Mechanisms for regulating step length while running towards and over an obstacle.

The ability to run across uneven terrain with continuous stable movement is critical to the safety and efficiency of a runner. Successful step-to-step stabilization while running may be mediated by minor adjustments to a few key parameters (e.g., leg stiffness, step length, foot strike pattern). However, it is not known to what degree runners in relatively natural settings (e.g., trails, paved road, curbs) use the same strategies across multiple steps. This study investigates how three readily measurable running parameters - step length, foot placement, and foot strike pattern - are adjusted in response to encountering a typical urban obstacle - a sidewalk curb. Thirteen subjects were video-recorded as they ran at self-selected slow and fast paces. Runners targeted a specific distance before the curb for foot placement, and lengthened their step over the curb (p<0.0001) regardless of where the step over the curb was initiated. These strategies of adaptive locomotion disrupt step cycles temporarily, and may increase locomotor cost and muscle loading, but in the end assure dynamic stability and minimize the risk of injury over the duration of a run.

Bortezomib blocks the catabolic process of autophagy via a cathepsin-dependent mechanism, affects endoplasmic reticulum stress and induces caspase-dependent cell death in antiestrogen-sensitive and resistant ER+ breast cancer cells.

In recent studies, we and others showed that autophagy is critical to estrogen receptor positive (ER+) breast cancer cell survival and the development of antiestrogen resistance. Consequently, new approaches are warranted for targeting autophagy in breast cancer cells undergoing antiestrogen therapy. Because crosstalk has been demonstrated between the autophagy- and proteasome-mediated pathways of protein degradation, this study investigated how the proteasome inhibitor bortezomib affects autophagy and cell survival in antiestrogen-treated ER+ breast cancer cells. Bortezomib, at clinically achievable doses, induced a robust death response in ER+, antiestrogen-sensitive and antiestrogen-resistant breast cancer cells undergoing hormonal therapy. Cleavage of PARP and lamin A was detectable as a read-out of cell death, following bortezomib-induced mitochondrial dysfunction. Prior to induction of cell death, bortezomib-treated cells showed high levels of light chain 3 (LC3) and p62, two protein markers for autophagy. The accumulation of these proteins was due to bortezomib-mediated blockade of long-lived protein turnover during macroautophagy. This novel action of bortezomib was linked to its blockade of cathepsin-L activity, which is required for autolysosomal-mediated protein turnover in ER+ breast cancer cells. Further, bortezomib-treated breast cancer cells showed induction of the unfolded protein response, with upregulation of CH OP and GRP78. Bortezomib also induced high levels of the pro-apoptotic protein BNIP3. Knockdown of CH OP and/or BNIP3 expression via RNAi targeting significantly attenuated the death-promoting effects of bortezomib. Thus, bortezomib inhibits prosurvival autophagy, in addition to its known function in blocking the proteasome, and is cytotoxic to hormonally treated ER+ breast cancer cells. These findings indicate that combining a proteasome inhibitor like bortezomib with antiestrogen therapy may have therapeutic advantage in the management of early-stage breast cancer.

Autophagy facilitates the progression of ERalpha-positive breast cancer cells to antiestrogen resistance.

A major impediment to the successful treatment of estrogen receptor alpha (ERalpha)-positive breast cancer is the development of antiestrogen resistance. Tamoxifen, the most commonly used antiestrogen, exerts its pharmacological action by binding to ERalpha and blocking the growth-promoting action of estrogen-bound ERalpha in breast cancer cells. Tamoxifen treatment primarily induces cytostasis (growth arrest) and the surviving breast cancer cells commonly acquire tamoxifen resistance. Numerous clinically-relevant mechanisms of acquired antiestrogen resistance have been identified by in vitro studies. Our recent studies (Mol Cancer Ther 2008; 7:2977-87) now demonstrate that autophagy (also referred to as macroautophagy) is critical to the development of antiestrogen resistance. Under conditions of compromised autophagy, including treatments with pharmacological inhibitors and RNAi targeting of the beclin 1 gene, the cytotoxicity (death-inducing effects) of the antiestrogen 4-hydroxytamoxifen (4-OHT) was significantly increased. 4-OHT is an active metabolite of tamoxifen commonly used for in vitro studies. A step-wise drug selection protocol, using 4-OHT as the selecting drug, established antiestrogen-resistant breast cancer cell lines. Analysis of a representative resistant cell line showed an increased ability of the cells to sustain high levels of antiestrogen-induced autophagy without progression to death. Importantly, blockade of autophagosome function in the 4-OHT-treated, antiestrogen-resistant cells induced a robust death response. These data provide strong evidence that autophagy is a key mechanism of cell survival during antiestrogen challenge and progression to antiestrogen resistance. We discuss the potential benefit of blocking autophagosome function to significantly reduce the emergence of antiestrogen-resistant breast cancer cells.