The interactions of Cobalt(II) with mitochondria from rat liver

The interactions of Co2+ with mitochondria have been investigated. The results indicate that Co2+ inhibits ATP synthesis. Further investigations into ATP synthesis mechanisms indicated that inhibition is due to the opening of a transmembrane pore. The opening of this pore causes the collapse of the high-energy intermediate where, under a pH and a potential gradient, the energy is stored and subsequently utilized to form ATP from ADP

Bax Function in the Absence of Mitochondria in the Primitive Protozoan Giardia lamblia

Bax-induced permeabilization of the mitochondrial outer membrane and release of cytochrome c are key events in apoptosis. Although Bax can compromise mitochondria in primitive unicellular organisms that lack a classical apoptotic machinery, it is still unclear if Bax alone is sufficient for this, or whether additional mitochondrial components are required. The protozoan parasite Giardia lamblia is one of the earliest branching eukaryotes and harbors highly degenerated mitochondrial remnant organelles (mitosomes) that lack a genome. Here we tested whether human Bax expressed in Giardia can be used to ablate mitosomes. We demonstrate that these organelles are neither targeted, nor compromised, by Bax. However, specialized compartments of the regulated secretory pathway are completely ablated by Bax. As a consequence, maturing cyst wall proteins that are sorted into these organelles are released into the cytoplasm, causing a developmental arrest and cell death. Interestingly, this ectopic cargo release is dependent on the carboxy-terminal 22 amino acids of Bax, and can be prevented by the Bax-inhibiting peptide Ku70. A C-terminally truncated Bax variant still localizes to secretory organelles, but is unable to permeabilize these membranes, uncoupling membrane targeting and cargo release. Even though mitosomes are too diverged to be recognized by Bax, off-target membrane permeabilization appears to be conserved and leads to cell death completely independently of mitochondria

Apoptosis commitment and activation of mitochondrial Bax during anoikis is regulated by p38MAPK

Most cells undergo apoptosis through the intrinsic pathway. This is dependent on mitochondrial outer membrane permeabilisation (MOMP), which is mediated by the pro-apoptotic Bcl-2 family proteins, Bax and Bak. During apoptosis, Bax translocates from the cytosol to the outer mitochondrial membrane (OMM), wherein it contributes to the formation of pores to release cytochrome-c. However, it remains unclear whether Bax translocation is sufficient to bring about MOMP or whether Bax requires further signals on the OMM to be fully activated. We have previously shown that during mammary epithelial cell anoikis, Bax translocation does not commit cells to MOMP and detached cells are rescued if survival signals from the extracellular matrix (ECM) are restored. These findings implied that a second signal is required for mitochondrial Bax to fully activate and cause MOMP. We now identify p38MAPK (mitogen-activated protein kinase) as this necessary signal to activate Bax after its translocation to mitochondria. The inhibition of p38MAPK did not prevent Bax translocation, but its activity was required for mitochondrial Bax to bring about MOMP. p38MAPK was activated and recruited to a high molecular weight mitochondrial complex after loss of ECM attachment. Artificially targeting p38MAPK to the OMM increased the kinetics of anoikis, supporting a requirement for its mitochondrial localisation to regulate Bax activation and drive commitment to apoptosis

The N-terminal conformation of Bax regulates cell commitment to apoptosis

The Bcl-2 protein Bax normally resides in the cytosol, but during apoptosis it translocates to mitochondria where it is responsible for releasing apoptogenic factors. Using anoikis as a model, we have shown that Bax translocation does not commit cells to apoptosis, and they can be rescued by reattachment to extracellular matrix within a specific time. Bax undergoes an N-terminal conformational change during apoptosis that has been suggested to regulate conversion from its benign, cytosolic form to the active, membrane bound pore. We now show that the Bax N-terminus regulates commitment and mitochondrial permeabilisation, but not the translocation to mitochondria. We identify Proline 13 within the N-terminus of Bax as critical for this regulation. The subcellular distribution of Proline 13 mutant Bax was identical to wild-type Bax in both healthy and apoptotic cells. However, Proline 13 mutant Bax induced rapid progression to commitment, mitochondrial permeabilisation and death. Our data identify changes in Bax controlling commitment to apoptosis that are mechanistically distinct from those controlling its subcellular localisation. Together, they indicate that multiple regulatory steps are required to activate the proapoptotic function of Bax