bims-mitrat Biomed News
on Mitochondrial Transplantation and Transfer
Issue of 2024‒08‒18
thirteen papers selected by
Gökhan Burçin Kubat, Gulhane Health Sciences Institute
  1. Mitochondrial Transfer in the Neurovascular Unit, Not Only for Energy Rescue: A Systematic Review.
  2. Adipose Stem Cells and Their Interplay with Cancer Cells and Mitochondrial Reservoir: A New Promising Target.
  3. Engineered Mitochondrial Transplantation as An Anti-Aging Therapy.
  4. Dental pulp stem cells promote malignant transformation of oral epithelial cells through mitochondrial transfer.
  5. Secondary mitochondrial dysfunction across the spectrum of hereditary and acquired muscle disorders.
  6. Mitochondria Transplantation to Bone Marrow Stromal Cells Promotes Angiogenesis During Bone Repair.
  7. Mitochondrial Ca 2+ controls pancreatic cancer growth and metastasis by regulating epithelial cell plasticity.
  8. Mitochondrial-derived compartments are multilamellar domains that encase membrane cargo and cytosol.
  9. Mitochondrial network reorganization and transient expansion during oligodendrocyte generation.
  10. Autophagy in Skeletal Muscle.
  11. Exercise-specific adaptations in human skeletal muscle: Molecular mechanisms of making muscles fit and mighty.
  12. Current methodologies for inducing aligned myofibers in tissue constructs for skeletal muscle tissue regeneration.
  13. Platelet extracellular vesicles preserve lymphatic endothelial cell integrity and enhance lymphatic vessel function.
  1. Aging Dis. 2024 Jul 30.
    Mitochondrial Transfer in the Neurovascular Unit, Not Only for Energy Rescue: A Systematic Review.
    Daqiang Zhou, Sibo Yang, Jiehong Wu, Yanan Li, Huijuan Jin, Yan Luo, Feng Zhang, Junjie Jiang, Bo Hu, Yifan Zhou.
      Despite substantial evidence highlighting molecular communication within the components of neurovascular units (NVU), the interactions at the organelle level have been insufficiently explored in recent decades. Mitochondria, for instance, beyond their traditional role as energy supply for intracellular metabolism and survival, provide a novel perspective on intercellular connections through mitochondrial transfer. These transferred mitochondria not only carry bioactive molecules but also signal to mitigate risks in both healthy and pathological conditions. In this review, we summarized mitochondrial transfer events, relevant routes, and underlying molecular mechanisms originating from diverse cell populations within NVU. We particularly focus on the therapeutic potential of this mechanism in treating central nervous system disorders, notably neurodegenerative diseases marked by mitochondrial dysfunction and then highlight the promising prospects of exogenous mitochondrial supplementation as a treatment target.
    DOI:  https://doi.org/10.14336/AD.2024.0461
  2. Cancers (Basel). 2024 Aug 05. pii: 2769. [Epub ahead of print]16(15):
    Adipose Stem Cells and Their Interplay with Cancer Cells and Mitochondrial Reservoir: A New Promising Target.
    Ayesha Rehman, Martina Marigliano, Martina Torsiello, Marcella La Noce, Gianpaolo Papaccio, Virginia Tirino, Vitale Del Vecchio, Federica Papaccio.
      Adipose-derived stem cells (ASCs) significantly influence tumor progression within the tumor microenvironment (TME). This review examines the pro-tumorigenic roles of ASCs, focusing on paracrine signaling, direct cell-cell interactions, and immunomodulation. ASC-mediated mitochondrial transfer through tunneling nanotubes (TNTs) and gap junctions (GJs) plays a significant role in enhancing cancer cell survival and metabolism. Cancer cells with dysfunctional mitochondria acquire mitochondria from ASCs to meet their metabolic needs and thrive in the TME. Targeting mitochondrial transfer, modulating ASC function, and influencing metabolic pathways are potential therapeutic strategies. However, challenges like TME complexity, specificity, safety concerns, and resistance mechanisms must be addressed. Disrupting the ASC-cancer cell-mitochondria axis offers a promising approach to cancer therapy.
    Keywords:  ASCs; CSCs; TME; cancer therapy; drug resistance; mitochondria
    DOI:  https://doi.org/10.3390/cancers16152769
  3. Aging Dis. 2024 Jul 19.
    Engineered Mitochondrial Transplantation as An Anti-Aging Therapy.
    Rui Zhao, Chen Dong, Qian Liang, Jianlin Gao, Chi Sun, Zhifeng Gu, Yujuan Zhu.
      Aging is an inevitable and complex biological process involving multi-factorial mechanisms. Mitochondrial dysfunction is a critical factor in the aging process, characterized by a decline in mitochondrial quality and activity, leading to aging and aging-related diseases. Therefore, mitochondria have become an attractive target in anti-aging therapies. Several senolytic drugs targeting mitochondria and antioxidant agents have been used in anti-aging research in the past few years. However, these strategies may cause adverse effects with long-term medication. In this extensive review, we propose "mitochondrial transplantation," which transfers healthy mitochondria from donor cells to recipient cells to replace damaged or dysfunctional mitochondria, as a new alternative strategy for treating mitochondrial dysfunction and aging-associated diseases. In this review, we introduce the contemporary landscape of mitochondrial transplantation, then discuss intensely the successful applications of mitochondrial transplantation therapy in aging diseases such as neurodegenerative diseases, cardiovascular aging, and reproductive aging, highlighting its translational potential. Finally, we summarize and prospect the challenges and opportunities mitochondrial transplantation faces in anti-aging therapy.
    DOI:  https://doi.org/10.14336/AD.2024.0231
  4. Med Mol Morphol. 2024 Aug 09.
    Dental pulp stem cells promote malignant transformation of oral epithelial cells through mitochondrial transfer.
    Peiqi Shen, Zeyi Ma, Xiaoqing Xu, Weiyu Li, Yaoyin Li.
      Oral epithelial dysplasia includes a range of clinical oral mucosal diseases with potentially malignant traits. Dental pulp stem cells (DPSCs) are potential candidates for cell-based therapies targeting various diseases. However, the effect of DPSCs on the progression of oral mucosal precancerous lesions remains unclear. Animal experiments were conducted to assess the effect of human DPSCs (hDPSCs). We measured the proliferation, motility and mitochondrial respiratory function of the human dysplastic oral keratinocyte (DOK) cells cocultured with hDPSCs. Mitochondrial transfer experiments were performed to determine the role mitochondria from hDPSCs in the malignant transformation of DOK cells. hDPSCs injection accelerated carcinogenesis in 4NQO-induced oral epithelial dysplasia in mice. Coculture with hDPSCs increased the proliferation, migration, invasion and mitochondrial respiratory function of DOK cells. Mitochondria from hDPSCs could be transferred to DOK cells, and activated mTOR signaling pathway in DOK cells. Our study demonstrates that hDPSCs activate the mTOR signaling pathway through mitochondrial transfer, promoting the malignant transformation of oral precancerous epithelial lesions.
    Keywords:  Dental pulp stem cells; Dysplastic oral keratinocyte cell line; Malignant transformation; Mitochondrial transfer; Oral epithelial dysplasia
    DOI:  https://doi.org/10.1007/s00795-024-00403-1
  5. Mitochondrion. 2024 Aug 10. pii: S1567-7249(24)00103-X. [Epub ahead of print] 101945
    Secondary mitochondrial dysfunction across the spectrum of hereditary and acquired muscle disorders.
    Gloria Mak, Mark Tarnopolsky, Jian-Qiang Lu.
      Mitochondria form a dynamic network within skeletal muscle. This network is not only responsible for producing adenine triphosphate through oxidative phosphorylation, but also responds through fission, fusion and mitophagy to various factors, such as increased energy demands, oxidative stress, inflammation, and calcium dysregulation. Mitochondrial dysfunction in skeletal muscle not only occurs in primary mitochondrial myopathies, but also other hereditary and acquired myopathies. As such, this review attempts to highlight the clinical and histopathologic aspects of mitochondrial dysfunction seen in hereditary and acquired myopathies, as well as discuss potential mechanisms leading to mitochondrial dysfunction and therapies to restore mitochondrial function.
    Keywords:  Congenital myopathies; Inflammatory myopathies; Mitochondrial dysfunction; Muscular dystrophies
    DOI:  https://doi.org/10.1016/j.mito.2024.101945
  6. Adv Sci (Weinh). 2024 Aug 13. e2403201
    Mitochondria Transplantation to Bone Marrow Stromal Cells Promotes Angiogenesis During Bone Repair.
    Yifan Wang, Wenjing Li, Yusi Guo, Ying Huang, Yaru Guo, Jia Song, Feng Mei, Peiwen Liao, Zijian Gong, Xiaopei Chi, Xuliang Deng.
      Angiogenesis is crucial for successful bone defect repair. Co-transplanting Bone Marrow Stromal Cells (BMSCs) and Endothelial Cells (ECs) has shown promise for vascular augmentation, but it face challenges in hostile tissue microenvironments, including poor cell survival and limited efficacy. In this study, the mitochondria of human BMSCs are isolated and transplanted to BMSCs from the same batch and passage number (BMSCsmito). The transplanted mitochondria significantly boosted the ability of BMSCsmito-ECs to promote angiogenesis, as assessed by in vitro tube formation and spheroid sprouting assays, as well as in vivo transplantation experiments in balb/c mouse and SD rat models. The Dll4-Notch1 signaling pathway is found to play a key role in BMSCsmito-induced endothelial tube formation. Co-transplanting BMSCsmito with ECs in a rat cranial bone defect significantly improves functional vascular network formation, and improve bone repair outcomes. These findings thus highlight that mitochondrial transplantation, by acting through the DLL4-Notch1 signaling pathway, represents a promising therapeutic strategy for enhancing angiogenesis and improving bone repair. Hence, mitochondrial transplantation to BMSCS as a therapeutic approach for promoting angiogenesis offers valuable insights and holds much promise for innovative regenerative medicine therapies.
    Keywords:  angiogenesis; bone marrow stromal cells; bone repair; co‐transplantation; endothelial cells; mitochondria; mitochondria transplantation
    DOI:  https://doi.org/10.1002/advs.202403201
  7. bioRxiv. 2024 Aug 09. pii: 2024.08.08.607195. [Epub ahead of print]
    Mitochondrial Ca 2+ controls pancreatic cancer growth and metastasis by regulating epithelial cell plasticity.
    Jillian S Weissenrieder, Jessica Peura, Usha Paudel, Nikita Bhalerao, Natalie Weinmann, Calvin Johnson, Maximilian Wengyn, Rebecca Drager, Emma Elizabeth Furth, Karl Simin, Marcus Ruscetti, Ben Z Stanger, Anil K Rustgi, Jason R Pitarresi, J Kevin Foskett.
      Endoplasmic reticulum to mitochondria Ca 2+ transfer is important for cancer cell survival, but the role of mitochondrial Ca 2+ uptake through the mitochondrial Ca 2+ uniporter (MCU) in pancreatic adenocarcinoma (PDAC) is poorly understood. Here, we show that increased MCU expression is associated with malignancy and poorer outcomes in PDAC patients. In isogenic murine PDAC models, Mcu deletion ( Mcu KO ) ablated mitochondrial Ca 2+ uptake, which reduced proliferation and inhibited self-renewal. Orthotopic implantation of MCU-null tumor cells reduced primary tumor growth and metastasis. Mcu deletion reduced the cellular plasticity of tumor cells by inhibiting epithelial-to-mesenchymal transition (EMT), which contributes to metastatic competency in PDAC. Mechanistically, the loss of mitochondrial Ca 2+ uptake reduced expression of the key EMT transcription factor Snail and secretion of the EMT-inducing ligand TGFβ. Snail re-expression and TGFβ treatment rescued deficits in Mcu KO cells and restored their metastatic ability. Thus, MCU may present a therapeutic target in PDAC to limit cancer-cell-induced EMT and metastasis.
    DOI:  https://doi.org/10.1101/2024.08.08.607195
  8. J Cell Biol. 2024 Nov 04. pii: e202307035. [Epub ahead of print]223(11):
    Mitochondrial-derived compartments are multilamellar domains that encase membrane cargo and cytosol.
    Zachary N Wilson, Matt West, Alyssa M English, Greg Odorizzi, Adam L Hughes.
      Preserving the health of the mitochondrial network is critical to cell viability and longevity. To do so, mitochondria employ several membrane remodeling mechanisms, including the formation of mitochondrial-derived vesicles (MDVs) and compartments (MDCs) to selectively remove portions of the organelle. In contrast to well-characterized MDVs, the distinguishing features of MDC formation and composition remain unclear. Here, we used electron tomography to observe that MDCs form as large, multilamellar domains that generate concentric spherical compartments emerging from mitochondrial tubules at ER-mitochondria contact sites. Time-lapse fluorescence microscopy of MDC biogenesis revealed that mitochondrial membrane extensions repeatedly elongate, coalesce, and invaginate to form these compartments that encase multiple layers of membrane. As such, MDCs strongly sequester portions of the outer mitochondrial membrane, securing membrane cargo into a protected domain, while also enclosing cytosolic material within the MDC lumen. Collectively, our results provide a model for MDC formation and describe key features that distinguish MDCs from other previously identified mitochondrial structures and cargo-sorting domains.
    DOI:  https://doi.org/10.1083/jcb.202307035
  9. Nat Commun. 2024 Aug 14. 15(1): 6979
    Mitochondrial network reorganization and transient expansion during oligodendrocyte generation.
    Xhoela Bame, Robert A Hill.
      Oligodendrocyte precursor cells (OPCs) give rise to myelinating oligodendrocytes of the brain. This process persists throughout life and is essential for recovery from neurodegeneration. To better understand the cellular checkpoints that occur during oligodendrogenesis, we determined the mitochondrial distribution and morphometrics across the oligodendrocyte lineage in mouse and human cerebral cortex. During oligodendrocyte generation, mitochondrial content expands concurrently with a change in subcellular partitioning towards the distal processes. These changes are followed by an abrupt loss of mitochondria in the oligodendrocyte processes and myelin, coinciding with sheath compaction. This reorganization and extensive expansion and depletion take 3 days. Oligodendrocyte mitochondria are stationary over days while OPC mitochondrial motility is modulated by animal arousal state within minutes. Aged OPCs also display decreased mitochondrial size, volume fraction, and motility. Thus, mitochondrial dynamics are linked to oligodendrocyte generation, dynamically modified by their local microenvironment, and altered in the aging brain.
    DOI:  https://doi.org/10.1038/s41467-024-51016-2
  10. Cold Spring Harb Perspect Biol. 2024 Aug 12. pii: a041565. [Epub ahead of print]
    Autophagy in Skeletal Muscle.
    Anais Franco-Romero, Marco Sandri, Stefano Schiaffino.
      Skeletal muscle fibers possess, like all cells of our body, an evolutionary conserved autophagy machinery, which allows them to segregate unfolded proteins and damaged organelles within autophagosomes, and to induce fusion of autophagosomes with lysosomes, leading to degradation of those altered cell constituents. This process may be selective for specific cell components, as in the case of glycogen (glycophagy) or organelles, as with mitochondria (mitophagy). The autophagic flux is activated by fasting, and contributes with the proteasome to provide the organism with amino acids required for survival. Autophagy is also essential for the normal turnover of muscle proteins and organelles, as shown by the degenerative changes induced by genetic block of the autophagic mechanism, and in several myopathies. Autophagy is enhanced in muscle by exercise and impaired during aging, suggesting that aging-dependent muscle dysfunction could be delayed by boosting autophagy.
    DOI:  https://doi.org/10.1101/cshperspect.a041565
  11. Free Radic Biol Med. 2024 Aug 13. pii: S0891-5849(24)00600-2. [Epub ahead of print]223 341-356
    Exercise-specific adaptations in human skeletal muscle: Molecular mechanisms of making muscles fit and mighty.
    Aaron C Q Thomas, Connor A Stead, Jatin G Burniston, Stuart M Phillips.
      The mechanisms leading to a predominantly hypertrophied phenotype versus a predominantly oxidative phenotype, the hallmarks of resistance training (RT) or aerobic training (AT), respectively, are being unraveled. In humans, exposure of naïve persons to either AT or RT results in their skeletal muscle exhibiting generic 'exercise stress-related' signaling, transcription, and translation responses. However, with increasing engagement in AT or RT, the responses become refined, and the phenotype typically associated with each form of exercise emerges. Here, we review some of the mechanisms underpinning the adaptations of how muscles become, through AT, 'fit' and RT, 'mighty.' Much of our understanding of molecular exercise physiology has arisen from targeted analysis of post-translational modifications and measures of protein synthesis. Phosphorylation of specific residue sites has been a dominant focus, with canonical signaling pathways (AMPK and mTOR) studied extensively in the context of AT and RT, respectively. These alone, along with protein synthesis, have only begun to elucidate key differences in AT and RT signaling. Still, key yet uncharacterized differences exist in signaling and regulation of protein synthesis that drive unique adaptation to AT and RT. Omic studies are required to better understand the divergent relationship between exercise and phenotypic outcomes of training.
    Keywords:  Human; Hypertrophy; Mitochondria; Protein signaling; Protein turnover
    DOI:  https://doi.org/10.1016/j.freeradbiomed.2024.08.010
  12. Adv Wound Care (New Rochelle). 2024 Aug 10.
    Current methodologies for inducing aligned myofibers in tissue constructs for skeletal muscle tissue regeneration.
    Sydnee T Sicherer, Noor Haque, Yash Parikh, Jonathan Grasman.
      SIGNIFICANCE: Volumetric muscle loss (VML) results in the loss of large amounts of tissue that inhibits muscle regeneration. Existing therapies, such as autologous muscle transfer and physical therapy, are incapable of returning full function and force production to injured muscle.RECENT ADVANCES: Skeletal muscle tissue constructs may provide an alternative to existing therapies currently used to treat VML. Unlike autologous muscle transplants, muscle constructs can be cultured in vitro and are not reliant on intact muscle tissue. Skeletal muscle constructs can be generated from small muscle biopsies and could be used to generate skeletal muscle tissue constructs to replace injured tissues.
    CRITICAL ISSUES: To serve as effective therapies, muscle constructs must be capable of generating contractile forces that can assist the function of host skeletal muscle. The contractile force of native muscle arises in part as a consequence of the highly aligned, bundled architecture of myofibers. Attempts to induce similar alignment include: applications of tension/strain across hydrogels, inducing aligned architectures within scaffolds, casting tissues in straited molds, and 3D printing. While all these methods have demonstrated efficacy towards inducing myofiber alignment, the extent of myofiber alignment, tissue formation, and force production varies. This manuscript critically reviews the advantages and limitations of these methods, and specifically discusses their ability to impart mechanical and architectural cues to induce alignment within constructs.
    FUTURE DIRECTIONS: As tissue synthesizing techniques continue to improve, muscle constructs must include more cell types than simply myoblasts, such as the addition of neuronal and endothelial cells. Higher level tissue organization is critical to the success of these constructs. Many of these technologies have yet to be implanted into host tissue to understand engraftment and how they can contribute to traumatic injury, and as such continued collaboration between surgeons and tissue engineers is necessary to ultimately result in clinical translation.
    DOI:  https://doi.org/10.1089/wound.2024.0111
  13. Commun Biol. 2024 Aug 11. 7(1): 975
    Platelet extracellular vesicles preserve lymphatic endothelial cell integrity and enhance lymphatic vessel function.
    Laurent Vachon, Gabriel Jean, Andreea Milasan, Sara Babran, Elizabeth Lacroix, Dainelys Guadarrama Bello, Louis Villeneuve, Janusz Rak, Antonio Nanci, Teodora Mihalache-Avram, Jean-Claude Tardif, Vincent Finnerty, Matthieu Ruiz, Eric Boilard, Nolwenn Tessier, Catherine Martel.
      Lymphatic vessels are essential for preventing the accumulation of harmful components within peripheral tissues, including the artery wall. Various endogenous mechanisms maintain adequate lymphatic function throughout life, with platelets being essential for preserving lymphatic vessel integrity. However, since lymph lacks platelets, their impact on the lymphatic system has long been viewed as restricted to areas where lymphatics intersect with blood vessels. Nevertheless, platelets can also exert long range effects through the release of extracellular vesicles (EVs) upon activation. We observed that platelet EVs (PEVs) are present in lymph, a compartment to which they could transfer regulatory effects of platelets. Here, we report that PEVs in lymph exhibit a distinct signature enabling them to interact with lymphatic endothelial cells (LECs). In vitro experiments show that the internalization of PEVs by LECs maintains their functional integrity. Treatment with PEVs improves lymphatic contraction capacity in atherosclerosis-prone mice. We suggest that boosting lymphatic pumping with exogenous PEVs offers a novel therapeutic approach for chronic inflammatory diseases characterized by defective lymphatics.
    DOI:  https://doi.org/10.1038/s42003-024-06675-8
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