Your search keyword '"Mitochondrial transfer"' showing total 607 results

1. Intercellular nanotube-mediated mitochondrial transfer enhances T cell metabolic fitness and antitumor efficacy.

Author

Baldwin, Jeremy G., Heuser-Loy, Christoph, Saha, Tanmoy, Schelker, Roland C., Slavkovic-Lukic, Dragana, Strieder, Nicholas, Hernandez-Lopez, Inmaculada, Rana, Nisha, Barden, Markus, Mastrogiovanni, Fabio, Martín-Santos, Azucena, Raimondi, Andrea, Brohawn, Philip, Higgs, Brandon W., Gebhard, Claudia, Kapoor, Veena, Telford, William G., Gautam, Sanjivan, Xydia, Maria, and Beckhove, Philipp

Abstract

Mitochondrial loss and dysfunction drive T cell exhaustion, representing major barriers to successful T cell-based immunotherapies. Here, we describe an innovative platform to supply exogenous mitochondria to T cells, overcoming these limitations. We found that bone marrow stromal cells establish nanotubular connections with T cells and leverage these intercellular highways to transplant stromal cell mitochondria into CD8+ T cells. Optimal mitochondrial transfer required Talin 2 on both donor and recipient cells. CD8+ T cells with donated mitochondria displayed enhanced mitochondrial respiration and spare respiratory capacity. When transferred into tumor-bearing hosts, these supercharged T cells expanded more robustly, infiltrated the tumor more efficiently, and exhibited fewer signs of exhaustion compared with T cells that did not take up mitochondria. As a result, mitochondria-boosted CD8+ T cells mediated superior antitumor responses, prolonging animal survival. These findings establish intercellular mitochondrial transfer as a prototype of organelle medicine, opening avenues to next-generation cell therapies. [Display omitted] • BMSCs transfer mitochondria to CD8+ T cells via intercellular nanotube connections • Mitochondrial transfer between BMSCs and CD8+ T cells depends on Talin 2 • Mitochondrial transfer augments CD8+ T cell mitochondria mass and metabolic fitness • Mitochondria-boosted mouse and human CD8+ T cells exhibit superior antitumor efficacy Transfer of mitochondria via nanotubes from bone marrow stem cells to CD8+ T cells augments cellular metabolism, empowering engineered T cells and tumor-infiltrating lymphocytes to counteract exhaustion and fight tumors more effectively. [ABSTRACT FROM AUTHOR]

Published

2024

2. From dysfunction to healing: advances in mitochondrial therapy for Osteoarthritis.

Author

Zhang, Minghang, Wu, Junfeng, Cai, Kehan, Liu, Yang, Lu, Botao, Zhang, Jiaojiao, Xu, Jianzhong, Gu, Chenxi, and Chen, Tao

Abstract

Osteoarthritis (OA) is a chronic degenerative joint condition characterised by cartilage deterioration and changes in bone morphology, resulting in pain and impaired joint mobility. Investigation into the pathophysiological mechanisms underlying OA has highlighted the significance of mitochondrial dysfunction in its progression. Mitochondria, which are cellular organelles, play a crucial role in regulating energy metabolism, generating reactive oxygen species, and facilitating essential biological processes including apoptosis. In recent years, the utilisation of exogenous drugs and MT to improve mitochondrial function in chondrocytes has shown great promise in OA treatment. Numerous studies have investigated the potential of stem cells and extracellular vesicles in mitochondrial transfer. This review aims to explore the underlying mechanisms of mitochondrial dysfunction in OA and assess the progress in utilising mitochondrial transfer as a therapeutic approach for this disease. [ABSTRACT FROM AUTHOR]

Published

2024

3. An Engineered Hierarchical Hydrogel with Immune Responsiveness and Targeted Mitochondrial Transfer to Augmented Bone Regeneration.

Author

Cai, Wenjin, Mao, Shihua, Wang, Ying, Gao, Bicong, Zhao, Jiaying, Li, Yongzheng, Chen, Yani, Zhang, Dong, Yang, Jintao, and Yang, Guoli

Abstract

Coordinating the immune response and bioenergy metabolism in bone defect environments is essential for promoting bone regeneration. Mitochondria are important organelles that control internal balance and metabolism. Repairing dysfunctional mitochondria has been proposed as a therapeutic approach for disease intervention. Here, an engineered hierarchical hydrogel with immune responsiveness can adapt to the bone regeneration environment and mediate the targeted mitochondria transfer between cells. The continuous supply of mitochondria by macrophages can restore the mitochondrial bioenergy of bone marrow mesenchymal stem cells (BMSC). Fundamentally solving the problem of insufficient energy support of BMSCs caused by local inflammation during bone repair and regeneration. This discovery provides a new therapeutic strategy for promoting bone regeneration and repair, which has research value and practical application prospects in the treatment of various diseases caused by mitochondrial dysfunction. [ABSTRACT FROM AUTHOR]

Published

2024

4. The role of mitochondrial transfer in the suppression of CD8+ T cell responses by Mesenchymal stem cells.

Author

Vaillant, Loic, Akhter, Waseem, Nakhle, Jean, Simon, Matthieu, Villalba, Martin, Jorgensen, Christian, Vignais, Marie-Luce, and Hernandez, Javier

Subjects

*GRAFT versus host disease, *MESENCHYMAL stem cells, *GRAFT rejection, *STROMAL cells, *TRANSGENIC mice, *T cells, *CYTOTOXIC T cells

Abstract

Background:. CD8+ Cytotoxic T lymphocytes play a key role in the pathogenesis of autoimmune diseases and clinical conditions such as graft versus host disease and graft rejection. Mesenchymal Stromal Cells (MSCs) are multipotent cells with tissue repair and immunomodulatory capabilities. Since they are able to suppress multiple pathogenic immune responses, MSCs have been proposed as a cellular therapy for the treatment of immune-mediated diseases. However, the mechanisms underlying their immunosuppressive properties are not yet fully understood. MSCs have the remarkable ability to sense tissue injury and inflammation and respond by donating their own mitochondria to neighboring cells. Whether mitochondrial transfer has any role in the repression of CD8+ responses is unknown. Methods and results:. We have utilized CD8+ T cells from Clone 4 TCR transgenic mice that differentiate into effector cells upon activation in vitro and in vivo to address this question. Allogeneic bone marrow derived MSCs, co-cultured with activated Clone 4 CD8+ T cells, decreased their expansion, the production of the effector cytokine IFNγ and their diabetogenic potential in vivo. Notably, we found that during this interaction leading to suppression, MSCs transferred mitochondria to CD8+ T cells as evidenced by FACS and confocal microscopy. Transfer of MSC mitochondria to Clone 4 CD8+ T cells also resulted in decreased expansion and production of IFNγ upon activation. These effects overlapped and were additive with those of prostaglandin E2 secreted by MSCs. Furthermore, preventing mitochondrial transfer in co-cultures diminished the ability of MSCs to inhibit IFNγ production. Finally, we demonstrated that both MSCs and MSC mitochondria downregulated T-bet and Eomes expression, key transcription factors for CTL differentiation, on activated CD8+ T cells. Conclusion:. In this report we showed that MSCs are able to interact with CD8+ T cells and transfer them their mitochondria. Mitochondrial transfer contributed to the global suppressive effect of MSCs on CD8+ T cell activation by downregulating T-bet and Eomes expression resulting in impaired IFNγ production of activated CD8+ T cells. [ABSTRACT FROM AUTHOR]

Published

2024

5. Augmented Mitochondrial Transfer Involved in Astrocytic PSPH Attenuates Cognitive Dysfunction in db/db Mice.

Author

Ma, Hongli, He, Shuxuan, Li, Yansong, Zhang, Xin, Chang, Haiqing, Du, Mengyu, Yan, Chaoying, Jiang, Shiqiu, Gao, Hui, Zhao, Jing, and Wang, Qiang

Abstract

Diabetes-associated cognitive dysfunction (DACD) has ascended to become the second leading cause of mortality among diabetic patients. Phosphoserine phosphatase (PSPH), a pivotal rate-limiting enzyme in L-serine biosynthesis, has been documented to instigate the insulin signaling pathway through dephosphorylation. Concomitantly, CD38, acting as a mediator in mitochondrial transfer, is activated by the insulin pathway. Given that we have demonstrated the beneficial effects of exogenous mitochondrial supplementation on DACD, we further hypothesized whether astrocytic PSPH could contribute to improving DACD by promoting astrocytic mitochondrial transfer into neurons. In the Morris Water Maze (MWM) test, our results demonstrated that overexpression of PSPH in astrocytes alleviated DACD in db/db mice. Astrocyte specific-stimulated by PSPH lentivirus/ adenovirus promoted the spine density both in vivo and in vitro. Mechanistically, astrocytic PSPH amplified the expression of CD38 via initiation of the insulin signaling pathway, thereby promoting astrocytic mitochondria transfer into neurons. In summation, this comprehensive study delineated the pivotal role of astrocytic PSPH in alleviating DACD and expounded upon its intricate cellular mechanism involving mitochondrial transfer. These findings propose that the specific up-regulation of astrocytic PSPH holds promise as a discerning therapeutic modality for DACD. [ABSTRACT FROM AUTHOR]

Published

2024

6. Aerobic exercise improves astrocyte mitochondrial quality and transfer to neurons in a mouse model of Alzheimer's disease.

Author

Cai, Jiachen, Chen, Yan, She, Yuzhu, He, Xiaoxin, Feng, Hu, Sun, Huaiqing, Yin, Mengmei, Gao, Junying, Sheng, Chengyu, Li, Qian, and Xiao, Ming

Subjects

*EXERCISE physiology, *ALZHEIMER'S disease, *AEROBIC exercises, *REACTIVE oxygen species, *CD38 antigen

Abstract

Mitochondrial dysfunction is a well‐established hallmark of Alzheimer's disease (AD). Despite recent documentation of transcellular mitochondrial transfer, its role in the pathogenesis of AD remains unclear. In this study, we report an impairment of mitochondrial quality within the astrocytes and neurons of adult 5 × FAD mice. Following treatment with mitochondria isolated from aged astrocytes induced by exposure to amyloid protein or extended cultivation, cultured neurons exhibited an excessive generation of reactive oxygen species and underwent neurite atrophy. Notably, aerobic exercise enhanced mitochondrial quality by upregulating CD38 within hippocampal astrocytes of 5 × FAD mice. Conversely, the knockdown of CD38 diminished astrocytic–neuronal mitochondrial transfer, thereby abolishing the ameliorative effects of aerobic exercise on neuronal oxidative stress, β‐amyloid plaque deposition, and cognitive dysfunction in 5 × FAD mice. These findings unveil an unexpected mechanism through which aerobic exercise facilitates the transference of healthy mitochondria from astrocytes to neurons, thus countering the AD‐like progression. [ABSTRACT FROM AUTHOR]

Published

2024

7. Chimeric Cell Therapy Transfers Healthy Donor Mitochondria in Duchenne Muscular Dystrophy.

Author

Siemionow, Maria, Bocian, Katarzyna, Bozyk, Katarzyna T, Ziemiecka, Anna, and Siemionow, Krzysztof

Subjects

*MITOCHONDRIAL dynamics, *DUCHENNE muscular dystrophy, *DYSTROPHIN genes, *MUSCLE weakness, *EARLY death

Abstract

Duchenne muscular dystrophy (DMD) is a severe X-linked disorder characterized by dystrophin gene mutations and mitochondrial dysfunction, leading to progressive muscle weakness and premature death of DMD patients. We developed human Dystrophin Expressing Chimeric (DEC) cells, created by the fusion of myoblasts from normal donors and DMD patients, as a foundation for DT-DEC01 therapy for DMD. Our preclinical studies on mdx mouse models of DMD revealed enhanced dystrophin expression and functional improvements in cardiac, respiratory, and skeletal muscles after systemic intraosseous DEC administration. The current study explored the feasibility of mitochondrial transfer and fusion within the created DEC cells, which is crucial for developing new therapeutic strategies for DMD. Following mitochondrial staining with MitoTracker Deep Red and MitoTracker Green dyes, mitochondrial fusion and transfer was assessed by Flow cytometry (FACS) and confocal microscopy. The PEG-mediated fusion of myoblasts from normal healthy donors (MBN/MBN) and normal and DMD-affected donors (MBN/MBDMD), confirmed the feasibility of myoblast and mitochondrial fusion and transfer. The colocalization of the mitochondrial dyes MitoTracker Deep Red and MitoTracker Green confirmed the mitochondrial chimeric state and the creation of chimeric mitochondria, as well as the transfer of healthy donor mitochondria within the created DEC cells. These findings are unique and significant, introducing the potential of DT-DEC01 therapy to restore mitochondrial function in DMD patients and in other diseases where mitochondrial dysfunction plays a critical role. [ABSTRACT FROM AUTHOR]

Published

2024

8. The movement of mitochondria in breast cancer: internal motility and intercellular transfer of mitochondria.

Author

Libring, Sarah, Berestesky, Emily D., and Reinhart-King, Cynthia A.

Abstract

As a major energy source for cells, mitochondria are involved in cell growth and proliferation, as well as migration, cell fate decisions, and many other aspects of cellular function. Once thought to be irreparably defective, mitochondrial function in cancer cells has found renewed interest, from suggested potential clinical biomarkers to mitochondria-targeting therapies. Here, we will focus on the effect of mitochondria movement on breast cancer progression. Mitochondria move both within the cell, such as to localize to areas of high energetic need, and between cells, where cells within the stroma have been shown to donate their mitochondria to breast cancer cells via multiple methods including tunneling nanotubes. The donation of mitochondria has been seen to increase the aggressiveness and chemoresistance of breast cancer cells, which has increased recent efforts to uncover the mechanisms of mitochondrial transfer. As metabolism and energetics are gaining attention as clinical targets, a better understanding of mitochondrial function and implications in cancer are required for developing effective, targeted therapeutics for cancer patients. [ABSTRACT FROM AUTHOR]

Published

2024

9. Mechanisms of Chimeric Cell Therapy in Duchenne Muscular Dystrophy.

Author

Siemionow, Maria, Ziemiecka, Anna, Bożyk, Katarzyna, and Siemionow, Krzysztof

Subjects

X-linked genetic disorders, DUCHENNE muscular dystrophy, DYSTROPHIN genes, MUSCLE weakness, MYOCARDIUM

Abstract

Despite scientific efforts, there is no cure for Duchenne muscular dystrophy (DMD), a lethal, progressive, X-linked genetic disorder caused by mutations in the dystrophin gene. DMD leads to cardiac and skeletal muscle weakness, resulting in premature death due to cardio-pulmonary complications. We have developed Dystrophin Expressing Chimeric (DEC) cell therapy, DT-DEC01, by fusing human myoblasts from healthy donors and from DMD patients. Preclinical studies on human DEC cells showed increased dystrophin expression and improved cardiac, pulmonary, and skeletal muscle function after intraosseous administration. Our clinical study confirmed the safety and efficacy of DT-DEC01 therapy up to 24 months post-administration. In this study, we conducted in vitro assays to test the composition and potency of DT-DEC01, assessing chimerism level and the presence of dystrophin, desmin, and myosin heavy chain. Myoblast fusion resulted in the transfer of healthy donor mitochondria and the creation of chimeric mitochondria within DT-DEC01. The Pappenheim assay confirmed myotube formation in the final product. This study highlights the unique properties of DT-DEC01 therapy and their relevance to DMD treatment mechanisms. [ABSTRACT FROM AUTHOR]

Published

2024

10. The role of mitochondrial transfer in the suppression of CD8+ T cell responses by Mesenchymal stem cells

Author

Loic Vaillant, Waseem Akhter, Jean Nakhle, Matthieu Simon, Martin Villalba, Christian Jorgensen, Marie-Luce Vignais, and Javier Hernandez

Subjects

Mesenchymal stem/stromal cells, CD8+ T cells, Mitochondrial transfer, Immunotherapy, Autoimmunity, Medicine (General), R5-920, Biochemistry, QD415-436

Abstract

Abstract Background . CD8+ Cytotoxic T lymphocytes play a key role in the pathogenesis of autoimmune diseases and clinical conditions such as graft versus host disease and graft rejection. Mesenchymal Stromal Cells (MSCs) are multipotent cells with tissue repair and immunomodulatory capabilities. Since they are able to suppress multiple pathogenic immune responses, MSCs have been proposed as a cellular therapy for the treatment of immune-mediated diseases. However, the mechanisms underlying their immunosuppressive properties are not yet fully understood. MSCs have the remarkable ability to sense tissue injury and inflammation and respond by donating their own mitochondria to neighboring cells. Whether mitochondrial transfer has any role in the repression of CD8+ responses is unknown. Methods and results . We have utilized CD8+ T cells from Clone 4 TCR transgenic mice that differentiate into effector cells upon activation in vitro and in vivo to address this question. Allogeneic bone marrow derived MSCs, co-cultured with activated Clone 4 CD8+ T cells, decreased their expansion, the production of the effector cytokine IFNγ and their diabetogenic potential in vivo. Notably, we found that during this interaction leading to suppression, MSCs transferred mitochondria to CD8+ T cells as evidenced by FACS and confocal microscopy. Transfer of MSC mitochondria to Clone 4 CD8+ T cells also resulted in decreased expansion and production of IFNγ upon activation. These effects overlapped and were additive with those of prostaglandin E2 secreted by MSCs. Furthermore, preventing mitochondrial transfer in co-cultures diminished the ability of MSCs to inhibit IFNγ production. Finally, we demonstrated that both MSCs and MSC mitochondria downregulated T-bet and Eomes expression, key transcription factors for CTL differentiation, on activated CD8+ T cells. Conclusion . In this report we showed that MSCs are able to interact with CD8+ T cells and transfer them their mitochondria. Mitochondrial transfer contributed to the global suppressive effect of MSCs on CD8+ T cell activation by downregulating T-bet and Eomes expression resulting in impaired IFNγ production of activated CD8+ T cells.

Published

2024

11. Dental pulp stem cells promote malignant transformation of oral epithelial cells through mitochondrial transfer.

Author

Shen, Peiqi, Ma, Zeyi, Xu, Xiaoqing, Li, Weiyu, and Li, Yaoyin

Abstract

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. [ABSTRACT FROM AUTHOR]

Published

2024

12. EKSPRESI GEN MIRO1 DAN P53 PADA CO-CULTURE WHARTON’S JELLY-MESENCHYMAL STEM CELL DAN JANTUNG TIKUS NEONATUS DIINDUKSI DOXORUBICIN

Author

Zikril Ariliusra

Subjects

mitochondrial transfer, whole organ culture, miro1, tunneling nano tube, tnt, Medicine (General), R5-920

Abstract

Transfer mitokondria interseluler diduga dapat menjadi mekanisme terapi mesenchymal stem cell (MSC) terhadap berbagai penyakit yang diakibatkan oleh gangguan atau kerusakan pada mitokondria, salah satunya kardiomiopati akibat doxorubicin. Tujuan penelitian ini adalah untuk mengetahui peran transfer mitokondria interseluler sebagai mekanisme protektif MSC. Penelitian ex vivo ini menggunakan jantung tikus neonatus yang diberikan doxorubicin dan MSC dengan metode whole organ culture. Pengukuran ekspresi gen Miro1 digunakan sebagai indikator aktivitas transfer mitokondria interseluler dan ekspresi gen p53 sebagai indikator stres sel. Ekspresi gen p53 pada kelompok yang diberikan doxorubicin 20µM selama 30 menit meningkat singnifikan (p

Published

2024

13. Mitochondrial transfer from Adipose stem cells to breast cancer cells drives multi-drug resistance

Author

Vitale Del Vecchio, Ayesha Rehman, Sameer Kumar Panda, Martina Torsiello, Martina Marigliano, Maria Maddalena Nicoletti, Giuseppe Andrea Ferraro, Vincenzo De Falco, Rosamaria Lappano, Eva Lieto, Francesca Pagliuca, Carlo Caputo, Marcella La Noce, Gianpaolo Papaccio, Virginia Tirino, Nirmal Robinson, Vincenzo Desiderio, and Federica Papaccio

Subjects

Mitochondrial transfer, Tunneling nanotubes, Mitoception, Adipose Stem cells, Multi-drug resistance, Breast Cancer, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Background Breast cancer (BC) is a complex disease, showing heterogeneity in the genetic background, molecular subtype, and treatment algorithm. Historically, treatment strategies have been directed towards cancer cells, but these are not the unique components of the tumor bulk, where a key role is played by the tumor microenvironment (TME), whose better understanding could be crucial to obtain better outcomes. Methods We evaluated mitochondrial transfer (MT) by co-culturing Adipose stem cells with different Breast cancer cells (BCCs), through MitoTracker assay, Mitoception, confocal and immunofluorescence analyses. MT inhibitors were used to confirm the MT by Tunneling Nano Tubes (TNTs). MT effect on multi-drug resistance (MDR) was assessed using Doxorubicin assay and ABC transporter evaluation. In addition, ATP production was measured by Oxygen Consumption rates (OCR) and Immunoblot analysis. Results We found that MT occurs via Tunneling Nano Tubes (TNTs) and can be blocked by actin polymerization inhibitors. Furthermore, in hybrid co-cultures between ASCs and patient-derived organoids we found a massive MT. Breast Cancer cells (BCCs) with ASCs derived mitochondria (ADM) showed a reduced HIF-1α expression in hypoxic conditions, with an increased ATP production driving ABC transporters-mediated multi-drug resistance (MDR), linked to oxidative phosphorylation metabolism rewiring. Conclusions We provide a proof-of-concept of the occurrence of Mitochondrial Transfer (MT) from Adipose Stem Cells (ASCs) to BC models. Blocking MT from ASCs to BCCs could be a new effective therapeutic strategy for BC treatment.

Published

2024

14. CB1 Promotes Osteogenic Differentiation Potential of Periodontal Ligament Stem Cells by Enhancing Mitochondrial Transfer of Bone Marrow Mesenchymal Stem Cells.

Author

Lan LUO, Wan Hao YAN, Feng Qiu ZHANG, and Zhi Peng FAN

Subjects

REVERSE transcriptase polymerase chain reaction, CALCIUM ions, PERIODONTAL ligament, MESENCHYMAL stem cells, CANNABINOID receptors

Abstract

Objective: To reveal the role and mechanism of cannabinoid receptor 1 (CB1) and mitochondria in promoting osteogenic differentiation of periodontal ligament stem cells (PDLSCs) in the inflammatory microenvironment. Methods: Bidirectional mitochondrial transfer was performed in bone mesenchymal stem cells (BMSCs) and PDLSCs. Laser confocal microscopy and quantitative flow cytometry were used to observe the mitochondrial transfer and quantitative mitochondrial transfer efficiency. Real-time reverse transcription polymerase chain reaction (RT-PCR) was employed to detect gene expression. Alkaline phosphatase (ALP) activity, alizarin red staining (ARS) and quantitative calcium ion analysis were used to evaluate the degree of osteogenic differentiation of PDLSCs. Results: Bidirectional mitochondrial transfer was observed between BMSCs and PDLSCs. The indirect co-culture system could simulate intercellular mitochondrial transfer. Compared with the conditioned medium (CM) for BMSCs, that for HA-CB1 BMSCs could significantly enhance the mineralisation ability of PDLSCs. The mineralisation ability of PDLSCs could not be enhanced after removing the mitochondria in CM for HA-CB1 BMSCs. The expression level of HO-1, PGC-1α, NRF-1, ND1 and HK2 was significantly increased in HA-CB1 BMSCs. Conclusion: CM for HA-CB1 BMSCs could significantly enhance the damaged osteogenic differentiation ability of PDLSCs in the inflammatory microenvironment, and the mitochondria of CM played an important role. CB1 was related to the activation of the HO-1/PGC-1α/NRF-1 mitochondrial biogenesis pathway, and significantly increased the mitochondrial content in BMSCs. [ABSTRACT FROM AUTHOR]

Published

2024

15. Post-acute ischemic stroke hyperglycemia aggravates destruction of the blood-brain barrier.

Author

Tianqi Xu, Jianhong Yang, Yao Xu, Xiaofeng Wang, Xiang Gao, Jie Sun, Chenhui Zhou, and Yi Huang

Published

2024

16. An Engineered Hierarchical Hydrogel with Immune Responsiveness and Targeted Mitochondrial Transfer to Augmented Bone Regeneration

Author

Wenjin Cai, Shihua Mao, Ying Wang, Bicong Gao, Jiaying Zhao, Yongzheng Li, Yani Chen, Dong Zhang, Jintao Yang, and Guoli Yang

Subjects

bioenergy metabolism, bone mesenchymal stem cells, bone regeneration, mitochondrial transfer, Science

Abstract

Abstract Coordinating the immune response and bioenergy metabolism in bone defect environments is essential for promoting bone regeneration. Mitochondria are important organelles that control internal balance and metabolism. Repairing dysfunctional mitochondria has been proposed as a therapeutic approach for disease intervention. Here, an engineered hierarchical hydrogel with immune responsiveness can adapt to the bone regeneration environment and mediate the targeted mitochondria transfer between cells. The continuous supply of mitochondria by macrophages can restore the mitochondrial bioenergy of bone marrow mesenchymal stem cells (BMSC). Fundamentally solving the problem of insufficient energy support of BMSCs caused by local inflammation during bone repair and regeneration. This discovery provides a new therapeutic strategy for promoting bone regeneration and repair, which has research value and practical application prospects in the treatment of various diseases caused by mitochondrial dysfunction.

Published

2024

17. Retinal damage promotes mitochondrial transfer in the visual system of a mouse model of Leber hereditary optic neuropathy

Author

Pascal Ezan, Eléonore Hardy, Alexis Bemelmans, Magali Taiel, Elena Dossi, and Nathalie Rouach

Subjects

Mitochondrial transfer, Leber hereditary optic neuropathy, Retina, Optic nerve, Gene therapy, Viral vector, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Lenadogene nolparvovec is a gene therapy which has been developed to treat Leber hereditary optic neuropathy (LHON) caused by a point mutation in the mitochondrial NADH dehydrogenase 4 (ND4) gene. Clinical trials have demonstrated a significant improvement of visual acuity up to 5 years after treatment by lenadogene nolparvovec but, surprisingly, unilateral treatment resulted in bilateral improvement of vision. This contralateral effect – similarly observed with other gene therapy products in development for MT-ND4-LHON – is supported by the migration of viral vector genomes and their transcripts to the contralateral eye, as reported in animals, and post-mortem samples from two patients. In this study, we used an AAV2 encoding fluorescent proteins targeting mitochondria to investigate whether these organelles themselves could transfer from the treated eye to the fellow one. We found that mitochondria travel along the visual system (optic chiasm and primary visual cortex) and reach the contralateral eye (optic nerve and retina) in physiological conditions. We also observed that, in a rotenone-induced model of retinal damage mimicking LHON, mitochondrial transfer from the healthy to the damaged eye was accelerated and enhanced. Our results thus provide a further explanation for the contralateral beneficial effect observed during clinical studies with lenadogene nolparvovec.

Published

2024

18. Melatonin-loaded bioactive microspheres accelerate aged bone regeneration by formation of tunneling nanotubes to enhance mitochondrial transfer

Author

Huacui Xiong, Huanhuan Qiu, Chunhui Wang, Yonghao Qiu, Shuyi Tan, Ke Chen, Fujian Zhao, and Jinlin Song

Subjects

Mesoporous bioactive glasses, Aged bone regeneration, Mitochondrial function, Mitochondrial transfer, Tunneling nanotubes, Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

The repair of bone defects in the elderly individuals is significantly delayed due to cellular senescence and dysfunction, which presents a challenge in clinical settings. Furthermore, there are limited effective methods available to promote bone repair in older individuals. Herein, melatonin-loaded mesoporous bioactive glasses microspheres (MTBG) were successfully prepared based on their mesoporous properties. The repair of bone defects in aged rats was significantly accelerated by enhancing mitochondrial function through the sustained release of melatonin and bioactive ions. MTBG effectively rejuvenated senescent bone marrow mesenchymal stem cells (BMSCs) by scavenging excessive reactive oxygen species (ROS), stabilizing the mitochondrial membrane potential (ΔΨm), and increasing ATP synthesis. Analysis of the underlying mechanism revealed that the formation of tunneling nanotubes (TNTs) facilitated the intercellular transfer of mitochondria, thereby resulting in the recovery of mitochondrial function. This study provides critical insights into the design of new biomaterials for the elderly individuals and the biological mechanism involved in aged bone regeneration.

Published

2024

19. Mitochondrial transfer in tunneling nanotubes—a new target for cancer therapy

Author

Fan Guan, Xiaomin Wu, Jiatong Zhou, Yuzhe Lin, Yuqing He, Chunmei Fan, Zhaoyang Zeng, and Wei Xiong

Subjects

Mitochondrial transfer, Oxidative phosphorylation, Metabolic symbiosis, Tunneling nanotubes, Immune evasion, Chemotherapy resistance, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract A century ago, the Warburg effect was first proposed, revealing that cancer cells predominantly rely on glycolysis during the process of tumorigenesis, even in the presence of abundant oxygen, shifting the main pathway of energy metabolism from the tricarboxylic acid cycle to aerobic glycolysis. Recent studies have unveiled the dynamic transfer of mitochondria within the tumor microenvironment, not only between tumor cells but also between tumor cells and stromal cells, immune cells, and others. In this review, we explore the pathways and mechanisms of mitochondrial transfer within the tumor microenvironment, as well as how these transfer activities promote tumor aggressiveness, chemotherapy resistance, and immune evasion. Further, we discuss the research progress and potential clinical significance targeting these phenomena. We also highlight the therapeutic potential of targeting intercellular mitochondrial transfer as a future anti-cancer strategy and enhancing cell-mediated immunotherapy. Graphical Abstract Mitochondrial Transfer in the Tumor Microenvironment. This review elaborates in detail on the molecular mechanisms and pathophysiological significance behind the mitochondrial transfer occurring between tumor cells and their microenvironment. This biological phenomenon of mitochondrial transfer is prevalent in a variety of cancers, including both solid tumors and hematologic malignancies, with a high incidence in acute myeloid leukemia (AML), breast cancer, and gliomas. The review also discusses therapeutic approaches targeting mitochondrial transfer, with a special focus on its application in immunotherapy, particularly in CAR-T cell therapy, where it has begun to show unique advantages

Published

2024

20. Focusing on mitochondria in the brain: from biology to therapeutics

Author

Nanshan Song, Shuyuan Mei, Xiangxu Wang, Gang Hu, and Ming Lu

Subjects

Mitochondria, Brain, Neurological disorders, Mitochondrial transfer, Neurology. Diseases of the nervous system, RC346-429

Abstract

Abstract Mitochondria have multiple functions such as supplying energy, regulating the redox status, and producing proteins encoded by an independent genome. They are closely related to the physiology and pathology of many organs and tissues, among which the brain is particularly prominent. The brain demands 20% of the resting metabolic rate and holds highly active mitochondrial activities. Considerable research shows that mitochondria are closely related to brain function, while mitochondrial defects induce or exacerbate pathology in the brain. In this review, we provide comprehensive research advances of mitochondrial biology involved in brain functions, as well as the mitochondria-dependent cellular events in brain physiology and pathology. Furthermore, various perspectives are explored to better identify the mitochondrial roles in neurological diseases and the neurophenotypes of mitochondrial diseases. Finally, mitochondrial therapies are discussed. Mitochondrial-targeting therapeutics are showing great potentials in the treatment of brain diseases.

Published

2024

21. Mitochondrial transplantation: new challenges for cancer

Author

O. I. Kit, E. M. Frantsiyants, A. I. Shikhlyarova, and I. V. Neskubina

Subjects

mitochondria, mitochondrial therapy, mitochondrial transfer, malignant tumors, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

This review discusses the uniqueness of mitochondria providing normal cellular functions and at the same time involved in many pathological conditions, and also analyzes the scientific literature to clarify the effectiveness of mitochondrial transplantation in cancer treatment. Being important and semi-autonomous organelles in cells, they are able to adapt their functions to the needs of the corresponding organ. The ability of mitochondria to reprogram is important for all cell types that can switch between resting and proliferation. At the same time, tumor mitochondria undergo adaptive changes to accelerate the reproduction of tumor cells in an acidic and hypoxic microenvironment. According to emerging data, mitochondria can go beyond the boundaries of cells and move between the cells of the body. Intercellular transfer of mitochondria occurs naturally in humans as a normal mechanism for repairing damaged cells. The revealed physiological mitochondrial transfer has become the basis for a modern form of mitochondrial transplantation, including autologous (isogenic), allogeneic, and even xenogenic transplantation. Currently, exogenous healthy mitochondria are used in treatment of several carcinomas, including breast cancer, pancreatic cancer, and glioma. Investigation of the functional activity of healthy mitochondria demonstrated and confirmed the fact that female mitochondria are more efficient in suppressing tumor cell proliferation than male mitochondria. However, tissue-specific sex differences in mitochondrial morphology and oxidative capacity were described, and few studies showed functional sex differences in mitochondria during therapy. The reviewed studies report that mitochondrial transplantation can be specifically targeted to a tumor, providing evidence for changes in tumor function after mitochondrial administration. Thus, the appearance of the most interesting data on the unique functions of mitochondria indicates the obvious need for mitochondrial transplantation.

Published

2024

22. Mitochondrial transfer in tunneling nanotubes—a new target for cancer therapy.

Author

Guan, Fan, Wu, Xiaomin, Zhou, Jiatong, Lin, Yuzhe, He, Yuqing, Fan, Chunmei, Zeng, Zhaoyang, and Xiong, Wei

Subjects

*KREBS cycle, *CANCER treatment, *WARBURG Effect (Oncology), *MITOCHONDRIA, *NANOTUBES

Abstract

A century ago, the Warburg effect was first proposed, revealing that cancer cells predominantly rely on glycolysis during the process of tumorigenesis, even in the presence of abundant oxygen, shifting the main pathway of energy metabolism from the tricarboxylic acid cycle to aerobic glycolysis. Recent studies have unveiled the dynamic transfer of mitochondria within the tumor microenvironment, not only between tumor cells but also between tumor cells and stromal cells, immune cells, and others. In this review, we explore the pathways and mechanisms of mitochondrial transfer within the tumor microenvironment, as well as how these transfer activities promote tumor aggressiveness, chemotherapy resistance, and immune evasion. Further, we discuss the research progress and potential clinical significance targeting these phenomena. We also highlight the therapeutic potential of targeting intercellular mitochondrial transfer as a future anti-cancer strategy and enhancing cell-mediated immunotherapy. [ABSTRACT FROM AUTHOR]

Published

2024

23. Focusing on mitochondria in the brain: from biology to therapeutics.

Author

Song, Nanshan, Mei, Shuyuan, Wang, Xiangxu, Hu, Gang, and Lu, Ming

Subjects

*MITOCHONDRIA, *BIOLOGY, *BRAIN physiology, *MOLECULAR pathology, *BRAIN diseases, *NEUROLOGICAL disorders

Abstract

Mitochondria have multiple functions such as supplying energy, regulating the redox status, and producing proteins encoded by an independent genome. They are closely related to the physiology and pathology of many organs and tissues, among which the brain is particularly prominent. The brain demands 20% of the resting metabolic rate and holds highly active mitochondrial activities. Considerable research shows that mitochondria are closely related to brain function, while mitochondrial defects induce or exacerbate pathology in the brain. In this review, we provide comprehensive research advances of mitochondrial biology involved in brain functions, as well as the mitochondria-dependent cellular events in brain physiology and pathology. Furthermore, various perspectives are explored to better identify the mitochondrial roles in neurological diseases and the neurophenotypes of mitochondrial diseases. Finally, mitochondrial therapies are discussed. Mitochondrial-targeting therapeutics are showing great potentials in the treatment of brain diseases. [ABSTRACT FROM AUTHOR]

Published

2024

24. Mitochondria in Mesenchymal Stem Cells: Key to Fate Determination and Therapeutic Potential.

Author

Liu, Yang, Wang, Lingjuan, Ai, Jihui, and Li, Kezhen

Subjects

*MESENCHYMAL stem cells, *CELL determination, *CELL transformation, *CELLULAR control mechanisms, *CELL physiology, *ENERGY metabolism, *REGENERATIVE medicine

Abstract

Mesenchymal stem cells (MSCs) have become popular tool cells in the field of transformation and regenerative medicine due to their function of cell rescue and cell replacement. The dynamically changing mitochondria serve as an energy metabolism factory and signal transduction platform, adapting to different cell states and maintaining normal cell activities. Therefore, a clear understanding of the regulatory mechanism of mitochondria in MSCs is profit for more efficient clinical transformation of stem cells. This review highlights the cutting-edge knowledge regarding mitochondrial biology from the following aspects: mitochondrial morphological dynamics, energy metabolism and signal transduction. The manuscript mainly focuses on mitochondrial mechanistic insights in the whole life course of MSCs, as well as the potential roles played by mitochondria in MSCs treatment of transplantation, for seeking pivotal targets of stem cell fate regulation and stem cell therapy. [ABSTRACT FROM AUTHOR]

Published

2024

25. Therapeutic effect of mitochondrial transplantation on burn injury.

Author

Li, Zhen, Cao, Xinhui, Liu, Zuohao, Wu, Fen, Lin, Changjun, and Wang, Chun-Ming

Subjects

*CELL migration, *SKIN regeneration, *TREATMENT effectiveness, *MITOCHONDRIA, *CELL cycle, *COLLOIDAL gold, *ENZYME-linked immunosorbent assay

Abstract

As mitochondrial damage or dysfunction is commonly observed following burn injuries, we investigated whether mitochondrial transplantation (MT) can result in therapeutic benefits in the treatment of burns. Human immortalized epidermal cells (HaCaT) and Kunming mice were used to establish a heat-injured cell model and a deep partial-thickness skin burn animal model, respectively. The cell model was established by exposing HaCaT cells to 45 or 50 °C for 10 min, after which cell proliferation was assayed using fluorescent double-staining and colony formation assays, cell migration was assessed using colloidal gold migration and scratch assays, and cell cycle progression and apoptosis were measured by flow cytometry. Histopathological staining, immunohistochemistry, nick-end labeling analysis, and enzyme-linked immunosorbent assays were used to evaluate the effects of MT on inflammation, tissue recovery, apoptosis, and scar growth in a mouse model. The therapeutic effects were observed in the heat-injured HaCaT cell model. MT promoted cell viability, colony formation, proliferation, and migration; decreased G1 phase; promoted cell division; and decreased apoptosis. Wound-healing promotion, anti-inflammation (decreased mast cell aggregation, down-regulated of TNF-α, IL-1β, IL-6, and up-regulated IL-10), acceleration of proliferation recovery (up-regulated CD34 and VEGF), apoptosis reduction, and scar formation reduction (decreased collagen I/III ratio and TGF-β1) were observed in the MT mouse model. The MT mode of action was, however, not investigated in this study. In conclusion, our data indicate that MT exerts a therapeutic effect on burn injuries both in vitro and in vivo. [Display omitted] • Mitochondrial transplantation promotes burn wound healing. • Mitochondrial transplantation alleviates the inflammatory response of skin burns. • Mitochondrial transplantation promotes cell migration, reduces burn-induced cell apoptosis. • Mitochondrial transplantation alleviates burn scar formation. [ABSTRACT FROM AUTHOR]

Published

2024

26. Extracellular vesicles meet mitochondria: Potential roles in regenerative medicine

Author

Shujie Wu, Tao Yang, Meirui Ma, Le Fan, Lin Ren, Gen Liu, Yiqiao Wang, Bin Cheng, Juan Xia, and Zhichao Hao

Subjects

Extracellular vesicles, Mitochondria, Mitochondrial transfer, Regenerative medicine, Therapeutics. Pharmacology, RM1-950

Abstract

Extracellular vesicles (EVs), secreted by most cells, act as natural cell-derived carriers for delivering proteins, nucleic acids, and organelles between cells. Mitochondria are highly dynamic organelles responsible for energy production and cellular physiological processes. Recent evidence has highlighted the pivotal role of EVs in intercellular mitochondrial content transfer, including mitochondrial DNA (mtDNA), proteins, and intact mitochondria. Intriguingly, mitochondria are crucial mediators of EVs release, suggesting an interplay between EVs and mitochondria and their potential implications in physiology and pathology. However, in this expanding field, much remains unknown regarding the function and mechanism of crosstalk between EVs and mitochondria and the transport of mitochondrial EVs. Herein, we shed light on the physiological and pathological functions of EVs and mitochondria, potential mechanisms underlying their interactions, delivery of mitochondria-rich EVs, and their clinical applications in regenerative medicine.

Published

2024

27. Mechanisms of Chimeric Cell Therapy in Duchenne Muscular Dystrophy

Author

Maria Siemionow, Anna Ziemiecka, Katarzyna Bożyk, and Krzysztof Siemionow

Subjects

Dystrophin Expressing Chimeric (DEC) cells, mitochondrial transfer, chimeric mitochondria, DMD therapy, DEC mechanisms, Duchenne muscular dystrophy (DMD), Biology (General), QH301-705.5

Abstract

Despite scientific efforts, there is no cure for Duchenne muscular dystrophy (DMD), a lethal, progressive, X-linked genetic disorder caused by mutations in the dystrophin gene. DMD leads to cardiac and skeletal muscle weakness, resulting in premature death due to cardio-pulmonary complications. We have developed Dystrophin Expressing Chimeric (DEC) cell therapy, DT-DEC01, by fusing human myoblasts from healthy donors and from DMD patients. Preclinical studies on human DEC cells showed increased dystrophin expression and improved cardiac, pulmonary, and skeletal muscle function after intraosseous administration. Our clinical study confirmed the safety and efficacy of DT-DEC01 therapy up to 24 months post-administration. In this study, we conducted in vitro assays to test the composition and potency of DT-DEC01, assessing chimerism level and the presence of dystrophin, desmin, and myosin heavy chain. Myoblast fusion resulted in the transfer of healthy donor mitochondria and the creation of chimeric mitochondria within DT-DEC01. The Pappenheim assay confirmed myotube formation in the final product. This study highlights the unique properties of DT-DEC01 therapy and their relevance to DMD treatment mechanisms.

Published

2024

28. Prospects of mitochondrial transplantation in clinical medicine: Aspirations and challenges

Author

Hosseinian, Sina, Ali Pour, Paria, and Kheradvar, Arash

Subjects

Biochemistry and Cell Biology, Biological Sciences, Transplantation, Clinical Medicine, Mitochondria, Mitochondrial transplantation, Mitochondrial transfer, Clinical medicine, Mitochondrial transplantation in medicine, Genetics, Biochemistry & Molecular Biology, Biochemistry and cell biology

Abstract

Mitochondria, known as the powerhouse of the cell, are at the center of healthy physiology and provide cells with energy in the form of ATP. These unique organelles are also implicated in many pathological conditions affecting a variety of organs in various systems. Recently, mitochondrial transplantation, inspired by mitochondria's endosymbiotic origin, has been attempted as a potential biotherapy in mitigating a variety of pathological conditions. Mitochondrial transplantation consists of the process of isolation, transfer, and uptake of exogenous, intact mitochondria into damaged cells. Here, we discuss mitochondrial transplantation in the context of clinical medicine practiced in neurology, cardiology, pulmonary medicine, and oncology, among others. We outline the role of mitochondria in various pathologies and discuss the state-of-the-art research that potentially form the basis of new therapeutics for the treatment of a variety of diseases due to mitochondrial dysfunction. Lastly, we explore some of the challenges associated with mitochondrial transplantation that must be addressed before mitochondrial transplantation becomes a viable therapeutic option in clinical settings.

Published

2022

29. Defining Endogenous Mitochondrial Transfer in Muscle After Rotator Cuff Injury.

Author

Chi, Hannah M., Davies, Michael R., Garcia, Steven M., Montenegro, Cristhian, Sharma, Sankalp, Lizarraga, Miguel, Wang, Zili, Nuthalapati, Prashant, Kim, Hubert T., Liu, Xuhui, and Feeley, Brian T.

Subjects

*SKELETAL muscle injuries, *ROTATOR cuff injuries, *WOUND healing, *BIOLOGICAL models, *IN vitro studies, *FLOW cytometry, *SEQUENCE analysis, *FIBROBLASTS, *ANIMAL experimentation, *MITOCHONDRIA, *CELL communication, *RATS, *COMPARATIVE studies, *T-test (Statistics), *DYES & dyeing, *STEM cells, *DESCRIPTIVE statistics, *DATA analysis software, *ROTATOR cuff, *ADIPOSE tissues, *PHENOTYPES

Abstract

Background: Rotator cuff muscle degeneration leads to poor clinical outcomes for patients with rotator cuff tears. Fibroadipogenic progenitors (FAPs) are resident muscle stem cells with the ability to differentiate into fibroblasts as well as white and beige adipose tissue. Induction of the beige adipose phenotype in FAPs has been shown to improve muscle quality after rotator cuff tears, but the mechanisms of how FAPs exert their beneficial effects have not been fully elucidated. Purpose: To study the horizontal transfer of mitochondria from FAPs to myogenic cells and examine the effects of β-agonism on this novel process. Study Design: Controlled laboratory study. Methods: In mice that had undergone a massive rotator cuff tear, single-cell RNA sequencing was performed on isolated FAPs for genes associated with mitochondrial biogenesis and transfer. Murine FAPs were isolated by fluorescence-activated cell sorting and treated with a β-agonist versus control. FAPs were stained with mitochondrial dyes and cocultured with recipient C2C12 myoblasts, and the rate of transfer was measured after 24 hours by flow cytometry. PdgfraCreERT/MitoTag mice were generated to study the effects of a rotator cuff injury on mitochondrial transfer. PdgfraCreERT/tdTomato mice were likewise generated to perform lineage tracing of PDGFRA+ cells in this injury model. Both populations of transgenic mice underwent tendon transection and denervation surgery, and MitoTag-labeled mitochondria from Pdgfra+ FAPs were visualized by fluorescent microscopy, spinning disk confocal microscopy, and 2-photon microscopy; overall mitochondrial quantity was compared between mice treated with β-agonists and dimethyl sulfoxide. Results: Single-cell RNA sequencing in mice that underwent rotator cuff tear demonstrated an association between transcriptional markers of adipogenic differentiation and genes associated with mitochondrial biogenesis. In vitro cocultures of murine FAPs with C2C12 cells revealed that treatment of cells with a β-agonist increased mitochondrial transfer compared to control conditions (17.8% ± 9.9% to 99.6% ± 0.13% P <.0001). Rotator cuff injury in PdgfraCreERT/MitoTag mice resulted in a robust increase in MitoTag signal in adjacent myofibers compared with uninjured mice. No accumulation of tdTomato signal from PDGFRA+ cells was seen in injured fibers at 6 weeks after injury, suggesting that FAPs do not fuse with injured muscle fibers but rather contribute their mitochondria. Conclusion: The authors have described a novel process of endogenous mitochondrial transfer that can occur within the injured rotator cuff between FAPs and myogenic cells. This process may be leveraged therapeutically with β-agonist treatment and represents an exciting target for improving translational therapies available for rotator cuff muscle degeneration. Clinical Relevance: Promoting endogenous mitochondrial transfer may represent a novel translational strategy to address muscle degeneration after rotator cuff tears. [ABSTRACT FROM AUTHOR]

Published

2024

30. Mitochondrial transfer - a novel promising approach for the treatment of metabolic diseases.

Author

Ruijing Chen and Jun Chen

Abstract

Metabolic disorders remain a major global health concern in the 21st century, with increasing incidence and prevalence. Mitochondria play a critical role in cellular energy production, calcium homeostasis, signal transduction, and apoptosis. Under physiological conditions, mitochondrial transfer plays a crucial role in tissue homeostasis and development. Mitochondrial dysfunction has been implicated in the pathogenesis of metabolic disorders. Numerous studies have demonstrated that mitochondria can be transferred from stem cells to pathologically injured cells, leading to mitochondrial functional restoration. Compared to cell therapy, mitochondrial transplantation has lower immunogenicity, making exogenous transplantation of healthy mitochondria a promising therapeutic approach for treating diseases, particularly metabolic disorders. This review summarizes the association between metabolic disorders and mitochondria, the mechanisms of mitochondrial transfer, and the therapeutic potential of mitochondrial transfer for metabolic disorders. We hope this review provides novel insights into targeted mitochondrial therapy for metabolic disorders. [ABSTRACT FROM AUTHOR]

Published

2024

31. Mesenchymal stromal cells, metabolism, and mitochondrial transfer in bone marrow normal and malignant hematopoiesis.

Author

Singh, Abhishek K., Prasad, Parash, and Cancelas, Jose A.

Published

2023

32. MELAS-Derived Neurons Functionally Improve by Mitochondrial Transfer from Highly Purified Mesenchymal Stem Cells (REC).

Author

Liu, Lu, Yang, Jiahao, Otani, Yoshinori, Shiga, Takahiro, Yamaguchi, Akihiro, Oda, Yasuaki, Hattori, Miho, Goto, Tsukimi, Ishibashi, Shuichi, Kawashima-Sonoyama, Yuki, Ishihara, Takaya, Matsuzaki, Yumi, Akamatsu, Wado, Fujitani, Masashi, and Taketani, Takeshi

Subjects

*MESENCHYMAL stem cells, *INDUCED pluripotent stem cells, *MITOCHONDRIAL DNA, *MITOCHONDRIA, *NEURONS, *PLANT mitochondria, *INTRACELLULAR calcium

Abstract

Mitochondrial encephalomyopathy, lactic acidosis, and stroke-like episode (MELAS) syndrome, caused by a single base substitution in mitochondrial DNA (m.3243A>G), is one of the most common maternally inherited mitochondrial diseases accompanied by neuronal damage due to defects in the oxidative phosphorylation system. There is no established treatment. Our previous study reported a superior restoration of mitochondrial function and bioenergetics in mitochondria-deficient cells using highly purified mesenchymal stem cells (RECs). However, whether such exogenous mitochondrial donation occurs in mitochondrial disease models and whether it plays a role in the recovery of pathological neuronal functions is unknown. Here, utilizing induced pluripotent stem cells (iPSC), we differentiated neurons with impaired mitochondrial function from patients with MELAS. MELAS neurons and RECs/mesenchymal stem cells (MSCs) were cultured under contact or non-contact conditions. Both RECs and MSCs can donate mitochondria to MELAS neurons, but RECs are more excellent than MSCs for mitochondrial transfer in both systems. In addition, REC-mediated mitochondrial transfer significantly restored mitochondrial function, including mitochondrial membrane potential, ATP/ROS production, intracellular calcium storage, and oxygen consumption rate. Moreover, mitochondrial function was maintained for at least three weeks. Thus, REC-donated exogenous mitochondria might offer a potential therapeutic strategy for treating neurological dysfunction in MELAS. [ABSTRACT FROM AUTHOR]

Published

2023

33. Progress in role of intercellular mitochondrial transfer in diabetes and its complications.

Author

WANG Haiyan, SONG Wenting, ZHAO Meng, WANG Dong, WANG Xiaolei, and LI Qiu

Subjects

*DIABETES complications, *CELL fusion, *MITOCHONDRIA, *EXTRACELLULAR vesicles, *BIOENERGETICS

Abstract

Diabetes mellitus is a metabolic disorder characterized by hyperglycemia and has become a common chronic disease worldwide. Mitochondria play key roles in energy production, signal transduction and apoptosis. Mitochondrial dysfunction is an important factor that promotes the development of diabetes and its complications. Maintaining mitochondrial function is expected to have a therapeutic effect on diabetes and its complications. Mitochondria can be transferred between cells, replacing dysfunctional mitochondria with exogenous healthy mitochondria and thereby reversing cell damage. Mitochondrial transfer through actin-based tunnel nanotubes, extracellular vesicles, connexins, cell fusion and extrusion has been shown to restore the bioenergetics of damaged mammalian cells. In addition, mitochondrial trans-plantation, which is an innovative strategy to treat mitochondrial diseases by increasing and replacing mitochondria, has attracted increasing attention. This article focuses on improving mitochondrial function in damaged cells as an entry point for the treatment of diabetes and its complications, focusing on the role of mitochondrial transfer among cells in diabetes and its complications. [ABSTRACT FROM AUTHOR]

Published

2023

34. Research Progress of Mitochondrial Transfer in Post-stroke Cognitive Impairment

Author

XIAO Yuqian, BAI Yanjie, WANG Yan, CHEN Shuying, CHEN Limin, SUN Kexin, WAN Jun

Subjects

stroke, cognition disorders, mitochondrial transfer, tunneling nanotubes, extracellular vesicles, gap junction, review, Medicine

Abstract

Stroke often leads to persistent post-stroke cognitive impairment (PSCI), which mainly manifests as impairment in learning and memory. The pathogenesis remains unclear as present, but it is closely related to mitochondrial dysfunction, and healthy mitochondria are essential for neuronal survival. Recent studies have shown that intercellular mitochondrial transfer can be linked to stroke through increasing neuronal viability, enhancing mitochondrial metabolism, and modulating neuroinflammation, thereby improving cognitive impairment. This review overviews the mechanisms of mitochondrial transfer and the key role of intercellular mitochondrial transfer in PSCI, and discusses that mitochondrial transplantation may serve as a novel therapeutic intervention for PSCI, providing references for its clinical management.

Published

2023

35. Mitochondrial transfer in hematological malignancies

Author

Xiaodong Guo, Can Can, Wancheng Liu, Yihong Wei, Xinyu Yang, Jinting Liu, Hexiao Jia, Wenbo Jia, Hanyang Wu, and Daoxin Ma

Subjects

Mitochondrial transfer, Tunneling nanotubes, Extracellular vesicles, Extracellular mitochondria, Hematological malignancies, Therapeutics. Pharmacology, RM1-950

Abstract

Abstract Mitochondria are energy-generated organelles and take an important part in biological metabolism. Mitochondria could be transferred between cells, which serves as a new intercellular communication. Mitochondrial transfer improves mitochondrial defects, restores the biological functions of recipient cells, and maintains the high metabolic requirements of tumor cells as well as drug resistance. In recent years, it has been reported mitochondrial transfer between cells of bone marrow microenvironment and hematological malignant cells play a critical role in the disease progression and resistance during chemotherapy. In this review, we discuss the patterns and mechanisms on mitochondrial transfer and their engagement in different pathophysiological contexts and outline the latest knowledge on intercellular transport of mitochondria in hematological malignancies. Besides, we briefly outline the drug resistance mechanisms caused by mitochondrial transfer in cells during chemotherapy. Our review demonstrates a theoretical basis for mitochondrial transfer as a prospective therapeutic target to increase the treatment efficiency in hematological malignancies and improve the prognosis of patients.

Published

2023

36. Mitochondrial transplantation in cardiomyocytes: foundation, methods, and outcomes

Author

Ali Pour, Paria, Hosseinian, Sina, and Kheradvar, Arash

Subjects

Transplantation, Cardiovascular, Generic health relevance, Animals, Cardiomyopathies, Cell Fractionation, Diabetes Mellitus, Experimental, Disease Models, Animal, Humans, Injections, Intralesional, Mitochondria, Heart, Mitochondrial Dynamics, Myocardial Infarction, Myocardial Reperfusion Injury, Myocytes, Cardiac, Oxidative Phosphorylation, Rabbits, Rats, Reactive Oxygen Species, Swine, ischemia reperfusion injury, mitochondrial diseases, mitochondrial transplantation, mitochondrial transfer, mitochondrial cardiomyopathy, Biochemistry and Cell Biology, Physiology, Medical Physiology

Abstract

Mitochondrial transplantation is emerging as a novel cellular biotherapy to alleviate mitochondrial damage and dysfunction. Mitochondria play a crucial role in establishing cellular homeostasis and providing cell with the energy necessary to accomplish its function. Owing to its endosymbiotic origin, mitochondria share many features with their bacterial ancestors. Unlike the nuclear DNA, which is packaged into nucleosomes and protected from adverse environmental effects, mitochondrial DNA are more prone to harsh environmental effects, in particular that of the reactive oxygen species. Mitochondrial damage and dysfunction are implicated in many diseases ranging from metabolic diseases to cardiovascular and neurodegenerative diseases, among others. While it was once thought that transplantation of mitochondria would not be possible due to their semiautonomous nature and reliance on the nucleus, recent advances have shown that it is possible to transplant viable functional intact mitochondria from autologous, allogenic, and xenogeneic sources into different cell types. Moreover, current research suggests that the transplantation could positively modulate bioenergetics and improve disease outcome. Mitochondrial transplantation techniques and consequences of transplantation in cardiomyocytes are the theme of this review. We outline the different mitochondrial isolation and transfer techniques. Finally, we detail the consequences of mitochondrial transplantation in the cardiovascular system, more specifically in the context of cardiomyopathies and ischemia.

Published

2021

37. A novel computational tool for tracking cancer energy hijacking from immune cells

Author

Hongyi Zhang and Bo Li

Subjects

Deconvolution, Mitochondrial Transfer, single‐cell genomics, Tumor‐immune Interaction, Medicine (General), R5-920

Abstract

Abstract Recent studies revealed a new biological process that malignant cancer cells hijack mitochondria from nearby T cells, providing another potential mechanism for immune evasion. We further confirmed this process at the single‐cell genomic level through MERCI, a novel algorithm for tracking mitochondrial (MT) transfer. Applied to human cancer samples, MERCI identified a new cancer phenotype linked to MT hijacking, correlating with rapid tumour proliferation and poor patient survival. This discovery offers insights into the limitations of current cancer immunotherapies and suggests new therapeutic avenues targeting MT transfer to enhance cancer treatment efficacy.

Published

2024

38. Mitochondrial transfer from Adipose stem cells to breast cancer cells drives multi-drug resistance

Author

Del Vecchio, Vitale, Rehman, Ayesha, Panda, Sameer Kumar, Torsiello, Martina, Marigliano, Martina, Nicoletti, Maria Maddalena, Ferraro, Giuseppe Andrea, De Falco, Vincenzo, Lappano, Rosamaria, Lieto, Eva, Pagliuca, Francesca, Caputo, Carlo, La Noce, Marcella, Papaccio, Gianpaolo, Tirino, Virginia, Robinson, Nirmal, Desiderio, Vincenzo, and Papaccio, Federica

Published

2024

39. Therapeutic Effects of Mesenchymal Stromal Cells Require Mitochondrial Transfer and Quality Control.

Author

Mukkala, Avinash Naraiah, Jerkic, Mirjana, Khan, Zahra, Szaszi, Katalin, Kapus, Andras, and Rotstein, Ori

Subjects

*STROMAL cells, *QUALITY control, *MITOCHONDRIA, *ANTIMICROBIAL peptides, *IMMUNOREGULATION, *HOMEOSTASIS, *CELL fusion

Abstract

Due to their beneficial effects in an array of diseases, Mesenchymal Stromal Cells (MSCs) have been the focus of intense preclinical research and clinical implementation for decades. MSCs have multilineage differentiation capacity, support hematopoiesis, secrete pro-regenerative factors and exert immunoregulatory functions promoting homeostasis and the resolution of injury/inflammation. The main effects of MSCs include modulation of immune cells (macrophages, neutrophils, and lymphocytes), secretion of antimicrobial peptides, and transfer of mitochondria (Mt) to injured cells. These actions can be enhanced by priming (i.e., licensing) MSCs prior to exposure to deleterious microenvironments. Preclinical evidence suggests that MSCs can exert therapeutic effects in a variety of pathological states, including cardiac, respiratory, hepatic, renal, and neurological diseases. One of the key emerging beneficial actions of MSCs is the improvement of mitochondrial functions in the injured tissues by enhancing mitochondrial quality control (MQC). Recent advances in the understanding of cellular MQC, including mitochondrial biogenesis, mitophagy, fission, and fusion, helped uncover how MSCs enhance these processes. Specifically, MSCs have been suggested to regulate peroxisome proliferator-activated receptor-gamma coactivator 1 alpha (PGC1α)-dependent biogenesis, Parkin-dependent mitophagy, and Mitofusins (Mfn1/2) or Dynamin Related Protein-1 (Drp1)-mediated fission/fusion. In addition, previous studies also verified mitochondrial transfer from MSCs through tunneling nanotubes and via microvesicular transport. Combined, these effects improve mitochondrial functions, thereby contributing to the resolution of injury and inflammation. Thus, uncovering how MSCs affect MQC opens new therapeutic avenues for organ injury, and the transplantation of MSC-derived mitochondria to injured tissues might represent an attractive new therapeutic approach. [ABSTRACT FROM AUTHOR]

Published

2023

40. Intercellular mitochondrial transfer in the brain, a new perspective for targeted treatment of central nervous system diseases.

Author

Geng, Ziang, Guan, Shu, Wang, Siqi, Yu, Zhongxue, Liu, Tiancong, Du, Shaonan, and Zhu, Chen

Subjects

*CENTRAL nervous system diseases, *ORGANELLES, *MITOCHONDRIA, *MITOCHONDRIAL DNA, *CENTRAL nervous system, *CENTRAL nervous system injuries

Abstract

Aim: Mitochondria is one of the important organelles involved in cell energy metabolism and regulation and also play a key regulatory role in abnormal cell processes such as cell stress, cell damage, and cell canceration. Recent studies have shown that mitochondria can be transferred between cells in different ways and participate in the occurrence and development of many central nervous system diseases. We aim to review the mechanism of mitochondrial transfer in the progress of central nervous system diseases and the possibility of targeted therapy. Methods: The PubMed databank, the China National Knowledge Infrastructure databank, and Wanfang Data were searched to identify the experiments of intracellular mitochondrial transferrin central nervous system. The focus is on the donors, receptors, transfer pathways, and targeted drugs of mitochondrial transfer. Results: In the central nervous system, neurons, glial cells, immune cells, and tumor cells can transfer mitochondria to each other. Meanwhile, there are many types of mitochondrial transfer, including tunneling nanotubes, extracellular vesicles, receptor cell endocytosis, gap junction channels, and intercellular contact. A variety of stress signals, such as the release of damaged mitochondria, mitochondrial DNA, or other mitochondrial products and the elevation of reactive oxygen species, can trigger the transfer of mitochondria from donor cells to recipient cells. Concurrently, a variety of molecular pathways and related inhibitors can affect mitochondrial intercellular transfer. Conclusion: This study reviews the phenomenon of intercellular mitochondrial transfer in the central nervous system and summarizes the corresponding transfer pathways. Finally, we propose targeted pathways and treatment methods that may be used to regulate mitochondrial transfer for the treatment of related diseases. [ABSTRACT FROM AUTHOR]

Published

2023

41. The Crosstalk between Mesenchymal Stromal/Stem Cells and Hepatocytes in Homeostasis and under Stress.

Author

Kholodenko, Irina V., Kholodenko, Roman V., and Yarygin, Konstantin N.

Subjects

*LIVER regeneration, *STEM cells, *HOMEOSTASIS, *LIVER cells, *EXTRACELLULAR matrix proteins, *REGENERATION (Biology), *THERAPEUTICS

Abstract

Liver diseases, characterized by high morbidity and mortality, represent a substantial medical problem globally. The current therapeutic approaches are mainly aimed at reducing symptoms and slowing down the progression of the diseases. Organ transplantation remains the only effective treatment method in cases of severe liver pathology. In this regard, the development of new effective approaches aimed at stimulating liver regeneration, both by activation of the organ's own resources or by different therapeutic agents that trigger regeneration, does not cease to be relevant. To date, many systematic reviews and meta-analyses have been published confirming the effectiveness of mesenchymal stromal cell (MSC) transplantation in the treatment of liver diseases of various severities and etiologies. However, despite the successful use of MSCs in clinical practice and the promising therapeutic results in animal models of liver diseases, the mechanisms of their protective and regenerative action remain poorly understood. Specifically, data about the molecular agents produced by these cells and mediating their therapeutic action are fragmentary and often contradictory. Since MSCs or MSC-like cells are found in all tissues and organs, it is likely that many key intercellular interactions within the tissue niches are dependent on MSCs. In this context, it is essential to understand the mechanisms underlying communication between MSCs and differentiated parenchymal cells of each particular tissue. This is important both from the perspective of basic science and for the development of therapeutic approaches involving the modulation of the activity of resident MSCs. With regard to the liver, the research is concentrated on the intercommunication between MSCs and hepatocytes under normal conditions and during the development of the pathological process. The goals of this review were to identify the key factors mediating the crosstalk between MSCs and hepatocytes and determine the possible mechanisms of interaction of the two cell types under normal and stressful conditions. The analysis of the hepatocyte–MSC interaction showed that MSCs carry out chaperone-like functions, including the synthesis of the supportive extracellular matrix proteins; prevention of apoptosis, pyroptosis, and ferroptosis; support of regeneration; elimination of lipotoxicity and ER stress; promotion of antioxidant effects; and donation of mitochondria. The underlying mechanisms suggest very close interdependence, including even direct cytoplasm and organelle exchange. [ABSTRACT FROM AUTHOR]

Published

2023

42. Mitochondrial transfer in hematological malignancies.

Author

Guo, Xiaodong, Can, Can, Liu, Wancheng, Wei, Yihong, Yang, Xinyu, Liu, Jinting, Jia, Hexiao, Jia, Wenbo, Wu, Hanyang, and Ma, Daoxin

Subjects

CELL communication, HEMATOLOGIC malignancies, BONE marrow, DRUG resistance in cancer cells, MITOCHONDRIA, BONE marrow cells, CANCER cells

Abstract

Mitochondria are energy-generated organelles and take an important part in biological metabolism. Mitochondria could be transferred between cells, which serves as a new intercellular communication. Mitochondrial transfer improves mitochondrial defects, restores the biological functions of recipient cells, and maintains the high metabolic requirements of tumor cells as well as drug resistance. In recent years, it has been reported mitochondrial transfer between cells of bone marrow microenvironment and hematological malignant cells play a critical role in the disease progression and resistance during chemotherapy. In this review, we discuss the patterns and mechanisms on mitochondrial transfer and their engagement in different pathophysiological contexts and outline the latest knowledge on intercellular transport of mitochondria in hematological malignancies. Besides, we briefly outline the drug resistance mechanisms caused by mitochondrial transfer in cells during chemotherapy. Our review demonstrates a theoretical basis for mitochondrial transfer as a prospective therapeutic target to increase the treatment efficiency in hematological malignancies and improve the prognosis of patients. [ABSTRACT FROM AUTHOR]

Published

2023

43. Exploring the therapeutic potential of the mitochondrial transfer-associated enzymatic machinery in brain degeneration.

Author

Luque-Campos, Noymar, Riquelme, Ricardo, Molina, Luis, Canedo-Marroquín, Gisela, Vega-Letter, Ana María, Luz-Crawford, Patricia, and Bustamante-Barrientos, Felipe A.

Subjects

BRAIN degeneration, MITOCHONDRIA, EXTRACELLULAR vesicles, NEURODEGENERATION

Abstract

Mitochondrial dysfunction is a central event in the pathogenesis of several degenerative brain disorders. It entails fission and fusion dynamics disruption, progressive decline in mitochondrial clearance, and uncontrolled oxidative stress. Many therapeutic strategies have been formulated to reverse these alterations, including replacing damaged mitochondria with healthy ones. Spontaneous mitochondrial transfer is a naturally occurring process with different biological functions. It comprises mitochondrial donation from one cell to another, carried out through different pathways, such as the formation and stabilization of tunneling nanotubules and Gap junctions and the release of extracellular vesicles with mitochondrial cargoes. Even though many aspects of regulating these mechanisms still need to be discovered, some key enzymatic regulators have been identified. This review summarizes the current knowledge on mitochondrial dysfunction in different neurodegenerative disorders. Besides, we analyzed the usage of mitochondrial transfer as an endogenous revitalization tool, emphasizing the enzyme regulators that govern this mechanism. Going deeper into this matter would be helpful to take advantage of the therapeutic potential of mitochondrial transfer. [ABSTRACT FROM AUTHOR]

Published

2023

44. Mitochondrial transplantation and transfer: The promising method for diseases.

Author

KUBAT, Gökhan Burçin

Subjects

*MITOCHONDRIA, *CELL survival, *ADENOSINE triphosphate, *EUKARYOTIC cells, *BIOENERGETICS, *CELL communication

Abstract

Mitochondria are organelles that serve as the powerhouses for cellular bioenergetics in eukaryotic cells. It is responsible for mitochondrial adenosine triphosphate (ATP) generation, cell signaling and activity, calcium balance, cell survival, proliferation, apoptosis, and autophagy. Mitochondrial transplantation is a promising disease therapy that involves the recovery of mitochondrial dysfunction using isolated functioning mitochondria. The objective of the present article is to provide current knowledge on natural mitochondrial transfer processes, in vitro and in vivo applications of mitochondrial transplantation, clinical trials, and challenges associated with mitochondrial transplantation. [ABSTRACT FROM AUTHOR]

Published

2023

45. Edaravone and mitochondrial transfer as potential therapeutics for vanishing white matter disease astrocyte dysfunction.

Author

Ng, Neville S., Newbery, Michelle, Touffu, Aude, Maksour, Simon, Chung, Johnson, Carroll, Luke, Zaw, Thiri, Wu, Yunqi, and Ooi, Lezanne

Subjects

*LEUKOENCEPHALOPATHIES, *MITOCHONDRIAL pathology, *GLIAL fibrillary acidic protein, *UNFOLDED protein response, *EDARAVONE, *KREBS cycle

Abstract

Introduction: Previous research has suggested that vanishing white matter disease (VWMD) astrocytes fail to fully differentiate and respond differently to cellular stresses compared to healthy astrocytes. However, few studies have investigated potential VWMD therapeutics in monoculture patient‐derived cell‐based models. Methods: To investigate the impact of alterations in astrocyte expression and function in VWMD, astrocytes were differentiated from patient and control induced pluripotent stem cells and analyzed by proteomics, pathway analysis, and functional assays, in the absence and presence of stressors or potential therapeutics. Results: Vanishing white matter disease astrocytes demonstrated significantly reduced expression of astrocyte markers and markers of inflammatory activation or cellular stress relative to control astrocytes. These alterations were identified both in the presence and absence of polyinosinic:polycytidylic acid stimuli, which is used to simulate viral infections. Pathway analysis highlighted differential signaling in multiple pathways in VWMD astrocytes, including eukaryotic initiation factor 2 (EIF2) signaling, oxidative stress, oxidative phosphorylation (OXPHOS), mitochondrial function, the unfolded protein response (UPR), phagosome regulation, autophagy, ER stress, tricarboxylic acid cycle (TCA) cycle, glycolysis, tRNA signaling, and senescence pathways. Since oxidative stress and mitochondrial function were two of the key pathways affected, we investigated whether two independent therapeutic strategies could ameliorate astrocyte dysfunction: edaravone treatment and mitochondrial transfer. Edaravone treatment reduced differential VWMD protein expression of the UPR, phagosome regulation, ubiquitination, autophagy, ER stress, senescence, and TCA cycle pathways. Meanwhile, mitochondrial transfer decreased VWMD differential expression of the UPR, glycolysis, calcium transport, phagosome formation, and ER stress pathways, while further modulating EIF2 signaling, tRNA signaling, TCA cycle, and OXPHOS pathways. Mitochondrial transfer also increased the gene and protein expression of the astrocyte marker, glial fibrillary acidic protein (GFAP) in VWMD astrocytes. Conclusion: This study provides further insight into the etiology of VWMD astrocytic failure and suggests edaravone and mitochondrial transfer as potential candidate VWMD therapeutics that can ameliorate disease pathways in astrocytes related to oxidative stress, mitochondrial dysfunction, and proteostasis. [ABSTRACT FROM AUTHOR]

Published

2023

46. Mitochondrial transfer from bone mesenchymal stem cells protects against tendinopathy both in vitro and in vivo

Author

Bing Wei, Mingliang Ji, Yucheng Lin, Shanzheng Wang, Yuxi Liu, Rui Geng, Xinyue Hu, Li Xu, Zhuang Li, Weituo Zhang, and Jun Lu

Subjects

Mesenchymal stem cells, Achilles tendinopathy, Mitochondrial transfer, Tenocytes, Mitochondrial dysfunction, Apoptosis, Medicine (General), R5-920, Biochemistry, QD415-436

Abstract

Abstract Background Although mesenchymal stem cells (MSCs) have been effective in tendinopathy, the mechanisms by which MSCs promote tendon healing have not been fully elucidated. In this study, we tested the hypothesis that MSCs transfer mitochondria to injured tenocytes in vitro and in vivo to protect against Achilles tendinopathy (AT). Methods Bone marrow MSCs and H2O2-injured tenocytes were co-cultured, and mitochondrial transfer was visualized by MitoTracker dye staining. Mitochondrial function, including mitochondrial membrane potential, oxygen consumption rate, and adenosine triphosphate content, was quantified in sorted tenocytes. Tenocyte proliferation, apoptosis, oxidative stress, and inflammation were analyzed. Furthermore, a collagenase type I-induced rat AT model was used to detect mitochondrial transfer in tissues and evaluate Achilles tendon healing. Results MSCs successfully donated healthy mitochondria to in vitro and in vivo damaged tenocytes. Interestingly, mitochondrial transfer was almost completely blocked by co-treatment with cytochalasin B. Transfer of MSC-derived mitochondria decreased apoptosis, promoted proliferation, and restored mitochondrial function in H2O2-induced tenocytes. A decrease in reactive oxygen species and pro-inflammatory cytokine levels (interleukin-6 and -1β) was observed. In vivo, mitochondrial transfer from MSCs improved the expression of tendon-specific markers (scleraxis, tenascin C, and tenomodulin) and decreased the infiltration of inflammatory cells into the tendon. In addition, the fibers of the tendon tissue were neatly arranged and the structure of the tendon was remodeled. Inhibition of mitochondrial transfer by cytochalasin B abrogated the therapeutic efficacy of MSCs in tenocytes and tendon tissues. Conclusions MSCs rescued distressed tenocytes from apoptosis by transferring mitochondria. This provides evidence that mitochondrial transfer is one mechanism by which MSCs exert their therapeutic effects on damaged tenocytes.

Published

2023

47. Highly-purified rapidly expanding clones, RECs, are superior for functional-mitochondrial transfer

Author

Jiahao Yang, Lu Liu, Yasuaki Oda, Keisuke Wada, Mako Ago, Shinichiro Matsuda, Miho Hattori, Tsukimi Goto, Yuki Kawashima, Yumi Matsuzaki, and Takeshi Taketani

Subjects

Mesenchymal stem cells (MSCs), Rapidly expanding clones (RECs), Mitochondrial transfer, Mitochondrial dysfunction, Medicine (General), R5-920, Biochemistry, QD415-436

Abstract

Abstract Background Mitochondrial dysfunction caused by mutations in mitochondrial DNA (mtDNA) or nuclear DNA, which codes for mitochondrial components, are known to be associated with various genetic and congenital disorders. These mitochondrial disorders not only impair energy production but also affect mitochondrial functions and have no effective treatment. Mesenchymal stem cells (MSCs) are known to migrate to damaged sites and carry out mitochondrial transfer. MSCs grown using conventional culture methods exhibit heterogeneous cellular characteristics. In contrast, highly purified MSCs, namely the rapidly expanding clones (RECs) isolated by single-cell sorting, display uniform MSCs functionality. Therefore, we examined the differences between RECs and MSCs to assess the efficacy of mitochondrial transfer. Methods We established mitochondria-deficient cell lines (ρ0 A549 and ρ0 HeLa cell lines) using ethidium bromide. Mitochondrial transfer from RECs/MSCs to ρ0 cells was confirmed by PCR and flow cytometry analysis. We examined several mitochondrial functions including ATP, reactive oxygen species, mitochondrial membrane potential, and oxygen consumption rate (OCR). The route of mitochondrial transfer was identified using inhibition assays for microtubules/tunneling nanotubes, gap junctions, or microvesicles using transwell assay and molecular inhibitors. Results Co-culture of ρ0 cells with MSCs or RECs led to restoration of the mtDNA content. RECs transferred more mitochondria to ρ0 cells compared to that by MSCs. The recovery of mitochondrial function, including ATP, OCR, mitochondrial membrane potential, and mitochondrial swelling in ρ0 cells co-cultured with RECs was superior than that in cells co-cultured with MSCs. Inhibition assays for each pathway revealed that RECs were sensitive to endocytosis inhibitor, dynasore. Conclusions RECs might serve as a potential therapeutic strategy for diseases linked to mitochondrial dysfunction by donating healthy mitochondria.

Published

2023

48. Pressure-Driven Mitochondrial Transfer Pipeline Generates Mammalian Cells of Desired Genetic Combinations and Fates.

Author

Patananan, Alexander N, Sercel, Alexander J, Wu, Ting-Hsiang, Ahsan, Fasih M, Torres, Alejandro, Kennedy, Stephanie AL, Vandiver, Amy, Collier, Amanda J, Mehrabi, Artin, Van Lew, Jon, Zakin, Lise, Rodriguez, Noe, Sixto, Marcos, Tadros, Wael, Lazar, Adam, Sieling, Peter A, Nguyen, Thang L, Dawson, Emma R, Braas, Daniel, Golovato, Justin, Cisneros, Luis, Vaske, Charles, Plath, Kathrin, Rabizadeh, Shahrooz, Niazi, Kayvan R, Chiou, Pei-Yu, and Teitell, Michael A

Subjects

Cell Line, Mitochondria, Fibroblasts, Animals, Mice, Inbred C57BL, Humans, Mice, DNA, Mitochondrial, Gene Transfer Techniques, Cell Differentiation, Metabolome, Induced Pluripotent Stem Cells, High-Throughput Screening Assays, HEK293 Cells, Transcriptome, Cellular Reprogramming, cell engineering, differentiation, MitoPunch, mitochondrial transplantation, mitochondrial replacement, mitonuclear communication, isolated mitochondria, mitochondrial transfer, mtDNA, reprogramming, Clinical Research, Genetics, Regenerative Medicine, Stem Cell Research, Stem Cell Research - Nonembryonic - Human, Stem Cell Research - Induced Pluripotent Stem Cell, 1.1 Normal biological development and functioning, Generic health relevance, Biochemistry and Cell Biology, Medical Physiology

Abstract

Generating mammalian cells with desired mitochondrial DNA (mtDNA) sequences is enabling for studies of mitochondria, disease modeling, and potential regenerative therapies. MitoPunch, a high-throughput mitochondrial transfer device, produces cells with specific mtDNA-nuclear DNA (nDNA) combinations by transferring isolated mitochondria from mouse or human cells into primary or immortal mtDNA-deficient (ρ0) cells. Stable isolated mitochondrial recipient (SIMR) cells isolated in restrictive media permanently retain donor mtDNA and reacquire respiration. However, SIMR fibroblasts maintain a ρ0-like cell metabolome and transcriptome despite growth in restrictive media. We reprogrammed non-immortal SIMR fibroblasts into induced pluripotent stem cells (iPSCs) with subsequent differentiation into diverse functional cell types, including mesenchymal stem cells (MSCs), adipocytes, osteoblasts, and chondrocytes. Remarkably, after reprogramming and differentiation, SIMR fibroblasts molecularly and phenotypically resemble unmanipulated control fibroblasts carried through the same protocol. Thus, our MitoPunch "pipeline" enables the production of SIMR cells with unique mtDNA-nDNA combinations for additional studies and applications in multiple cell types.

Published

2020

49. A novel computational tool for tracking cancer energy hijacking from immune cells.

Author

Zhang, Hongyi and Li, Bo

Subjects

*CANCER cells, *T cells, *TRACKING algorithms, *OVERALL survival, *TREATMENT effectiveness

Abstract

Recent studies revealed a new biological process that malignant cancer cells hijack mitochondria from nearby T cells, providing another potential mechanism for immune evasion. We further confirmed this process at the single‐cell genomic level through MERCI, a novel algorithm for tracking mitochondrial (MT) transfer. Applied to human cancer samples, MERCI identified a new cancer phenotype linked to MT hijacking, correlating with rapid tumour proliferation and poor patient survival. This discovery offers insights into the limitations of current cancer immunotherapies and suggests new therapeutic avenues targeting MT transfer to enhance cancer treatment efficacy. [ABSTRACT FROM AUTHOR]

Published

2024

50. Mesenchymal stem cells influence monocyte/macrophage phenotype: Regulatory mode and potential clinical applications

Author

Dejin Lu, Xue Jiao, Wenjian Jiang, Li Yang, Qian Gong, Xiaobin Wang, Minjie Wei, and Shiqiang Gong

Subjects

Mesenchymal stem cells, M1/M2 phenotype, Monocytes/macrophages, Phagocytosis, Paracrine action, Mitochondrial transfer, Therapeutics. Pharmacology, RM1-950

Abstract

Mesenchymal stem cells (MSCs) are pluripotent stem cells derived from a variety of tissues, such as umbilical cord, fat, and bone marrow. Today, MSCs are widely recognized for their prominent anti-inflammatory properties in a variety of acute and chronic inflammatory diseases. In inflammatory diseases, monocytes/macrophages are an important part of the innate immune response in the body, and the alteration of the inflammatory phenotype plays a crucial role in the secretion of pro-inflammatory/anti-inflammatory factors, the repair of injured sites, and the infiltration of inflammatory cells. In this review, starting from the effect of MSCs on the monocyte/macrophage phenotype, we have outlined in detail the process by which MSCs influence the transformation of the monocyte/macrophage inflammatory phenotype, emphasizing the central role of monocytes/macrophages in MSC-mediated anti-inflammatory and damage site repair. MSCs are phagocytosed by monocytes/macrophages in various physiological states, the paracrine effect of MSCs and mitochondrial transfer of MSCs to macrophages to promote the transformation of monocytes/macrophages into anti-inflammatory phenotypes. We also review the clinical applications of the MSCs-monocytes/macrophages system and describe novel pathways between MSCs and tissue repair, the effects of MSCs on the adaptive immune system, and the effects of energy metabolism levels on monocyte/macrophage phenotypic changes.

Published

2023