The clinical efficacy of MET tyrosine kinase inhibitors (MET-TKIs) is hindered by the emergence of acquired resistance, presenting an obstacle to drug discovery. To clarify the mechanisms underlying acquired resistance to MET-TKIs, we established resistance models by continuous exposure of the MET-amplified gastric cancer cell line MKN45 to MET-TKIs, PHA665752 (MKN45-PR) and GSK1363089 (MKN45-GR). Baseline expression and phosphorylation of MET were elevated in MKN45-PR and MKN45-GR compared to MKN45 cells, and higher concentrations of MET-TKIs were required to inhibit MET phosphorylation compared to parental cells. Alterations in MET previously associated with resistance to MET-TKIs were observed in resistant cells, including elevated MET copy number, observed in both resistant lines compared to MKN45 cells, and the Y1230H mutation, detected in MKN45-PR cells. Notably, the growth of resistant lines was lower in the absence of MET-TKIs, suggesting "addiction" to inhibitors. While MKN45-PR cells exhibited a higher S-phase fraction in the absence of PHA665752, bromodeoxyuridine (BrdU) uptake was identical. Baseline phosphorylation of ATR, Chk1 and p53 and p21(waf1/Cip1) expression was higher in MKN45-PR compared to MKN45 cells, and levels were reduced to those observed in untreated MKN45 cells following PHA665752 treatment. Furthermore, targeted knockdown of MET enhanced the growth of MKN45-PR cells. These findings suggest that alterations in MET leading to acquired MET-TKI resistance, may cause excessive MET signaling, subsequent replication stress and DNA damage response, and intra-S-phase arrest in the absence of MET-TKIs. Thus, partial MET inhibition is necessary for resistant cells to proliferate, a phenomenon we refer to as MET-TKI "addiction".