bims-camemi Biomed News
on Mitochondrial metabolism in cancer
Issue of 2024‒11‒10
29 papers selected by
Christian Frezza, Universität zu Köln
  1. Cellular ATP demand creates metabolically distinct subpopulations of mitochondria.
  2. Cytosolic N6AMT1-dependent translation supports mitochondrial RNA processing.
  3. mTORC1 activity licenses its own release from the lysosomal surface.
  4. Mitochondrial elongation impairs breast cancer metastasis.
  5. Monitoring protein phosphorylation at the mitochondrial protein import machinery by PhosTag electrophoresis.
  6. Cancer Metabolism: Historical Landmarks, New Concepts, and Opportunities.
  7. The multifaceted modulation of mitochondrial metabolism in tumorigenesis.
  8. Approaches for the analysis of redox-dependent protein import into mitochondria of mammalian cells.
  9. Metabolite signatures of chronological age, aging, survival, and longevity.
  10. Origins and impact of extrachromosomal DNA.
  11. Plasma protein-based organ-specific aging and mortality models unveil diseases as accelerated aging of organismal systems.
  12. Exploration of the mutational landscape of cutaneous leiomyoma confirms FH as a driver gene and identifies targeting purine metabolism as a potential therapeutic strategy.
  13. Analysis of mitochondrial protein translocation by disulfide bond formation and cysteine specific crosslinking.
  14. Mitochondrial respiratory complex II is altered in renal carcinoma.
  15. Analysis of mitochondrial biogenesis regulation by oxidative stress.
  16. Division of labour: mitochondria split to meet energy demands.
  17. Does a transmembrane sodium gradient control membrane potential in mammalian mitochondria?
  18. Mitochondrial nucleoids.
  19. All we are is our memories.
  20. Organ-specific electrophile responsivity mapping in live C. elegans.
  21. STED super-resolution microscopy of mitochondrial translocases.
  22. Coordinated inheritance of extrachromosomal DNAs in cancer cells.
  23. Regulation of leukemogenesis via redox metabolism.
  24. A new kind of mitochondrion.
  25. Transfer of mitochondrial DNA into the nuclear genome during induced DNA breaks.
  26. Calcium signals as regulators of ferroptosis in cancer.
  27. Cell-cell fusion: To lose one life and begin another.
  28. Whole-cell metabolic control analysis.
  29. mTORC1 restricts TFE3 activity by auto-regulating its presence on lysosomes.
  1. Nature. 2024 Nov 06.
    Cellular ATP demand creates metabolically distinct subpopulations of mitochondria.
    Keun Woo Ryu, Tak Shun Fung, Daphne C Baker, Michelle Saoi, Jinsung Park, Christopher A Febres-Aldana, Rania G Aly, Ruobing Cui, Anurag Sharma, Yi Fu, Olivia L Jones, Xin Cai, H Amalia Pasolli, Justin R Cross, Charles M Rudin, Craig B Thompson.
      Mitochondria serve a crucial role in cell growth and proliferation by supporting both ATP synthesis and the production of macromolecular precursors. Whereas oxidative phosphorylation (OXPHOS) depends mainly on the oxidation of intermediates from the tricarboxylic acid cycle, the mitochondrial production of proline and ornithine relies on reductive synthesis1. How these competing metabolic pathways take place in the same organelle is not clear. Here we show that when cellular dependence on OXPHOS increases, pyrroline-5-carboxylate synthase (P5CS)-the rate-limiting enzyme in the reductive synthesis of proline and ornithine-becomes sequestered in a subset of mitochondria that lack cristae and ATP synthase. This sequestration is driven by both the intrinsic ability of P5CS to form filaments and the mitochondrial fusion and fission cycle. Disruption of mitochondrial dynamics, by impeding mitofusin-mediated fusion or dynamin-like-protein-1-mediated fission, impairs the separation of P5CS-containing mitochondria from mitochondria that are enriched in cristae and ATP synthase. Failure to segregate these metabolic pathways through mitochondrial fusion and fission results in cells either sacrificing the capacity for OXPHOS while sustaining the reductive synthesis of proline, or foregoing proline synthesis while preserving adaptive OXPHOS. These findings provide evidence of the key role of mitochondrial fission and fusion in maintaining both oxidative and reductive biosyntheses in response to changing nutrient availability and bioenergetic demand.
    DOI:  https://doi.org/10.1038/s41586-024-08146-w
  2. Proc Natl Acad Sci U S A. 2024 Nov 19. 121(47): e2414187121
    Cytosolic N6AMT1-dependent translation supports mitochondrial RNA processing.
    Mads M Foged, Emeline Recazens, Sylvain Chollet, Miriam Lisci, George E Allen, Boris Zinshteyn, Doha Boutguetait, Christian Münch, Vamsi K Mootha, Alexis A Jourdain.
      Mitochondrial biogenesis relies on both the nuclear and mitochondrial genomes, and imbalance in their expression can lead to inborn errors of metabolism, inflammation, and aging. Here, we investigate N6AMT1, a nucleo-cytosolic methyltransferase that exhibits genetic codependency with mitochondria. We determine transcriptional and translational profiles of N6AMT1 and report that it is required for the cytosolic translation of TRMT10C (MRPP1) and PRORP (MRPP3), two subunits of the mitochondrial RNAse P enzyme. In the absence of N6AMT1, or when its catalytic activity is abolished, RNA processing within mitochondria is impaired, leading to the accumulation of unprocessed and double-stranded RNA, thus preventing mitochondrial protein synthesis and oxidative phosphorylation, and leading to an immune response. Our work sheds light on the function of N6AMT1 in protein synthesis and highlights a cytosolic program required for proper mitochondrial biogenesis.
    Keywords:  OXPHOS; RNA processing; mitochondria; mitochondrial RNA granules; translation
    DOI:  https://doi.org/10.1073/pnas.2414187121
  3. Mol Cell. 2024 Oct 25. pii: S1097-2765(24)00831-1. [Epub ahead of print]
    mTORC1 activity licenses its own release from the lysosomal surface.
    Aishwarya Acharya, Constantinos Demetriades.
      Nutrient signaling converges on mTORC1, which, in turn, orchestrates a physiological cellular response. A key determinant of mTORC1 activity is its shuttling between the lysosomal surface and the cytoplasm, with nutrients promoting its recruitment to lysosomes by the Rag GTPases. Active mTORC1 regulates various cellular functions by phosphorylating distinct substrates at different subcellular locations. Importantly, how mTORC1 that is activated on lysosomes is released to meet its non-lysosomal targets and whether mTORC1 activity itself impacts its localization remain unclear. Here, we show that, in human cells, mTORC1 inhibition prevents its release from lysosomes, even under starvation conditions, which is accompanied by elevated and sustained phosphorylation of its lysosomal substrate TFEB. Mechanistically, "inactive" mTORC1 causes persistent Rag activation, underlining its release as another process actively mediated via the Rags. In sum, we describe a mechanism by which mTORC1 controls its own localization, likely to prevent futile cycling on and off lysosomes.
    Keywords:  GATOR1; Rag GTPases; Rheb; TFE3; TFEB; Torin1; lysosomes; mTORC1; rapamycin
    DOI:  https://doi.org/10.1016/j.molcel.2024.10.008
  4. Sci Adv. 2024 Nov 08. 10(45): eadm8212
    Mitochondrial elongation impairs breast cancer metastasis.
    Lucía Minarrieta, Matthew G Annis, Yannick Audet-Delage, Hellen Kuasne, Alain Pacis, Catherine St-Louis, Alexander Nowakowski, Marco Biondini, Mireille Khacho, Morag Park, Peter M Siegel, Julie St-Pierre.
      Mitochondrial dynamics orchestrate many essential cellular functions, including metabolism, which is instrumental in promoting cancer growth and metastatic progression. However, how mitochondrial dynamics influences metastatic progression remains poorly understood. Here, we show that breast cancer cells with low metastatic potential exhibit a more fused mitochondrial network compared to highly metastatic cells. To study the impact of mitochondrial dynamics on metastasis, we promoted mitochondrial elongation in metastatic breast cancer cells by individual genetic deletion of three key regulators of mitochondrial fission (Drp1, Fis1, Mff) or by pharmacological intervention with leflunomide. Omics analyses revealed that mitochondrial elongation causes substantial alterations in metabolic pathways and processes related to cell adhesion. In vivo, enhanced mitochondrial elongation by loss of mitochondrial fission mediators or treatment with leflunomide notably reduced metastasis formation. Furthermore, the transcriptomic signature associated with elongated mitochondria correlated with improved clinical outcome in patients with breast cancer. Overall, our findings highlight mitochondrial dynamics as a potential therapeutic target in breast cancer.
    DOI:  https://doi.org/10.1126/sciadv.adm8212
  5. Methods Enzymol. 2024 ;pii: S0076-6879(24)00408-7. [Epub ahead of print]707 501-517
    Monitoring protein phosphorylation at the mitochondrial protein import machinery by PhosTag electrophoresis.
    Fatimah Lami Imam, Chris Meisinger, Adinarayana Marada.
      The mitochondrial import machinery is regulated by several protein kinases that phosphorylate key components. This allows an adjustment of the protein flux to changing cellular demands and allow a dynamic organellar proteome. PhosTag electrophoresis has been proven as highly valuably tool to study these signalling machanisms at the import machinery.
    Keywords:  TOM complex; assembly; biogenesis; import machinery; precursor protein; protein kinase; reversible phosphorylation; signalling
    DOI:  https://doi.org/10.1016/bs.mie.2024.07.063
  6. Cold Spring Harb Perspect Med. 2024 Nov 05. pii: a041814. [Epub ahead of print]
    Cancer Metabolism: Historical Landmarks, New Concepts, and Opportunities.
    Navdeep S Chandel, Karen H Vousden, Ralph J DeBerardinis.
      Cancer cells undergo changes in metabolism that distinguish them from non-malignant tissue. These may provide a growth advantage by promoting oncogenic signaling and redirecting intermediates to anabolic pathways that provide building blocks for new cellular components. Cancer metabolism is far from uniform, however, and recent work has shed light on its heterogenity within and between tumors. This work is also revealing how cancer metabolism adapts to the tumor microenvironment, as well as ways in which we may capitalize on metabolic changes in cancer cells to create new therapies.
    DOI:  https://doi.org/10.1101/cshperspect.a041814
  7. Mitochondrion. 2024 Nov 04. pii: S1567-7249(24)00135-1. [Epub ahead of print] 101977
    The multifaceted modulation of mitochondrial metabolism in tumorigenesis.
    Rajendiran Keerthiga, Yafang Xie, Desheng Pei, Ailing Fu.
      Changes in mitochondrial metabolism produce a malignant transformation from normal cells to tumor cells. Mitochondrial metabolism, comprising bioenergetic metabolism, biosynthetic process, biomolecular decomposition, and metabolic signal conversion, obviously forms a unique sign in the process of tumorigenesis. Several oncometabolites produced by mitochondrial metabolism maintain tumor phenotype, which are recognized as tumor indicators. The mitochondrial metabolism synchronizes the metabolic and genetic outcome to the potent tumor microenvironmental signals, thereby further promoting tumor initiation. Moreover, the bioenergetic and biosynthetic metabolism within tumor mitochondria orchestrates dynamic contributions toward cancer progression and invasion. In this review, we describe the contribution of mitochondrial metabolism in tumorigenesis through shaping several hallmarks such as microenvironment modulation, plasticity, mitochondrial calcium, mitochondrial dynamics, and epithelial-mesenchymal transition. The review will provide a new insight into the abnormal mitochondrial metabolism in tumorigenesis, which will be conducive to tumor prevention and therapy through targeting tumor mitochondria.
    Keywords:  EMT-MET transition; OXPHOS; Oncometabolites; Plasticity; TCA cycle; Tumorigenesis
    DOI:  https://doi.org/10.1016/j.mito.2024.101977
  8. Methods Enzymol. 2024 ;pii: S0076-6879(24)00367-7. [Epub ahead of print]707 637-671
    Approaches for the analysis of redox-dependent protein import into mitochondria of mammalian cells.
    Julia Racho, Jan Riemer.
      Oxidation of cysteine residues in proteins can take place as part of an enzymatic reaction cycle, during oxidative protein folding or as a consequence of redox signalling or oxidative stress. Following changes in protein thiol redox states allows to investigate the mechanisms underlying thiol-disulphide redox processes. In this book chapter, we provide information and protocols on different methods for redox state determination with a focus on these processes in the context of oxidation-dependent protein import into the mitochondrial intermembrane space. These methods include assessing the cysteine redox state of mature proteins, methods to investigate oxidative protein folding in radioactive pulse chase assays and methods to follow specifically the formation of oxidative folding intermediates between oxidoreductases and substrates.
    Keywords:  ALR; MIA40; disulphide bond formation; import; mitochondria; oxidative protein folding; redox
    DOI:  https://doi.org/10.1016/bs.mie.2024.07.031
  9. Cell Rep. 2024 Nov 05. pii: S2211-1247(24)01264-6. [Epub ahead of print]43(11): 114913
    Metabolite signatures of chronological age, aging, survival, and longevity.
    Paola Sebastiani, Stefano Monti, Michael S Lustgarten, Zeyuan Song, Dylan Ellis, Qu Tian, Michaela Schwaiger-Haber, Ethan Stancliffe, Anastasia Leshchyk, Meghan I Short, Andres V Ardisson Korat, Anastasia Gurinovich, Tanya Karagiannis, Mengze Li, Hannah J Lords, Qingyan Xiang, Megan M Marron, Harold Bae, Mary F Feitosa, Mary K Wojczynski, Jeffrey R O'Connell, May E Montasser, Nicole Schupf, Konstantin Arbeev, Anatoliy Yashin, Nicholas Schork, Kaare Christensen, Stacy L Andersen, Luigi Ferrucci, Noa Rappaport, Thomas T Perls, Gary J Patti.
      Metabolites that mark aging are not fully known. We analyze 408 plasma metabolites in Long Life Family Study participants to characterize markers of age, aging, extreme longevity, and mortality. We identify 308 metabolites associated with age, 258 metabolites that change over time, 230 metabolites associated with extreme longevity, and 152 metabolites associated with mortality risk. We replicate many associations in independent studies. By summarizing the results into 19 signatures, we differentiate between metabolites that may mark aging-associated compensatory mechanisms from metabolites that mark cumulative damage of aging and from metabolites that characterize extreme longevity. We generate and validate a metabolomic clock that predicts biological age. Network analysis of the age-associated metabolites reveals a critical role of essential fatty acids to connect lipids with other metabolic processes. These results characterize many metabolites involved in aging and point to nutrition as a source of intervention for healthy aging therapeutics.
    Keywords:  CP: Metabolism; aging; centenarians; longevity; metabolomics
    DOI:  https://doi.org/10.1016/j.celrep.2024.114913
  10. Nature. 2024 Nov;635(8037): 193-200
    Origins and impact of extrachromosomal DNA.
    Genomics England Consortium
      Extrachromosomal DNA (ecDNA) is a major contributor to treatment resistance and poor outcome for patients with cancer1,2. Here we examine the diversity of ecDNA elements across cancer, revealing the associated tissue, genetic and mutational contexts. By analysing data from 14,778 patients with 39 tumour types from the 100,000 Genomes Project, we demonstrate that 17.1% of tumour samples contain ecDNA. We reveal a pattern highly indicative of tissue-context-based selection for ecDNAs, linking their genomic content to their tissue of origin. We show that not only is ecDNA a mechanism for amplification of driver oncogenes, but it also a mechanism that frequently amplifies immunomodulatory and inflammatory genes, such as those that modulate lymphocyte-mediated immunity and immune effector processes. Moreover, ecDNAs carrying immunomodulatory genes are associated with reduced tumour T cell infiltration. We identify ecDNAs bearing only enhancers, promoters and lncRNA elements, suggesting the combinatorial power of interactions between ecDNAs in trans. We also identify intrinsic and environmental mutational processes linked to ecDNA, including those linked to its formation, such as tobacco exposure, and progression, such as homologous recombination repair deficiency. Clinically, ecDNA detection was associated with tumour stage, more prevalent after targeted therapy and cytotoxic treatments, and associated with metastases and shorter overall survival. These results shed light on why ecDNA is a substantial clinical problem that can cooperatively drive tumour growth signals, alter transcriptional landscapes and suppress the immune system.
    DOI:  https://doi.org/10.1038/s41586-024-08107-3
  11. Cell Metab. 2024 Oct 29. pii: S1550-4131(24)00401-7. [Epub ahead of print]
    Plasma protein-based organ-specific aging and mortality models unveil diseases as accelerated aging of organismal systems.
    Ludger J E Goeminne, Anastasiya Vladimirova, Alec Eames, Alexander Tyshkovskiy, M Austin Argentieri, Kejun Ying, Mahdi Moqri, Vadim N Gladyshev.
      Aging is a complex process manifesting at molecular, cellular, organ, and organismal levels. It leads to functional decline, disease, and ultimately death, but the relationship between these fundamental biomedical features remains elusive. By applying elastic net regularization to plasma proteome data of over 50,000 human subjects in the UK Biobank and other cohorts, we report interpretable organ-specific and conventional aging models trained on chronological age, mortality, and longitudinal proteome data. These models predict organ/system-specific disease and indicate that men age faster than women in most organs. Accelerated organ aging leads to diseases in these organs, and specific diets, lifestyles, professions, and medications influence organ aging rates. We then identify proteins driving these associations with organ-specific aging. Our analyses reveal that age-related chronic diseases epitomize accelerated organ- and system-specific aging, modifiable through environmental factors, advocating for both universal whole-organism and personalized organ/system-specific anti-aging interventions.
    Keywords:  aging models; blood plasma; diet; disease; elastic net; lifestyle; longevity interventions; mortality; organ-specific aging; proteomic clocks
    DOI:  https://doi.org/10.1016/j.cmet.2024.10.005
  12. Br J Dermatol. 2024 Nov 07. pii: ljae432. [Epub ahead of print]
    Exploration of the mutational landscape of cutaneous leiomyoma confirms FH as a driver gene and identifies targeting purine metabolism as a potential therapeutic strategy.
    Louise van der Weyden, Martin Del Castillo Velasco-Herrera, Saamin Cheema, Kim Wong, Jacqueline M Boccacino, Ian Vermes, Victoria Offord, Alastair Droop, David R A Jones, Elizabeth Anderson, Claire Hardy, Nicolas de Saint Aubain, Peter M Ferguson, Carolin Mogler, Neil Rajan, Derek Frew, Paul W Harms, Steven D Billings, Désirée Schatton, Marc Segarra-Mondejar, Mark J Arends, Ingrid Ferreira, Thomas Brenn, Christian Frezza, David J Adams.
      
    DOI:  https://doi.org/10.1093/bjd/ljae432
  13. Methods Enzymol. 2024 ;pii: S0076-6879(24)00402-6. [Epub ahead of print]707 257-298
    Analysis of mitochondrial protein translocation by disulfide bond formation and cysteine specific crosslinking.
    Laura F Fielden, Jakob D Busch, Caroline Lindau, Jian Qiu, Nils Wiedemann.
      Protein translocation is a highly dynamic process and, in addition, mitochondrial protein import is especially complicated as the majority of nuclear encoded precursor proteins must engage with multiple translocases before they are assembled in the correct mitochondrial subcompartment. In this chapter, we describe assays for engineered disulfide bond formation and cysteine specific crosslinking to analyze the rearrangement of translocase subunits or to probe protein-protein interactions between precursor proteins and translocase subunits. Such assays were used to characterize the translocase of the outer membrane, the presequence translocase of the inner membrane and the sorting and assembly machinery for the biogenesis of β-Barrel proteins. Moreover, these approaches were also employed to determine the translocation path of precursor proteins (identification of import receptors and specific domains required for translocation) as well as the analysis, location and translocase subunit dependence for the formation of β-Barrel proteins. Here we describe how engineered disulfide bond formation and cysteine specific crosslinking assays are planned and performed and discuss important aspects for its application to study mitochondrial protein translocation.
    Keywords:  Mitochondria; Precursor protein; Protein biogenesis; Protein import; Protein-protein interaction; SAM complex; TIM complex; TOM complex; Translocase
    DOI:  https://doi.org/10.1016/bs.mie.2024.07.057
  14. Biochim Biophys Acta Mol Basis Dis. 2024 Oct 31. pii: S0925-4439(24)00550-7. [Epub ahead of print]1871(1): 167556
    Mitochondrial respiratory complex II is altered in renal carcinoma.
    Sona Miklovicova, Luca Volpini, Ondrej Sanovec, Federica Monaco, Katerina Hadrava Vanova, Jaromir Novak, Stepana Boukalova, Renata Zobalova, Petr Klezl, Marco Tomasetti, Vladimir Bobek, Vojtech Fiala, Josef Vcelak, Lory Santarelli, Zuzana Bielcikova, Katerina Komrskova, Katarina Kolostova, Karel Pacak, Sarka Dvorakova, Jiri Neuzil.
      BACKGROUND: Renal cell carcinoma (RCC) is a disease typified by anomalies in cell metabolism. The function of mitochondria, including subunits of mitochondrial respiratory complex II (CII), in particular SDHB, are often affected. Here we investigated the state and function of CII in RCC patients.METHODS: We evaluated tumour tissue as well as the adjacent healthy kidney tissue of 78 patients with RCC of different histotypes, focusing on their mitochondrial function. As clear cell RCC (ccRCC) is by far the most frequent histotype of RCC, we focused on these patients, which were grouped based on the pathological WHO/ISUP grading system to low- and high-grade patients, indicative of prognosis. We also evaluated mitochondrial function in organoids derived from tumour tissue of 7 patients.
    RESULTS: ccRCC tumours were characterized by mutated von Hippel-Lindau gene and high expression of carbonic anhydrase IX. We found low levels of mitochondrial DNA, protein and function, together with CII function in ccRCC tumour tissue, but not in other RCC types and non-tumour tissues. Mitochondrial content increased in high-grade tumours, while the function of CII remained low. Tumour organoids from ccRCC patients recapitulated molecular characteristics of RCC tissue.
    CONCLUSIONS: Our findings suggest that the state of CII, epitomized by its assembly and SDHB levels, deteriorates with the progressive severity of ccRCC. These observations hold the potential for stratification of patients with worse prognosis and may guide the exploration of targeted therapeutic interventions.
    Keywords:  Complex II; Metabolism; Mitochondria; Organoids; Renal cell carcinoma; Succinate dehydrogenase
    DOI:  https://doi.org/10.1016/j.bbadis.2024.167556
  15. Methods Enzymol. 2024 ;pii: S0076-6879(24)00405-1. [Epub ahead of print]707 519-539
    Analysis of mitochondrial biogenesis regulation by oxidative stress.
    Dheeraj Pathak, Thanuja Krishnamoorthy, Naresh Babu V Sepuri.
      Of all the causes of metabolic and neurological disorders, oxidative stress distinguishes itself by its sweeping effect on the dynamic cellular redox homeostasis and, in its wake, exposing the vulnerabilities of the protein machinery of the cell. High levels of Reactive Oxygen Species (ROS) that mitochondria produce during ATP synthesis can damage mtDNA, lipids, and essential mitochondrial proteins. ROS majorly oxidizes cysteine and methionine amino acids in peptides, which can lead to protein unfolding or misfolding of proteins, which ultimately can have a toll on their function. As mitochondrial biogenesis relies on the continuous import of nuclear-encoded proteins into mitochondria mediated by mitochondrial protein import complexes, oxidative stress triggered by mitochondria can rapidly and detrimentally affect mitochondrial biogenesis and homeostasis. Functional Mge1 is a homodimer and acts as a cochaperone and a nucleotide exchange factor of mitochondrial heat shock protein 70 (mHsp70), crucial for mitochondrial protein import. Oxidative stress like ROS, oxidizes Met 155 in Mge1, compromising its ability to dimerize and interact with mHsp70. The cell employs Methionine sulphoxide reductase 2 (Mxr2), a member of the methionine sulphoxide reductase family, to reduce oxidized Met 155 and thereby restore the essential function of Mge1. Oxidation of methionine as a regulated post-translational modification has been gaining traction. Future high throughput studies that can scan the entire mitochondrial proteome to interrogate methionine oxidation and reversal may increase the repertoire of mitochondrial proteins undergoing regulated oxidation and reduction. In this chapter, we describe the methods followed in our laboratory to study the oxidation of Mge1 and its reduction by Mxr2 in vitro.
    Keywords:  Cross linking; Methionine oxidation; Methionine sulfoixde reductase 2; Mge1; Mitochondria; Reactive Oxygen Species
    DOI:  https://doi.org/10.1016/bs.mie.2024.07.060
  16. Nature. 2024 Nov 06.
    Division of labour: mitochondria split to meet energy demands.
    Lena Pernas.
      
    Keywords:  Cell biology; Metabolism
    DOI:  https://doi.org/10.1038/d41586-024-03469-0
  17. Cell Calcium. 2024 Oct 23. pii: S0143-4160(24)00120-9. [Epub ahead of print]124 102962
    Does a transmembrane sodium gradient control membrane potential in mammalian mitochondria?
    David G Nicholls.
      In a recent publication, Hernansanz-Agusti̒n et al. propose that a sodium gradient across the inner mitochondrial membrane, generated by a Na+/H+ activity integral to Complex I can account for half of the mitochondrial membrane potential. This conflicts with conventional electrophysiological and chemiosmotic understanding.
    Keywords:  Calcium signaling; Goldman equation; Membrane potential; Mitochondria; Sodium proton exchange
    DOI:  https://doi.org/10.1016/j.ceca.2024.102962
  18. Curr Biol. 2024 Nov 04. pii: S0960-9822(24)01346-0. [Epub ahead of print]34(21): R1067-R1068
    Mitochondrial nucleoids.
    Eve V Kakudji, Samantha C Lewis.
      Eve Kakudji and Samantha Lewis discuss the structure and function of mitochondrial nucleoids - large nucleoprotein complexes containing mitochondrial DNA and the regulatory factors necessary for its packaging, replication, transcription, and repair.
    DOI:  https://doi.org/10.1016/j.cub.2024.09.078
  19. Nature. 2024 Nov 06.
    All we are is our memories.
    Simon Quellen Field.
      
    Keywords:  Arts; Culture
    DOI:  https://doi.org/10.1038/d41586-024-03597-7
  20. Cell. 2024 Nov 02. pii: S0092-8674(24)01190-5. [Epub ahead of print]
    Organ-specific electrophile responsivity mapping in live C. elegans.
    Jinmin Liu, Amogh Kulkarni, Yong-Qi Gao, Daniel A Urul, Romain Hamelin, Balázs Á Novotny, Marcus J C Long, Yimon Aye.
      Proximity labeling technologies are limited to indexing localized protein residents. Such data-although valuable-cannot inform on small-molecule responsivity of local residents. We here bridge this gap by demonstrating in live C. elegans how electrophile-sensing propensity in specific organs can be quantitatively mapped and ranked. Using this method, >70% of tissue-specific responders exhibit electrophile responsivity, independent of tissue-specific abundance. One responder, cyp-33e1-for which both human and worm orthologs are electrophile responsive-marshals stress-dependent gut functions, despite manifesting uniform abundance across all tissues studied. Cyp-33e1's localized electrophile responsivity operates site specifically, triggering multifaceted responses: electrophile sensing through the catalytic-site cysteine results in partitioning between enzyme inhibition and localized production of a critical metabolite that governs global lipid availability, whereas rapid dual-cysteine site-specific sensing modulates gut homeostasis. Beyond pinpointing chemical actionability within local proteomes, organ-specific electrophile responsivity mapping illuminates otherwise intractable locale-specific metabolite signaling and stress response programs influencing organ-specific decision-making.
    Keywords:  4-hydroxynonenal; C. elegans; cytochrome P450; function-guided spatial mapping; organ-specific responsivity profiling; proximity labeling proteomics; reactive metabolite signaling; tissue-specific stress response
    DOI:  https://doi.org/10.1016/j.cell.2024.10.014
  21. Methods Enzymol. 2024 ;pii: S0076-6879(24)00397-5. [Epub ahead of print]707 299-327
    STED super-resolution microscopy of mitochondrial translocases.
    Sarah V Schweighofer, Kaushik Inamdar, Daniel C Jans, Stefan Jakobs.
      The mitochondrial translocases of the outer membrane (TOM) and of the inner membrane (TIM) act together to facilitate the import of nuclear-encoded proteins across the mitochondrial membranes. Stimulated Emission Depletion (STED) super-resolution microscopy enables the in situ imaging of such complexes in single cells at sub-diffraction resolution. STED microscopy requires only conventional sample preparation techniques and provides super-resolved raw data without the need for further image processing. In this chapter, we provide a detailed example protocol for STED microscopy of TOM20 and mitochondrial DNA in fixed mammalian cells. The protocol includes instructions on sample preparation for immunolabeling, including cell line selection, fixation, permeabilization, blocking, labeling and mounting, but also recommendations for sample and microscope performance evaluation. The protocol is supplemented by considerations on key factors that influence the quality of the final image and also includes some considerations for the analysis of the acquired images. While the protocol described here is aimed at imaging TOM20 and DNA, it contains all the information for an immediate adaptation to other cellular targets.
    DOI:  https://doi.org/10.1016/bs.mie.2024.07.052
  22. Nature. 2024 Nov;635(8037): 201-209
    Coordinated inheritance of extrachromosomal DNAs in cancer cells.
    King L Hung, Matthew G Jones, Ivy Tsz-Lo Wong, Ellis J Curtis, Joshua T Lange, Britney Jiayu He, Jens Luebeck, Rachel Schmargon, Elisa Scanu, Lotte Brückner, Xiaowei Yan, Rui Li, Aditi Gnanasekar, Rocío Chamorro González, Julia A Belk, Zhonglin Liu, Bruno Melillo, Vineet Bafna, Jan R Dörr, Benjamin Werner, Weini Huang, Benjamin F Cravatt, Anton G Henssen, Paul S Mischel, Howard Y Chang.
      The chromosomal theory of inheritance dictates that genes on the same chromosome segregate together while genes on different chromosomes assort independently1. Extrachromosomal DNAs (ecDNAs) are common in cancer and drive oncogene amplification, dysregulated gene expression and intratumoural heterogeneity through random segregation during cell division2,3. Distinct ecDNA sequences, termed ecDNA species, can co-exist to facilitate intermolecular cooperation in cancer cells4. How multiple ecDNA species within a tumour cell are assorted and maintained across somatic cell generations is unclear. Here we show that cooperative ecDNA species are coordinately inherited through mitotic co-segregation. Imaging and single-cell analyses show that multiple ecDNAs encoding distinct oncogenes co-occur and are correlated in copy number in human cancer cells. ecDNA species are coordinately segregated asymmetrically during mitosis, resulting in daughter cells with simultaneous copy-number gains in multiple ecDNA species before any selection. Intermolecular proximity and active transcription at the start of mitosis facilitate the coordinated segregation of ecDNA species, and transcription inhibition reduces co-segregation. Computational modelling reveals the quantitative principles of ecDNA co-segregation and co-selection, predicting their observed distributions in cancer cells. Coordinated inheritance of ecDNAs enables co-amplification of specialized ecDNAs containing only enhancer elements and guides therapeutic strategies to jointly deplete cooperating ecDNA oncogenes. Coordinated inheritance of ecDNAs confers stability to oncogene cooperation and novel gene regulatory circuits, allowing winning combinations of epigenetic states to be transmitted across cell generations.
    DOI:  https://doi.org/10.1038/s41586-024-07861-8
  23. Trends Cell Biol. 2024 Nov;pii: S0962-8924(23)00205-2. [Epub ahead of print]34(11): 928-941
    Regulation of leukemogenesis via redox metabolism.
    Zhuo Zhang, Chiqi Chen, Xie Li, Junke Zheng, Yuzheng Zhao.
      Redox metabolism plays a central role in the cellular metabolism network, involves catabolic and anabolic reactions of diverse biomass, and determines the redox state of cells. It can be quantitatively and conveniently measured in living cells and organisms with genetically encoded fluorescent sensors, providing novel insights that cannot be readily acquired via conventional metabolic assays. Here, we review the recent progress on the regulation of leukemogenesis via redox metabolism, especially redox biosensor-based findings. In general, low reactive oxygen species levels and high reductive capacity promote leukemogenesis and chemotherapy resistance in leukemia cells, and acute leukemia cells rewire metabolism of glucose, fatty acids, and some amino acids, together with oxidative phosphorylation, to fuel energy production, support biomass-related synthesis, and survive oxidative stress. In summary, redox metabolism is a potential target for the development of novel therapies for leukemia or beneficial dietary regimens for patients with refractory and relapsed leukemia.
    Keywords:  genetically encoded redox sensors; leukemia; leukemia-initiating cells; real-time monitoring; redox metabolism
    DOI:  https://doi.org/10.1016/j.tcb.2023.10.001
  24. Nature. 2024 Nov 06.
    A new kind of mitochondrion.
    Nick Petrić Howe.
      
    Keywords:  Cell biology; Metabolism
    DOI:  https://doi.org/10.1038/d41586-024-03636-3
  25. Nat Commun. 2024 Nov 01. 15(1): 9438
    Transfer of mitochondrial DNA into the nuclear genome during induced DNA breaks.
    Jinchun Wu, Yang Liu, Liqiong Ou, Tingting Gan, Zhengrong Zhangding, Shaopeng Yuan, Xinyi Liu, Mengzhu Liu, Jiasheng Li, Jianhang Yin, Changchang Xin, Ye Tian, Jiazhi Hu.
      Mitochondria serve as the cellular powerhouse, and their distinct DNA makes them a prospective target for gene editing to treat genetic disorders. However, the impact of genome editing on mitochondrial DNA (mtDNA) stability remains a mystery. Our study reveals previously unknown risks of genome editing that both nuclear and mitochondrial editing cause discernible transfer of mitochondrial DNA segments into the nuclear genome in various cell types including human cell lines, primary T cells, and mouse embryos. Furthermore, drug-induced mitochondrial stresses and mtDNA breaks exacerbate this transfer of mtDNA into the nuclear genome. Notably, we observe that mitochondrial editors, including mitoTALEN and recently developed base editor DdCBE, can also enhance crosstalk between mtDNA and the nuclear genome. Moreover, we provide a practical solution by co-expressing TREX1 or TREX2 exonucleases during DdCBE editing. These findings imply genome instability of mitochondria during induced DNA breaks and explain the origins of mitochondrial-nuclear DNA segments.
    DOI:  https://doi.org/10.1038/s41467-024-53806-0
  26. Cell Calcium. 2024 Oct 29. pii: S0143-4160(24)00124-6. [Epub ahead of print]124 102966
    Calcium signals as regulators of ferroptosis in cancer.
    Ioana Stejerean-Todoran, Christine S Gibhardt, Ivan Bogeski.
      The field of ferroptosis research has grown exponentially since this form of cell death was first identified over a decade ago. Ferroptosis, an iron- and ROS-dependent type of cell death, is controlled by various metabolic pathways, including but not limited to redox and calcium (Ca2+) homeostasis, iron fluxes, mitochondrial function and lipid metabolism. Importantly, therapy-resistant tumors are particularly susceptible to ferroptotic cell death, rendering ferroptosis a promising therapeutic strategy against numerous malignancies. Calcium signals are important regulators of both cancer progression and cell death, with recent studies indicating their involvement in ferroptosis. Cells undergoing ferroptosis are characterized by plasma membrane rupture and the formation of nanopores, which facilitate influx of ions such as Ca2+ into the affected cells. Furthermore, mitochondrial Ca²⁺ levels have been implicated in directly influencing the cellular response to ferroptosis. Despite the remarkable progress made in the field, our understanding of the contribution of Ca2+ signals to ferroptosis remains limited. Here, we summarize key connections between Ca²⁺ signaling and ferroptosis in cancer pathobiology and discuss their potential therapeutic significance.
    Keywords:  Calcium; Cancer; Ferroptosis; Mitochondria; ROS
    DOI:  https://doi.org/10.1016/j.ceca.2024.102966
  27. Bioessays. 2024 Nov 06. e2400206
    Cell-cell fusion: To lose one life and begin another.
    Jarred M Whitlock, Leonid V Chernomordik.
      As life extended into eukaryota, a great host of strategies emerged in the pursuit of cellular life. Some cells have been successful in solitude, some moved into cooperatives (i.e., multicellular organisms), but one additional strategy emerged. Throughout eukaryotes, many of the diverse multicellular cooperatives took life in partnership one step further. These cells came together and lost their singularity in the expanse of syncytial life. Recently in our search for this elusive "how", we discovered the intriguing peculiarity of a nuclear, RNA-binding protein living a second life as a fusion manager at the surface of developing osteoclasts, ushering them into syncytia 1. It is from here that we will develop several thoughts about the advantages of multinucleated cells and discuss how these fusing cells pass through several hallmarks of cell death. We will propose that cell fusion shares much with cell death because cell fusion is a death of sorts for the cells that undergo it - a death of the life that was and the beginning of new life in a community without borders.
    Keywords:  apoptosis; cell‐cell fusion; membrane fusion; myoblast; osteoclast; syncytia
    DOI:  https://doi.org/10.1002/bies.202400206
  28. Biosystems. 2023 Oct 28. pii: S0303-2647(23)00242-3. [Epub ahead of print] 105067
    Whole-cell metabolic control analysis.
    Frank J Bruggeman, Maaike Remeijer, Maarten Droste, Luis Salinas, Meike Wortel, Robert Planqué, Herbert M Sauro, Bas Teusink, Hans V Westerhoff.
      Since its conception some fifty years ago, metabolic control analysis (MCA) aims to understand how cells control their metabolism by adjusting the activity of their enzymes. Here we extend its scope to a whole-cell context. We consider metabolism in the evolutionary context of growth-rate maximisation by optimisation of protein concentrations. This framework allows for the prediction of flux control coefficients from proteomics data or stoichiometric modelling. Since genes compete for finite biosynthetic resources, we treat all protein concentrations as interdependent. We show that elementary flux modes (EFMs) emerge naturally as the optimal metabolic networks in the whole-cell context and we derive their control properties. In the evolutionary optimum, the number of expressed EFMs is determined by the number of protein-concentration constraints that limit growth rate. We use published glucose-limited chemostat data of S. cerevisiae to illustrate that it uses only two EFMs prior to the onset of fermentation and that it uses four EFMs during fermentation. We discuss published enzyme-titration data to show that S. cerevisiae and E. coli indeed can express proteins at growth-rate maximising concentrations. Accordingly, we extend MCA to elementary flux modes operating at an optimal state. We find that the expression of growth-unassociated proteins changes results from classical metabolic control analysis. Finally, we show how flux control coefficients can be estimated from proteomics and ribosome-profiling data. We analyse published proteomics data of E. coli to provide a whole-cell perspective of the control of metabolic enzymes on growth rate. We hope that this paper stimulates a renewed interest in metabolic control analysis, so that it can serve again the purpose it once had: to identify general principles that emerge from the biochemistry of the cell and are conserved across biological species.
    Keywords:  Elementary flux modes; Enzyme kinetics; Metabolic control analysis; Whole cell models
    DOI:  https://doi.org/10.1016/j.biosystems.2023.105067
  29. Mol Cell. 2024 Oct 25. pii: S1097-2765(24)00832-3. [Epub ahead of print]
    mTORC1 restricts TFE3 activity by auto-regulating its presence on lysosomes.
    Susan Zwakenberg, Denise Westland, Robert M van Es, Holger Rehmann, Jasper Anink, Jolita Ciapaite, Marjolein Bosma, Ellen Stelloo, Nalan Liv, Paula Sobrevals Alcaraz, Nanda M Verhoeven-Duif, Judith J M Jans, Harmjan R Vos, Eleonora Aronica, Fried J T Zwartkruis.
      To stimulate cell growth, the protein kinase complex mTORC1 requires intracellular amino acids for activation. Amino-acid sufficiency is relayed to mTORC1 by Rag GTPases on lysosomes, where growth factor signaling enhances mTORC1 activity via the GTPase Rheb. In the absence of amino acids, GATOR1 inactivates the Rags, resulting in lysosomal detachment and inactivation of mTORC1. We demonstrate that in human cells, the release of mTORC1 from lysosomes depends on its kinase activity. In accordance with a negative feedback mechanism, activated mTOR mutants display low lysosome occupancy, causing hypo-phosphorylation and nuclear localization of the lysosomal substrate TFE3. Surprisingly, mTORC1 activated by Rheb does not increase the cytoplasmic/lysosomal ratio of mTORC1, indicating the existence of mTORC1 pools with distinct substrate specificity. Dysregulation of either pool results in aberrant TFE3 activity and may explain nuclear accumulation of TFE3 in epileptogenic malformations in focal cortical dysplasia type II (FCD II) and tuberous sclerosis (TSC).
    Keywords:  FCD IIb; NPRL2; Rag GTPases; Rheb; TFE3; TSC; amino acids; lysosomes; mTORC1
    DOI:  https://doi.org/10.1016/j.molcel.2024.10.009
This page is being maintained by Thomas Krichel. It was last updated on 2024‒11‒10 at 6:10.