Project description:The transient receptor potential cation channel, subfamily M, member 7 (TRPM7) is a ubiquitously expressed membrane protein consisting of an ion channel domain and an intracellularly located protein kinase domain. TRPM7 plays a fundamental role in the cellular uptake of divalent cations such as Zn2+, Mg2+ and Ca2+, and thus shapes cellular excitability, plasticity and metabolic activity. The molecular appearance and operation of TRPM7 channel complexes in native tissues have remained unresolved. Here, we investigated the subunit composition of endogenous TRPM7 channels in rodent brain by multi-epitope affinity purification and high-resolution quantitative MS analysis. We found that native TRPM7 channels are high molecular-weight multi-protein complexes that contain the putative metal transporter proteins CNNM1-4 and a small G-protein ARL15. Heterologous reconstitution experiments confirmed the formation of TRPM7/CNNM/ARL15 ternary complexes and indicated that ARL15 effectively and specifically impacts TRPM7 channel activity. These results open up new avenues towards a mechanistic understanding of the cellular regulation and function of TRPM7 channels.

Project description:The most severe form of malaria is caused by Plasmodium falciparum. These parasites invade human erythrocytes and an essential step in this process involves the ligand PfRh5, which forms a complex with CyRPA and PfRipr (RCR complex) and binds basigin on the host cell. We identified a heteromeric disulphide-linked complex consisting of PfPTRAMP and PfCSS and have shown it binds RCR to form a pentameric complex PCRCR. Using P. falciparum lines with conditional knockouts and invasion inhibitory nanobodies to both PfPTRAMP and PfCSS we utilised lattice light-sheet microscopy and show they are essential for merozoite invasion. The PCRCR complex functions to anchor the contact between merozoite and erythrocyte membranes brought together by strong parasite deformations. We solved the structure of nanobody/PfCSS complexes to identify an inhibitory epitope. Our results define the function of the PCRCR complex and identify invasion neutralising epitopes providing a roadmap for structure-guided development of these proteins for a blood stage malaria vaccine.

Project description:In the mammalian brain TRPC channels, a family of Ca2+-permeable cation channels, are involved in a variety of processes from neuronal growth and synapse formation to transmitter release, synaptic transmission and plasticity. The molecular appearance and operation of native TRPC channels, however, remained poorly understood. Here we used high-resolution proteomics to show that TRPC channels in the rodent brain are macro-molecular complexes of more than 1 MDa in size that results from co-assembly of the tetrameric channel core with an ensemble of interacting proteins (interactome). The core(s) of TRPC1, 4, 5-containing channels are mostly heteromers with defined stoichiometries for each subtype, while TRPC 3, 6, 7 preferentially form homomers. In addition, TRPC1, 4, 5-channels may co-assemble with the metabotropic glutamate receptor mGluR1 thus guaranteeing both specificity and reliability of channel activation via the phospholipase-Ca2+ pathway. Our results unveil the subunit composition of native TRPC channels and resolve molecular details underlying their activation.

Project description:Oxidative phosphorylation (OXPHOS) is essential for the synthesis of the vast majority of ATP in eukaryotic cells. It is carried out by multi-protein assemblies that form the electron transport chain (ETC), which are coupled to the mitochondrial ATP synthase, which uses the proton gradient generated by the ETC to drive ATP synthesis. The assembly of the OXPHOS protein machinery requires the coordinated integration of proteins encoded in the nuclear and the mitochondrial genomes, imposing an additional layer of complexity. While the biogenesis of the individual OXPHOS complexes is well understood, it remains unknown how the assembly of the ETC and ATP synthase is coordinated to achieve the correct stoichiometry of the OXPHOS machinery. Here, we identify the mitochondrial regulatory hub for respiratory assembly (MiRA), which serves as a platform on which complex IV and complex V biogenesis are synchronised to ensure balanced assembly of the ETC and complex V. At the molecular level, this is achieved by a stop-and-go safeguarding mechanism: The novel mitochondrial protein Mra1 binds to and slows down complex IV assembly. Two Go signals are then required for assembly to proceed: Binding of the complex IV assembly factor Rcf2 and interaction with the mitoribosome, which translates the complex V subunit Atp9. Both Go signals induce the clipping and subsequent degradation of Mra1, relieving the molecular break and allowing parallel maturation of complexes IV and V. The absence of the stop-and-go safety mechanism results in the formation of immature complexes, decreased ATP levels and reduced cell viability. The antagonistic activities at MiRA provide a regulated orchestration of complex IV and V assembly which is essential to avoid the predominance of either complex and an unbalanced ratio of OXPHOS complexes, thus ensuring the correct stoichiometry of protein machineries encoded by two different genomes.

Project description:Plasmodium falciparum causes the most severe form of malaria in humans. The protozoan parasite develops within erythrocytes to mature schizonts, that contain more than 16 merozoites, which egress and invade fresh erythrocytes. The aspartic protease plasmepsin X (PMX), processes proteins and proteases essential for merozoite egress from the schizont and invasion of the host erythrocyte, including the leading vaccine candidate PfRh5. PfRh5 is anchored to the merozoite surface through a 5-membered complex (PCRCR), consisting of Plasmodium thrombospondin-related apical merozoite protein (PTRAMP), cysteine-rich small secreted protein (CSS), Rh5-interacting protein (PfRipr) and cysteine-rich protective antigen (CyRPA). We show that PCRCR is processed by PMX in micronemes to remove the N-terminal prodomain and this activates the function of the complex unmasking a form that can bind basigin on the erythrocyte membrane and mediate merozoite invasion. The ability to activate PCRCR at a specific time in merozoite invasion ensures invasion inhibitory epitopes are exposed to the immune system for a minimal time but also mask potential deleterious effects of its function until they are required. These results provide an important understanding of the essential roles of PMX and the fine regulation of PCRCR function in P. falciparum biology.

Project description:A universal feature of the response to stress and nutrient limitation is transcriptional upregulation of genes encoding proteins important for survival. Interestingly, under many of these conditions overall protein synthesis levels are reduced, thereby dampening the stress response at the level of protein expression. For example, during glucose starvation in yeast, translation is rapidly and reversibly repressed, yet transcription of many stress- and glucose-repressed genes is increased. Using ribosome profiling and microscopy, we found that this transcriptionally upregulated gene set consists of two classes: (1) one producing mRNAs that are preferentially translated during glucose limitation and are diffusely localized in the cytoplasm – this class includes many heat shock protein mRNAs; and (2) another producing mRNAs that are poorly translated during glucose limitation, have high rates of translation initiation, and are concentrated in foci that co-localize with P bodies and stress granules – this class is enriched for glucose metabolism mRNAs. Remarkably, the information specifying differential localization and translation of these two classes of mRNAs is encoded in the promoter sequence – promoter responsiveness to heat shock factor (Hsf1) specifies diffuse cytoplasmic localization and preferential translation upon glucose starvation, whereas different promoter elements upstream of genes encoding poorly translated glucose metabolism mRNAs direct these mRNAs to RNA granules under glucose starvation. Thus, promoter sequences and transcription factor binding can influence not only mRNA levels, but also subcellular localization of mRNAs and the efficiency with which they are translated, enabling cells to tailor protein production to environmental conditions. Examination of mRNA translation in S. cerevisiae upon glucose starvation.

Project description:Inactivating mutations in SMARCA4 and concurrent epigenetic silencing of SMARCA2 characterize subsets of ovarian and lung cancers. Concomitant loss of these key subunits of SWI/SNF chromatin remodeling complexes in both cancers is associated with chemotherapy resistance and poor prognosis. Here, we discover that SMARCA4/2 loss inhibits chemotherapy-induced apoptosis through disrupting intracellular organelle calcium ion (Ca2+) release in these cancers. By restricting chromatin accessibility to ITPR3, encoding Ca2+ channel IP3R3, SMARCA4/2 deficiency causes reduced IP3R3 expression leading to impaired Ca2+ transfer from the endoplasmic reticulum to mitochondria required for apoptosis induction. Reactivation of SMARCA2 by a histone deacetylase inhibitor rescues IP3R3 expression and enhances cisplatin response in SMARCA4/2-deficient cancer cells both in vitro and in vivo. Our findings elucidate the contribution of SMARCA4/2 to Ca2+-dependent apoptosis induction, which may be exploited to enhance chemotherapy response in SMARCA4/2-deficient cancers.

Project description:Plasmodium falciparum malaria is a deadly infectious disease for which we have no licensed vaccine. Antibodies confer protection against malaria and individuals exposed to P. falciparum acquire protective antibodies, but only after years of repeated infections. We recently showed that malaria exposure is associated with a large expansion of a population of atypical memory B cells (MBCs) that phenotypically resemble B cell populations expanded in chronic viral infections, including HIV. At present the relationship of atypical MBCs to classical MBCs and their function are not known. We provide evidence that the expressed VH gene repertoires and somatic hypermutation rates of atypical and classical MBCs are indistinguishable, indicating the two populations are closely related developmentally. Atypical MBCs can be distinguished by their expression of multiple inhibitory receptors, including Fc receptor-like-5. B cell receptor (BCR) signaling is stunted in atypical MBCs, resulting in impaired Ca2+ mobilization, proliferation and cytokine production. Atypical MBCs do not spontaneously secrete antibodies and cannot be stimulated to differentiate into antibody-secreting cells in vitro. These results suggest that in individuals chronically exposed to malaria, atypical MBCs differentiate from classical MBCs and assume a phenotype refractory to BCR-mediated activation, potentially contributing to the inefficient acquisition of immunity to malaria. Comparison of human atypical B cell versus classical B cell versus naïve B cell.

Project description:Ca2+ overload-induced mitochondrial dysfunction is considered as a major contributing factor in the pathogenesis of alcohol-associated liver disease (ALD). However, the initiating factors that drive mitochondrial Ca2+ accumulation in ALD remain elusive. Here, we demonstrate that an aberrant increase in mitochondria-associated ER membranes (MAMs) mediates Ca2+ accumulation-induced mitochondrial dysfunction in ALD via the formation of glucose-regulated protein 75 (GRP75)-mediated MAM Ca2+-channeling (MCC) complex. Unbiased transcriptomic analysis reveals pyruvate dehydrogenase kinase 4 (PDK4) as a prominently inducible MAM kinase in ALD. Additional mass spectrometry analysis unveils the critical role of PDK4 in promoting alcohol-induced MCC complex formation and mitochondrial dysfunction by phosphorylating GRP75. Non-phosphorylatable GRP75 mutation or genetic ablation of PDK4 prevents alcohol-induced mitochondrial Ca2+ accumulation and dysfunction. Conversely, ectopic induction of MAM formation in PDK4-deficient mice abrogate the protective effect in alcohol-induced liver injury. Together, our study defines the mediatory role of PDK4 in promoting mitochondrial dysfunction in ALD.

Project description:Plasmodium falciparum malaria is a deadly infectious disease for which we have no licensed vaccine. Antibodies confer protection against malaria and individuals exposed to P. falciparum acquire protective antibodies, but only after years of repeated infections. We recently showed that malaria exposure is associated with a large expansion of a population of atypical memory B cells (MBCs) that phenotypically resemble B cell populations expanded in chronic viral infections, including HIV. At present the relationship of atypical MBCs to classical MBCs and their function are not known. We provide evidence that the expressed VH gene repertoires and somatic hypermutation rates of atypical and classical MBCs are indistinguishable, indicating the two populations are closely related developmentally. Atypical MBCs can be distinguished by their expression of multiple inhibitory receptors, including Fc receptor-like-5. B cell receptor (BCR) signaling is stunted in atypical MBCs, resulting in impaired Ca2+ mobilization, proliferation and cytokine production. Atypical MBCs do not spontaneously secrete antibodies and cannot be stimulated to differentiate into antibody-secreting cells in vitro. These results suggest that in individuals chronically exposed to malaria, atypical MBCs differentiate from classical MBCs and assume a phenotype refractory to BCR-mediated activation, potentially contributing to the inefficient acquisition of immunity to malaria.