Your search keyword '"Kwok, Maxwell"' showing total 4 results

1. SARS-CoV-2 variants divergently infect and damage cardiomyocytes in vitro and in vivo.

Author

Mok, Bobo Wing-Yee, Kwok, Maxwell, Li, Hung Sing, Ling, Lowell, Lai, Angel, Yan, Bin, Law, Cherie Tsz-Yiu, Yeung, Chui Him, Zhang, Anna Jinxia, Tam, Rachel Chun-Yee, Kukic, Anja, Cremin, Conor J., Zhang, Yajie, Long, Teng, Kang, Zhisen, Luo, Ruibang, Leung, Kam Tong, Li, Albert M., Lui, Grace, and Tsui, Stephen Kwok-Wing

Subjects

*SARS-CoV-2, *COVID-19, *SARS-CoV-2 Omicron variant, *GOLDEN hamster, *HEART diseases, *VIRAL tropism

Abstract

Background: COVID-19 can cause cardiac complications and the latter are associated with poor prognosis and increased mortality. SARS-CoV-2 variants differ in their infectivity and pathogenicity, but how they affect cardiomyocytes (CMs) is unclear. Methods: The effects of SARS-CoV-2 variants were investigated using human induced pluripotent stem cell-derived (hiPSC-) CMs in vitro and Golden Syrian hamsters in vivo. Results: Different variants exhibited distinct tropism, mechanism of viral entry and pathology in the heart. Omicron BA.2 most efficiently infected and injured CMs in vitro and in vivo, and induced expression changes consistent with increased cardiac dysfunction, compared to other variants tested. Bioinformatics and upstream regulator analyses identified transcription factors and network predicted to control the unique transcriptome of Omicron BA.2 infected CMs. Increased infectivity of Omicron BA.2 is attributed to its ability to infect via endocytosis, independently of TMPRSS2, which is absent in CMs. Conclusions: In this study, we reveal previously unknown differences in how different SARS-CoV-2 variants affect CMs. Omicron BA.2, which is generally thought to cause mild disease, can damage CMs in vitro and in vivo. Our study highlights the need for further investigations to define the pathogenesis of cardiac complications arising from different SARS-CoV-2 variants. [ABSTRACT FROM AUTHOR]

Published

2024

2. SARS-CoV-2 variants divergently infect and damage cardiomyocytes in vitro and in vivo.

Author

Mok, Bobo Wing-Yee, Kwok, Maxwell, Li, Hung Sing, Ling, Lowell, Lai, Angel, Yan, Bin, Law, Cherie Tsz-Yiu, Yeung, Chui Him, Zhang, Anna Jinxia, Tam, Rachel Chun-Yee, Kukic, Anja, Cremin, Conor J., Zhang, Yajie, Long, Teng, Kang, Zhisen, Luo, Ruibang, Leung, Kam Tong, Li, Albert M., Lui, Grace, and Tsui, Stephen Kwok-Wing

Subjects

*SARS-CoV-2, *COVID-19, *SARS-CoV-2 Omicron variant, *GOLDEN hamster, *HEART diseases, *VIRAL tropism

Abstract

Background: COVID-19 can cause cardiac complications and the latter are associated with poor prognosis and increased mortality. SARS-CoV-2 variants differ in their infectivity and pathogenicity, but how they affect cardiomyocytes (CMs) is unclear. Methods: The effects of SARS-CoV-2 variants were investigated using human induced pluripotent stem cell-derived (hiPSC-) CMs in vitro and Golden Syrian hamsters in vivo. Results: Different variants exhibited distinct tropism, mechanism of viral entry and pathology in the heart. Omicron BA.2 most efficiently infected and injured CMs in vitro and in vivo, and induced expression changes consistent with increased cardiac dysfunction, compared to other variants tested. Bioinformatics and upstream regulator analyses identified transcription factors and network predicted to control the unique transcriptome of Omicron BA.2 infected CMs. Increased infectivity of Omicron BA.2 is attributed to its ability to infect via endocytosis, independently of TMPRSS2, which is absent in CMs. Conclusions: In this study, we reveal previously unknown differences in how different SARS-CoV-2 variants affect CMs. Omicron BA.2, which is generally thought to cause mild disease, can damage CMs in vitro and in vivo. Our study highlights the need for further investigations to define the pathogenesis of cardiac complications arising from different SARS-CoV-2 variants. [ABSTRACT FROM AUTHOR]

Published

2024

3. Remdesivir induces persistent mitochondrial and structural damage in human induced pluripotent stem cell-derived cardiomyocytes.

Author

Kwok, Maxwell, Lee, Carrie, Li, Hung Sing, Deng, Ruixia, Tsoi, Chantelle, Ding, Qianqian, Tsang, Suk Ying, Leung, Kam Tong, Yan, Bryan P, and Poon, Ellen N

Subjects

*CORONAVIRUS disease treatment, *REMDESIVIR, *COVID-19, *MITOCHONDRIA, *ADENOSINE triphosphate, *PRODRUGS

Abstract

Aims Remdesivir is a prodrug of an adenosine triphosphate analogue and is currently the only drug formally approved for the treatment of hospitalized coronavirus disease of 2019 (COVID-19) patients. Nucleoside/nucleotide analogues have been shown to induce mitochondrial damage and cardiotoxicity, and this may be exacerbated by hypoxia, which frequently occurs in severe COVID-19 patients. Although there have been few reports of adverse cardiovascular events associated with remdesivir, clinical data are limited. Here, we investigated whether remdesivir induced cardiotoxicity using an in vitro human cardiac model. Methods and results Human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) were exposed to remdesivir under normoxic and hypoxic conditions to simulate mild and severe COVID-19, respectively. Remdesivir induced mitochondrial fragmentation, reduced redox potential, and suppressed mitochondrial respiration at levels below the estimated plasma concentration under both normoxic and hypoxic conditions. Non-mitochondrial damage such as electrophysiological alterations and sarcomere disarray were also observed. Importantly, some of these changes persisted after the cessation of treatment, culminating in increased cell death. Mechanistically, we found that inhibition of DRP1, a regulator of mitochondrial fission, ameliorated the cardiotoxic effects of remdesivir, showing that remdesivir-induced cardiotoxicity was preventable and excessive mitochondrial fission might contribute to this phenotype. Conclusions Using an in vitro model, we demonstrated that remdesivir can induce cardiotoxicity in hiPSC-CMs at clinically relevant concentrations. These results reveal previously unknown potential side-effects of remdesivir and highlight the importance of further investigations with in vivo animal models and active clinical monitoring to prevent lasting cardiac damage to patients. [ABSTRACT FROM AUTHOR]

Published

2022

4. Adipose tissue-derived human mesenchymal stromal cells can better suppress complement lysis, engraft and inhibit acute graft-versus-host disease in mice.

Author

Wu, Stanley Chun Ming, Zhu, Manyu, Chik, Stanley C. C., Kwok, Maxwell, Javed, Asif, Law, Laalaa, Chan, Shing, Boheler, Kenneth R., Liu, Yin Ping, Chan, Godfrey Chi Fung, and Poon, Ellen Ngar-Yun

Subjects

*GRAFT versus host disease, *STROMAL cells, *ADIPOSE tissues, *ACUTE diseases, *COMPLEMENT receptors, *HEMATOPOIETIC stem cell transplantation, *LYSIS

Abstract

Background: Acute graft-versus-host disease (aGvHD) is a life-threatening complication of allogeneic hematopoietic stem cell transplantation (HSCT). Transplantation of immunosuppressive human mesenchymal stromal cells (hMSCs) can protect against aGvHD post-HSCT; however, their efficacy is limited by poor engraftment and survival. Moreover, infused MSCs can be damaged by activated complement, yet strategies to minimise complement injury of hMSCs and improve their survival are limited. Methods: Human MSCs were derived from bone marrow (BM), adipose tissue (AT) and umbilical cord (UC). In vitro immunomodulatory potential was determined by co-culture experiments between hMSCs and immune cells implicated in aGvHD disease progression. BM-, AT- and UC-hMSCs were tested for their abilities to protect aGvHD in a mouse model of this disease. Survival and clinical symptoms were monitored, and target tissues of aGvHD were examined by histopathology and qPCR. Transplanted cell survival was evaluated by cell tracing and by qPCR. The transcriptome of BM-, AT- and UC-hMSCs was profiled by RNA-sequencing. Focused experiments were performed to compare the expression of complement inhibitors and the abilities of hMSCs to resist complement lysis. Results: Human MSCs derived from three tissues divergently protected against aGvHD in vivo. AT-hMSCs preferentially suppressed complement in vitro and in vivo, resisted complement lysis and survived better after transplantation when compared to BM- and UC-hMSCs. AT-hMSCs also prolonged survival and improved the symptoms and pathological features of aGvHD. We found that complement-decay accelerating factor (CD55), an inhibitor of complement, is elevated in AT-hMSCs and contributed to reduced complement activation. We further report that atorvastatin and erlotinib could upregulate CD55 and suppress complement in all three types of hMSCs. Conclusion: CD55, by suppressing complement, contributes to the improved protection of AT-hMSCs against aGvHD. The use of AT-hMSCs or the upregulation of CD55 by small molecules thus represents promising new strategies to promote hMSC survival to improve the efficacy of transplantation therapy. As complement injury is a barrier to all types of hMSC therapy, our findings are of broad significance to enhance the use of hMSCs for the treatment of a wide range of disorders. [ABSTRACT FROM AUTHOR]

Published

2023