family of receptors. Those bound proteins then link (
dimerize), activating the receptor. HER2 sends a signal from its intracellular domain, activating several different biochemical pathways. These include the
PI3K/
Akt pathway and the
MAPK pathway. Signals on these pathways promote cell proliferation and the growth of blood vessels to nourish the tumor (
angiogenesis). ERBB2 is the preferred dimerization partner for the other family members and ERBB2 heterodimers signaling is stronger and longer acting compared to heterodimers between other ERBB members. It has been reported that Trastuzumab induces the formation of
complementarity-determining regions (CDRs) leading to surface redistribution of ERBB2 and
EGFR in CDRs and that the ERBB2-dependent
MAPK phosphorylation and EGFR/ERBB1 expression are both required for CDR formation. CDR formation requires activation of both the protein regulator of actin polymerization
N-WASP, mediated by ERK1/2, and of the actin-depolymerizing protein
cofilin, mediated by EGFR/ERBB1. Furthermore, this latter event may be inhibited by the negative
cell motility regulator p140Cap, as we found that p140Cap overexpression led to cofilin deactivation and inhibition of CDR formation. Normal cell division—
mitosis—has checkpoints that keep cell division under control. Some of the proteins that control this cycle are called
cdk2 (CDKs). Overexpression of HER2 sidesteps these checkpoints, causing cells to proliferate in an uncontrolled fashion. Trastuzumab binds to domain IV of the extracellular segment of the HER2/neu receptor. Monoclonal antibodies that bind to this region have been shown to reverse the phenotype of HER2/neu expressing tumor cells. Cells treated with trastuzumab undergo arrest during the G1 phase of the
cell cycle so there is reduced proliferation. It has been suggested that trastuzumab does not alter HER-2 expression, but downregulates activation of AKT. Experiments in laboratory animals indicate that antibodies, including trastuzumab, when bound to a cell, induce immune cells to kill that cell, and that such
antibody-dependent cell-mediated cytotoxicity is another important mechanism of action. ==Predicting response==