Stimulation of oxidative phosphorylation by electrophoretic K+ entry associated to electroneutral K+/H+ exchange in yeast mitochondria

AbstractThe effect of the addition of KCl, at constant osmolarity, was investigated on oxidative phosphorylation in isolated yeast mitochondria. KCl stimulated both respiration and ATP synthesis rates without changing the ATP/O ratio. KCl did not change the relationships between respiration rates and the protonmotive force. Since the K+/H+ exchange activity was active under these conditions, the stimulatory effect of respiration could be explained by the net proton entry caused by the electrophoretic K+ entry/electroneutral K+/H+ exchange cycle. On the other hand, K+ entry stimulated phosphate accumulation and transport under non-phosphorylating conditions and decreased the kinetic control by phosphate transport under phosphorylating conditions. Additionally, the stimulation of ATP synthesis strongly depended on the activity of phosphate transport. Taken together, these data showed that electrophoretic K+-entry and electroneutral K+/H+ exchange occurred in phosphorylating yeast mitochondria but did not promote any uncoupling between respiration and ATP synthesis

Role of the C-terminal domain of Bax and Bcl-xL in their localization and function in yeast cells

AbstractIt has been suggested that the C-terminal domain of Bcl-2 family members may contain a signal anchor sequence that targets these proteins to the mitochondrial outer membrane. We have investigated the consequence of deleting this domain upon cytochrome c release in yeast strains that coexpress truncated forms of Bax (i.e. BaxΔ) and Bcl-xL (i.e. Bcl-xLΔ). We find that (i) BaxΔ is as efficient as full-length Bax in promoting cytochrome c release, but Bcl-xLΔ has remarkably reduced rescuing ability compared to full-length Bcl-xL; (ii) full-length Bcl-xL protein acts by relocalizing Bax from the mitochondrial fraction to the soluble cytosolic fraction; (iii) Bax undergoes N-terminal cleavage when expressed in yeast, which is prevented by coexpression of Bcl-xL, suggesting that Bcl-xL may mask the cleavage site of Bax through a direct physical interaction of the two proteins

Modulation of bax mitochondrial insertion and induced cell death in yeast by mammalian protein kinase calpha

Protein kinase Cα (PKCα) is a classical PKC isoform whose involvement in cell death is not completely understood. Bax, a major member of the Bcl-2 family, is required for apoptotic cell death and regulation of Bax translocation and insertion into the outer mitochondrial membrane is crucial for regulation of the apoptotic process. Here we show that PKCα increases the translocation and insertion of Bax c-myc (an active form of Bax) into the outer membrane of yeast mitochondria. This is associated with an increase in cytochrome c (cyt c) release, reactive oxygen species production (ROS), mitochondrial network fragmentation and cell death. This cell death process is regulated, since it correlates with an increase in autophagy but not with plasma membrane permeabilization. The observed increase in Bax c-myc translocation and insertion by PKCα is not due to Bax c-myc phosphorylation, and the higher cell death observed is independent of the PKCα kinase activity. PKCα may therefore have functions other than its kinase activity that aid in Bax c-myc translocation and insertion into mitochondria. Together, these results give a mechanistic insight on apoptosis regulation by PKCα through regulation of Bax insertion into mitochondria.RDS is supported by the FCT grant SFRH/BD/23774/200

The importance of humanized yeast to better understand the role of Bcl-2 family in apoptosis : finding of novel therapeutic opportunities

The Bcl-2 protein family plays a central role in mitochondrial membrane permeabilization. This event and the ensuing release of cytochrome c are decisive in the apoptotic cascade. Therefore, a better knowledge of these processes and their regulation will probably lead to the development of novel therapeutic strategies for treatment of apoptosis-related diseases. However, the mode of action of Bcl-2 protein family and its regulation are not completely understood. Yeast has proved to be a powerful tool to investigate the molecular aspects of several biological processes, including the steps of the apoptotic cascade involving mitochondria. The fact that yeast does not have obvious homologues of the mammalian Bcl-2 family proteins and that these proteins conserve some of their molecular and biochemical functions when expressed in yeast favours the use of this simpler model system to unravel some of the functions of this family. In this review we attempt to encompass the current knowledge regarding Bcl-2 family mode of action and regulation obtained using the yeast model system. Moreover, we discuss how this model system can be used in the future to gain new understanding about the intricate mechanisms of Bcl-2 family protein regulation, and highlight novel therapeutic targets revealed by this system. We believe that the studies here summarized also provide a proof of principle of yeast as an important tool to elucidate some of the complex mechanisms of apoptotic cell death in higher eukaryotes.R. D. Silva (SFRH/BD/23774/2005) have a fellowship from Fundação para a Ciência e Tecnologia, Portugal. This work was supported by a FCT funded project (PTDC/BIA-BCM/ 69448/2006)

Assessment of oxidative modification of the Aac2p carrier and its contribution to a PTP-like function in yeast mitochondria

D.T. is supported by a PhD grant from F.C. Gulbenkian, n.º 104495. This work was financed by FEDER through POFC–COMPETE and national funds from FCT PEst-C/BIA/UI4050/201

Mitochondria-Associated Membranes (MAMs) are involved in Bax mitochondrial localization and cytochrome c release

The distribution of the pro-apoptotic protein Bax in the outer mitochondrial membrane (OMM) is a central point of regulation of apoptosis. It is now widely recognized that parts of the endoplasmic reticulum (ER) are closely associated to the OMM, and are actively involved in different signaling processes. We addressed a possible role of these domains, called Mitochondria-Associated Membranes (MAMs) in Bax localization and function, by expressing the human protein in a yeast mutant deleted of MDM34, a ERMES (ER-Mitochondria Encounter Structure) component. By affecting MAMs stability, the deletion of MDM34 altered Bax mitochondrial localization, and decreased its capacity to release cytochrome c. Furthermore, the deletion of MDM34 decreased the size of an incompletely released, MAMs-associated pool of cytochrome c

Lactoferrin perturbs lipid rafts and requires integrity of Pma1p-lipid rafts association to exert its antifungal activity against Saccharomyces cerevisiae

"Available online 07 January 2021"Lactoferrin (Lf) is a bioactive milk-derived protein with remarkable wide-spectrum antifungal activity. To deepen our understanding of the molecular mechanisms underlying Lf cytotoxicity, the role of plasma membrane ergosterol- and sphingolipid-rich lipid rafts and their association with the proton pump Pma1p was explored. Pma1p was previously identified as a Lf-binding protein. Results showed that bovine Lf (bLf) perturbs sterol-rich lipid rafts organization by inducing intracellular accumulation of ergosterol. Using yeast mutant strains lacking lipid rafts-associated proteins or enzymes involved in the synthesis of ergosterol and sphingolipids, we found that perturbations in the composition of these membrane domains increase resistance to bLf-induced yeast cell death. Also, when Pma1p-lipid rafts association is compromised in the Pma110 mutant and in the absence of the Pma1p-binding protein Ast1p, the bLf killing activity is impaired. Altogether, results showed that the perturbation of lipid rafts and the inhibition of both Pma1p and V-ATPase activities mediate the antifungal activity of bLf. Since it is suggested that the combination of conventional antifungals with lipid rafts-disrupting compounds is a powerful antifungal approach, our data will help to pave the way for the use of bLf alone or in combination for the treatment/eradication of clinically and agronomically relevant yeast pathogens/fungi.This work was supported by national funds through the Portuguese Foundation for Science and Technology (FCT I.P.) under the scope of the strategic funding of “Contrato-Programa” UIDB/04050/2020 and UIDB/ 04469/2020 unit; by the BioTecNorte operation (NORTE-01-0145- FEDER-000004) funded by the European Regional Development Fund under the scope of Norte2020 - Programa Operacional Regional do Norte; and by the Servicio para el Control de la Esterilización, Laboratorio de Microbiología Oral (CN-16-036). Cátia Santos-Pereira acknowledges the PhD fellowship PD/BD/128032/2016 funded by FCT under the scope of the doctoral programme in Applied and Environmental Microbiology (DP_AEM).info:eu-repo/semantics/publishedVersio

Vacuole-mitochondrial crosstalk during apoptosis induced by acetic acid in yeast

This work was supported by the FCT project PTDC/BIA-BCM/69448/200

What yeast can tell us about how cells commit suicide?

Multicellular organisms developed a complex system to balance cell proliferation and cell death in order to guarantee correct embryonic development and tissue homeostasis. Failure of cells to undergo programmed cell death (PCD) can potentially lead to severe diseases, including neural degeneration, autoimmunity and cancer. Identifying the molecules involved in PCD and understanding the regulation of the process are crucial for prevention and management of these diseases. Evidence of the enormous impact of PCD, of which apoptosis is the most frequent morphological phenotype, on human health makes it one of the today’s main research topics. Since PCD was initially considered specific of metazoans, biological models were first restricted to animal cells. Actually, based on the absence of known crucial PCD regulators, as indicated by plain homologies searches, as well as on the difficulty to explain the sense of cell suicide in a unicellular organism, it was not accepted that these organisms could possess a PDC mechanism. However, evidence has been reported in the last decade indicating that the process of self-destruction in different unicellular organisms, namely in yeast, can also take place. In the present communication, I will present the research we have been developing on PCD, based on the exploration/exploitation of yeast as a simple eukaryotic unicellular model system. Particular focus will be given to our more recent studies suggesting a complex regulation and interplay between mitochondria and the vacuole in acetic acid induced PCD. The validation in mammalian cell lines of the hypothesis postulated with the yeast model will be also discussed.Fundação para a Ciência e a Tecnologia (FCT