N-terminal truncation of antiapoptotic MCL1, but not G2/M-induced phosphorylation, is associated with stabilization and abundant expression in tumor cells.

The antiapoptotic BCL2 family member MCL1 is normally up- and down-modulated in response to environmental signals and conditions, but is constitutively expressed in cancer where it promotes cell survival and drug resistance. A post-translational modification identified here, truncation at the N terminus, was found to act along with previously described ERK- and GSK3-induced phosphorylation events to regulate the turnover of the MCL1 protein and thus its availability for antiapoptotic effects. Although both N-terminally truncated and full-length MCL1 contain sequences enriched in proline, glutamic acid, serine, and threonine and were susceptible to proteasomal degradation, the truncated form decayed less rapidly and was maintained for an extended period in the presence of ERK activation. This was associated with extended cell survival because the truncated form of MCL1 (unlike those of BCL2 and BCLX) retained antiapoptotic activity. N-terminal truncation slightly increased the electrophoretic mobility of MCL1 and differed from the phosphorylation/band shift to decreased mobility, which occurs in the G2/M phase and was not found to affect MCL1 turnover. The N-terminally truncated form of MCL1 was expressed to varying extents in normal lymphoid tissues and was the predominant form present in lymphomas from transgenic mice and human tumor lines of B-lymphoid origin. The degradation versus stabilized expression of antiapoptotic MCL1 is thus controlled by N-terminal truncation as well as by ERK- and GSK3 (but not G2/M)-induced phosphorylation. These modifications may contribute to dysregulated MCL1 expression in cancer and represent targets for promoting its degradation to enhance tumor cell death.

An MCL1-overexpressing Burkitt lymphoma subline exhibits enhanced survival on exposure to serum deprivation, topoisomerase inhibitors, or staurosporine but remains sensitive to 1-beta-D-arabinofuranosylcytosine.

Members of the BCL2 gene family influence cell viability and can, therefore, affect the susceptibility of cancer cells to multiple chemotherapeutic agents. Thus, it is a challenge to devise approaches for inducing the death of tumor cells in which the expression of prosurvival family members is elevated or deregulated. BL41-3, a spontaneously derived subline of BL41 Burkitt lymphoma cells, was found to have amplified the prosurvival MCL1 gene (3-fold) and overexpressed the MCL1 protein. The level of MCL1 protein was 5-fold elevated compared with ML-1 cells expressing maximal MCL1 on exposure to phorbol-12-myristate-13- acetate. To assess whether this increase in MCL1 expression was associated with enhanced protection from cell death, cells were exposed to conditions of growth factor deprivation or to various cytotoxic agents. Whereas BL41-3 and BL41 cells exhibited similar growth rates in logarithmic phase, BL41-3 cells remained largely viable on reaching saturation phase in contrast to BL41 cells, which began to die. Similarly, the BL41-3 subline remained viable for an extended period under conditions of reduced serum. BL41-3 cells were also more resistant to the apoptosis-inducing effects of etoposide, camptothecin, and staurosporine (>3-fold more than BL41 cells). Unexpectedly, these cells exhibited enhanced sensitivity to 1-beta-D-arabinofuranosylcytosine, but only on exposure for an extended period (>10-fold more sensitive than BL41 cells with a 24-h but not a 6-h exposure). Thus, whereas cells expressing prosurvival BCL2 family members are frequently resistant to a variety of chemotherapeutic agents, the findings presented here, using a cell line exhibiting amplification and overexpression of MCL1, indicate that such cells may exhibit increased sensitivity to certain chemotherapeutic regimens.