Your search keyword '"Reyat, Jasmeet S"' showing total 40 results

1. Generating human bone marrow organoids for disease modeling and drug discovery

Author

Olijnik, Aude-Anais, Rodriguez-Romera, Antonio, Wong, Zoë C., Shen, Yuqi, Reyat, Jasmeet S., Jooss, Natalie J., Rayes, Julie, Psaila, Bethan, and Khan, Abdullah O.

Published

2024

2. An angiopoietin 2, FGF23, and BMP10 biomarker signature differentiates atrial fibrillation from other concomitant cardiovascular conditions

Author

Chua, Winnie, Cardoso, Victor R., Guasch, Eduard, Sinner, Moritz F., Al-Taie, Christoph, Brady, Paul, Casadei, Barbara, Crijns, Harry J. G. M., Dudink, Elton A. M. P., Hatem, Stéphane N., Kääb, Stefan, Kastner, Peter, Mont, Lluis, Nehaj, Frantisek, Purmah, Yanish, Reyat, Jasmeet S., Schotten, Ulrich, Sommerfeld, Laura C., Zeemering, Stef, Ziegler, André, Gkoutos, Georgios V., Kirchhof, Paulus, and Fabritz, Larissa

Published

2023

3. Chronic activation of human cardiac fibroblasts in vitro attenuates the reversibility of the myofibroblast phenotype

Author

Hall, Caitlin, Law, Jonathan P., Reyat, Jasmeet S., Cumberland, Max J., Hang, Shaun, Vo, Nguyen T. N., Raniga, Kavita, Weston, Chris J., O’Shea, Christopher, Townend, Jonathan N., Gehmlich, Katja, Ferro, Charles J., Denning, Chris, and Pavlovic, Davor

Published

2023

4. S100A8/A9 drives the formation of procoagulant platelets through GPIbα

Author

Colicchia, Martina, Schrottmaier, Waltraud C., Perrella, Gina, Reyat, Jasmeet S., Begum, Jenefa, Slater, Alexandre, Price, Joshua, Clark, Joanne C., Zhi, Zhaogong, Simpson, Megan J., Bourne, Joshua H., Poulter, Natalie S., Khan, Abdullah O., Nicolson, Phillip L. R., Pugh, Matthew, Harrison, Paul, Iqbal, Asif J., Rainger, George E., Watson, Steve P., Thomas, Mark R., Mutch, Nicola J., Assinger, Alice, and Rayes, Julie

Published

2022

5. Increased atrial effectiveness of flecainide conferred by altered biophysical properties of sodium channels

Author

O' Brien, Sian, Holmes, Andrew P., Johnson, Daniel M., Kabir, S. Nashitha, O' Shea, Christopher, O' Reilly, Molly, Avezzu, Adelisa, Reyat, Jasmeet S., Hall, Amelia W., Apicella, Clara, Ellinor, Patrick T., Niederer, Steven, Tucker, Nathan R., Fabritz, Larissa, Kirchhof, Paulus, and Pavlovic, Davor

Published

2022

6. Atrial resting membrane potential confers sodium current sensitivity to propafenone, flecainide and dronedarone

Author

Holmes, Andrew P., Saxena, Priyanka, Kabir, S. Nashitha, O’Shea, Christopher, Kuhlmann, Stefan M., Gupta, Suranjana, Fobian, Dannie, Apicella, Clara, O’Reilly, Molly, Syeda, Fahima, Reyat, Jasmeet S., Smith, Godfrey L., Workman, Antony J., Pavlovic, Davor, Fabritz, Larissa, and Kirchhof, Paulus

Published

2021

7. Modelling the pathology and treatment of cardiac fibrosis in vascularised atrial and ventricular cardiac microtissues

Author

Reyat, Jasmeet S., primary, di Maio, Alessandro, additional, Grygielska, Beata, additional, Pike, Jeremy, additional, Kemble, Samuel, additional, Rodriguez-Romero, Antonio, additional, Simoglou Karali, Christina, additional, Croft, Adam P., additional, Psaila, Bethan, additional, Simões, Filipa, additional, Rayes, Julie, additional, and Khan, Abdullah O., additional

Published

2023

8. Epigenetic and Transcriptional Networks Underlying Atrial Fibrillation

Author

van Ouwerkerk, Antoinette F., Hall, Amelia W., Kadow, Zachary A., Lazarevic, Sonja, Reyat, Jasmeet S., Tucker, Nathan R., Nadadur, Rangarajan D., Bosada, Fernanda M., Bianchi, Valerio, Ellinor, Patrick T., Fabritz, Larissa, Martin, James F., de Laat, Wouter, Kirchhof, Paulus, Moskowitz, Ivan P., and Christoffels, Vincent M.

Published

2020

9. Data from Human Bone Marrow Organoids for Disease Modeling, Discovery, and Validation of Therapeutic Targets in Hematologic Malignancies

Author

Khan, Abdullah O., primary, Rodriguez-Romera, Antonio, primary, Reyat, Jasmeet S., primary, Olijnik, Aude-Anais, primary, Colombo, Michela, primary, Wang, Guanlin, primary, Wen, Wei Xiong, primary, Sousos, Nikolaos, primary, Murphy, Lauren C., primary, Grygielska, Beata, primary, Perrella, Gina, primary, Mahony, Christopher B., primary, Ling, Rebecca E., primary, Elliott, Natalina E., primary, Karali, Christina Simoglou, primary, Stone, Andrew P., primary, Kemble, Samuel, primary, Cutler, Emily A., primary, Fielding, Adele K., primary, Croft, Adam P., primary, Bassett, David, primary, Poologasundarampillai, Gowsihan, primary, Roy, Anindita, primary, Gooding, Sarah, primary, Rayes, Julie, primary, Machlus, Kellie R., primary, and Psaila, Bethan, primary

Published

2023

10. Supp Table 1 from Human Bone Marrow Organoids for Disease Modeling, Discovery, and Validation of Therapeutic Targets in Hematologic Malignancies

Author

Khan, Abdullah O., primary, Rodriguez-Romera, Antonio, primary, Reyat, Jasmeet S., primary, Olijnik, Aude-Anais, primary, Colombo, Michela, primary, Wang, Guanlin, primary, Wen, Wei Xiong, primary, Sousos, Nikolaos, primary, Murphy, Lauren C., primary, Grygielska, Beata, primary, Perrella, Gina, primary, Mahony, Christopher B., primary, Ling, Rebecca E., primary, Elliott, Natalina E., primary, Karali, Christina Simoglou, primary, Stone, Andrew P., primary, Kemble, Samuel, primary, Cutler, Emily A., primary, Fielding, Adele K., primary, Croft, Adam P., primary, Bassett, David, primary, Poologasundarampillai, Gowsihan, primary, Roy, Anindita, primary, Gooding, Sarah, primary, Rayes, Julie, primary, Machlus, Kellie R., primary, and Psaila, Bethan, primary

Published

2023

11. Supp Table 2 from Human Bone Marrow Organoids for Disease Modeling, Discovery, and Validation of Therapeutic Targets in Hematologic Malignancies

Author

Khan, Abdullah O., primary, Rodriguez-Romera, Antonio, primary, Reyat, Jasmeet S., primary, Olijnik, Aude-Anais, primary, Colombo, Michela, primary, Wang, Guanlin, primary, Wen, Wei Xiong, primary, Sousos, Nikolaos, primary, Murphy, Lauren C., primary, Grygielska, Beata, primary, Perrella, Gina, primary, Mahony, Christopher B., primary, Ling, Rebecca E., primary, Elliott, Natalina E., primary, Karali, Christina Simoglou, primary, Stone, Andrew P., primary, Kemble, Samuel, primary, Cutler, Emily A., primary, Fielding, Adele K., primary, Croft, Adam P., primary, Bassett, David, primary, Poologasundarampillai, Gowsihan, primary, Roy, Anindita, primary, Gooding, Sarah, primary, Rayes, Julie, primary, Machlus, Kellie R., primary, and Psaila, Bethan, primary

Published

2023

12. Supp Table 3 from Human Bone Marrow Organoids for Disease Modeling, Discovery, and Validation of Therapeutic Targets in Hematologic Malignancies

Author

Khan, Abdullah O., primary, Rodriguez-Romera, Antonio, primary, Reyat, Jasmeet S., primary, Olijnik, Aude-Anais, primary, Colombo, Michela, primary, Wang, Guanlin, primary, Wen, Wei Xiong, primary, Sousos, Nikolaos, primary, Murphy, Lauren C., primary, Grygielska, Beata, primary, Perrella, Gina, primary, Mahony, Christopher B., primary, Ling, Rebecca E., primary, Elliott, Natalina E., primary, Karali, Christina Simoglou, primary, Stone, Andrew P., primary, Kemble, Samuel, primary, Cutler, Emily A., primary, Fielding, Adele K., primary, Croft, Adam P., primary, Bassett, David, primary, Poologasundarampillai, Gowsihan, primary, Roy, Anindita, primary, Gooding, Sarah, primary, Rayes, Julie, primary, Machlus, Kellie R., primary, and Psaila, Bethan, primary

Published

2023

13. Supp Table 4 from Human Bone Marrow Organoids for Disease Modeling, Discovery, and Validation of Therapeutic Targets in Hematologic Malignancies

Author

Khan, Abdullah O., primary, Rodriguez-Romera, Antonio, primary, Reyat, Jasmeet S., primary, Olijnik, Aude-Anais, primary, Colombo, Michela, primary, Wang, Guanlin, primary, Wen, Wei Xiong, primary, Sousos, Nikolaos, primary, Murphy, Lauren C., primary, Grygielska, Beata, primary, Perrella, Gina, primary, Mahony, Christopher B., primary, Ling, Rebecca E., primary, Elliott, Natalina E., primary, Karali, Christina Simoglou, primary, Stone, Andrew P., primary, Kemble, Samuel, primary, Cutler, Emily A., primary, Fielding, Adele K., primary, Croft, Adam P., primary, Bassett, David, primary, Poologasundarampillai, Gowsihan, primary, Roy, Anindita, primary, Gooding, Sarah, primary, Rayes, Julie, primary, Machlus, Kellie R., primary, and Psaila, Bethan, primary

Published

2023

14. Supp Table 5 from Human Bone Marrow Organoids for Disease Modeling, Discovery, and Validation of Therapeutic Targets in Hematologic Malignancies

Author

Khan, Abdullah O., primary, Rodriguez-Romera, Antonio, primary, Reyat, Jasmeet S., primary, Olijnik, Aude-Anais, primary, Colombo, Michela, primary, Wang, Guanlin, primary, Wen, Wei Xiong, primary, Sousos, Nikolaos, primary, Murphy, Lauren C., primary, Grygielska, Beata, primary, Perrella, Gina, primary, Mahony, Christopher B., primary, Ling, Rebecca E., primary, Elliott, Natalina E., primary, Karali, Christina Simoglou, primary, Stone, Andrew P., primary, Kemble, Samuel, primary, Cutler, Emily A., primary, Fielding, Adele K., primary, Croft, Adam P., primary, Bassett, David, primary, Poologasundarampillai, Gowsihan, primary, Roy, Anindita, primary, Gooding, Sarah, primary, Rayes, Julie, primary, Machlus, Kellie R., primary, and Psaila, Bethan, primary

Published

2023

15. Supplementary Information from Human Bone Marrow Organoids for Disease Modeling, Discovery, and Validation of Therapeutic Targets in Hematologic Malignancies

Author

Khan, Abdullah O., primary, Rodriguez-Romera, Antonio, primary, Reyat, Jasmeet S., primary, Olijnik, Aude-Anais, primary, Colombo, Michela, primary, Wang, Guanlin, primary, Wen, Wei Xiong, primary, Sousos, Nikolaos, primary, Murphy, Lauren C., primary, Grygielska, Beata, primary, Perrella, Gina, primary, Mahony, Christopher B., primary, Ling, Rebecca E., primary, Elliott, Natalina E., primary, Karali, Christina Simoglou, primary, Stone, Andrew P., primary, Kemble, Samuel, primary, Cutler, Emily A., primary, Fielding, Adele K., primary, Croft, Adam P., primary, Bassett, David, primary, Poologasundarampillai, Gowsihan, primary, Roy, Anindita, primary, Gooding, Sarah, primary, Rayes, Julie, primary, Machlus, Kellie R., primary, and Psaila, Bethan, primary

Published

2023

16. Insights into the Role of a Cardiomyopathy-Causing Genetic Variant in ACTN2

Author

Broadway-Stringer, Sophie, primary, Jiang, He, additional, Wadmore, Kirsty, additional, Hooper, Charlotte, additional, Douglas, Gillian, additional, Steeples, Violetta, additional, Azad, Amar J., additional, Singer, Evie, additional, Reyat, Jasmeet S., additional, Galatik, Frantisek, additional, Ehler, Elisabeth, additional, Bennett, Pauline, additional, Kalisch-Smith, Jacinta I., additional, Sparrow, Duncan B., additional, Davies, Benjamin, additional, Djinovic-Carugo, Kristina, additional, Gautel, Mathias, additional, Watkins, Hugh, additional, and Gehmlich, Katja, additional

Published

2023

17. Human Bone Marrow Organoids Enable the Study of Hematopoietic Cell-Stromal Interactions and Support the Survival of Malignant Cells from Patients

Author

Khan, Abdullah, primary, Rodriguez-Romera, Antonio, additional, Colombo, Michela, additional, Reyat, Jasmeet S, additional, Wang, Guanlin, additional, Wen, Wei Xiong, additional, Murphy, Lauren C, additional, Ling, Rebecca, additional, Elliott, Natalina, additional, Sousos, Nikolaos, additional, Kemble, Samuel, additional, Grygielska, Beata, additional, Mahoney, Christopher, additional, Stone, Andrew P., additional, Croft, Adam P, additional, Bassett, David, additional, Poologasundarampillai, Gowsihan, additional, Fielding, Adele K., additional, Cutler, Emily A., additional, Roy, Anindita, additional, Gooding, Sarah, additional, Rayes, Julie, additional, Machlus, Kellie, additional, and Psaila, Bethan, additional

Published

2022

18. Human Bone Marrow Organoids for Disease Modeling, Discovery, and Validation of Therapeutic Targets in Hematologic Malignancies

Author

Khan, Abdullah O., primary, Rodriguez-Romera, Antonio, additional, Reyat, Jasmeet S., additional, Olijnik, Aude-Anais, additional, Colombo, Michela, additional, Wang, Guanlin, additional, Wen, Wei Xiong, additional, Sousos, Nikolaos, additional, Murphy, Lauren C., additional, Grygielska, Beata, additional, Perrella, Gina, additional, Mahony, Christopher B., additional, Ling, Rebecca E., additional, Elliott, Natalina E., additional, Karali, Christina Simoglou, additional, Stone, Andrew P., additional, Kemble, Samuel, additional, Cutler, Emily A., additional, Fielding, Adele K., additional, Croft, Adam P., additional, Bassett, David, additional, Poologasundarampillai, Gowsihan, additional, Roy, Anindita, additional, Gooding, Sarah, additional, Rayes, Julie, additional, Machlus, Kellie R., additional, and Psaila, Bethan, additional

Published

2022

19. Utilizing Lentiviral Gene Transfer in Primary Endothelial Cells to Assess Lymphocyte-Endothelial Interactions

Author

Reyat, Jasmeet S., primary, Tomlinson, Michael G., additional, and Noy, Peter J., additional

Published

2017

20. Preferential uptake of SARS-CoV-2 by pericytes potentiates vascular damage and permeability in an organoid model of the microvasculature

Author

Khan, Abdullah O, primary, Reyat, Jasmeet S, additional, Hill, Harriet, additional, Bourne, Joshua H, additional, Colicchia, Martina, additional, Newby, Maddy L, additional, Allen, Joel D, additional, Crispin, Max, additional, Youd, Esther, additional, Murray, Paul G, additional, Taylor, Graham, additional, Stamataki, Zania, additional, Richter, Alex G, additional, Cunningham, Adam F, additional, Pugh, Matthew, additional, and Rayes, Julie, additional

Published

2022

21. The atrial resting membrane potential confers sodium current sensitivity to propafenone, flecainide and dronedarone

Author

Holmes, Andrew P., Saxena, Priyanka, Kabir, S. Nashitha, O'Shea, Christopher, Kuhlmann, Stefan M., Gupta, Suranjana, Fobian, Dannie, Apicella, Clara, O'Reilly, Molly, Syeda, Fahima, Reyat, Jasmeet S., Smith, Godfrey L., Workman, Antony J., Pavlovic, Davor, Fabritz, Larissa, and Kirchhof, Paulus

Subjects

cardiovascular system

Abstract

Background: \ud Although atrial fibrillation (AF) ablation is increasingly used for rhythm control therapy, antiarrhythmic drugs (AADs) are commonly used, either alone or in combination with ablation. The effectiveness of AADs is highly variable. Prior work from our group suggests that alterations in the atrial resting membrane potential (RMP) induced by low Pitx2 expression could explain the variable effect of flecainide.\ud \ud Objective: \ud This study assessed whether alterations in the atrial/cardiac RMP modify the effectiveness of multiple clinically used AADs.\ud \ud Methods: \ud The sodium channel blocking effects of propafenone (300nM, 1μM), flecainide (1μM) and dronedarone (5μM, 10μM) were measured in human stem cell derived cardiac myocytes, HEK293 expressing human Nav1.5, primary murine atrial cardiac myocytes and murine hearts with reduced Pitx2c.\ud \ud Results: \ud A more positive atrial RMP delayed INa recovery, slowed channel inactivation and decreased the peak AP upstroke velocity. All three AADs displayed enhanced sodium channel block at more positive atrial RMPs. Dronedarone was the most sensitive to changes in the atrial RMP. Dronedarone caused greater reductions in AP amplitude and peak AP upstroke velocity at more positive RMPs. Dronedarone evoked greater prolongation of the atrial effective refractory period and post-repolarisation refractoriness in murine Langendorff-perfused Pitx2c+/- hearts, which have a more positive RMP compared to wild-type.\ud \ud Conclusion: \ud The atrial RMP modifies the effectiveness of several clinically used AADs. Dronedarone is more sensitive to changes in atrial RMP than flecainide or propafenone. Identifying and modifying the atrial RMP may offer a novel approach to enhancing the effectiveness of AADs or personalizing AAD selection.

Published

2021

22. Novel gene variants in patients with platelet‐based bleeding using combined exome sequencing and RNAseq murine expression data

Author

Khan, Abdullah O., Stapley, Rachel J., Pike, Jeremy A., Wijesinghe, Susanne.N., Reyat, Jasmeet S., Almazni, Ibrahim, Machlus, Kellie R., and Morgan, Neil V.

Published

2021

23. Stimulation of vascular organoids with SARS-CoV-2 antigens increases endothelial permeability and regulates vasculopathy

Author

Khan, Abdullah O., primary, Reyat, Jasmeet S., additional, Bourne, Joshua H., additional, Colicchia, Martina, additional, Newby, Maddy L., additional, Allen, Joel D., additional, Crispin, Max, additional, Youd, Esther, additional, Murray, Paul G., additional, Taylor, Graham, additional, Stamataki, Zania, additional, Richter, Alex G., additional, Cunningham, Adam F., additional, Pugh, Matthew, additional, and Rayes, Julie, additional

Published

2021

24. Epigenetic and Transcriptional Networks Underlying Atrial Fibrillation

Author

van Ouwerkerk, Antoinette F, Hall, Amelia W, Kadow, Zachary A, Lazarevic, Sonja, Reyat, Jasmeet S, Tucker, Nathan R, Nadadur, Rangarajan D, Bosada, Fernanda M, Bianchi, Valerio, Ellinor, Patrick T, Fabritz, Larissa, Martin, James F, de Laat, Wouter, Kirchhof, Paulus, Moskowitz, Ivan P, Christoffels, Vincent M, van Ouwerkerk, Antoinette F, Hall, Amelia W, Kadow, Zachary A, Lazarevic, Sonja, Reyat, Jasmeet S, Tucker, Nathan R, Nadadur, Rangarajan D, Bosada, Fernanda M, Bianchi, Valerio, Ellinor, Patrick T, Fabritz, Larissa, Martin, James F, de Laat, Wouter, Kirchhof, Paulus, Moskowitz, Ivan P, and Christoffels, Vincent M

Abstract

Genome-wide association studies have uncovered over a 100 genetic loci associated with atrial fibrillation (AF), the most common arrhythmia. Many of the top AF-associated loci harbor key cardiac transcription factors, including PITX2, TBX5, PRRX1, and ZFHX3. Moreover, the vast majority of the AF-associated variants lie within noncoding regions of the genome where causal variants affect gene expression by altering the activity of transcription factors and the epigenetic state of chromatin. In this review, we discuss a transcriptional regulatory network model for AF defined by effector genes in Genome-wide association studies loci. We describe the current state of the field regarding the identification and function of AF-relevant gene regulatory networks, including variant regulatory elements, dose-sensitive transcription factor functionality, target genes, and epigenetic states. We illustrate how altered transcriptional networks may impact cardiomyocyte function and ionic currents that impact AF risk. Last, we identify the need for improved tools to identify and functionally test transcriptional components to define the links between genetic variation, epigenetic gene regulation, and atrial function.

Published

2020

25. Epigenetic and Transcriptional Networks Underlying Atrial Fibrillation

Author

Genetica, Cancer, Hubrecht Institute with UMC, van Ouwerkerk, Antoinette F, Hall, Amelia W, Kadow, Zachary A, Lazarevic, Sonja, Reyat, Jasmeet S, Tucker, Nathan R, Nadadur, Rangarajan D, Bosada, Fernanda M, Bianchi, Valerio, Ellinor, Patrick T, Fabritz, Larissa, Martin, James F, de Laat, Wouter, Kirchhof, Paulus, Moskowitz, Ivan P, Christoffels, Vincent M, Genetica, Cancer, Hubrecht Institute with UMC, van Ouwerkerk, Antoinette F, Hall, Amelia W, Kadow, Zachary A, Lazarevic, Sonja, Reyat, Jasmeet S, Tucker, Nathan R, Nadadur, Rangarajan D, Bosada, Fernanda M, Bianchi, Valerio, Ellinor, Patrick T, Fabritz, Larissa, Martin, James F, de Laat, Wouter, Kirchhof, Paulus, Moskowitz, Ivan P, and Christoffels, Vincent M

Published

2020

26. Post-translational polymodification of β1-tubulin regulates motor protein localization in platelet production and function

Author

Khan, Abdullah O., primary, Slater, Alexandre, additional, Maclachlan, Annabel, additional, Nicolson, Phillip L.R., additional, Pike, Jeremy A., additional, Reyat, Jasmeet S., additional, Yule, Jack, additional, Stapley, Rachel, additional, Rayes, Julie, additional, Thomas, Steven G., additional, and Morgan, Neil V., additional

Published

2020

27. Reduced left atrial cardiomyocyte PITX2 and elevated circulating BMP10 predict atrial fibrillation after ablation

Author

Reyat, Jasmeet S., primary, Chua, Winnie, additional, Cardoso, Victor R., additional, Witten, Anika, additional, Kastner, Peter M., additional, Kabir, S. Nashitha, additional, Sinner, Moritz F., additional, Wesselink, Robin, additional, Holmes, Andrew P., additional, Pavlovic, Davor, additional, Stoll, Monika, additional, Kääb, Stefan, additional, Gkoutos, Georgios V., additional, de Groot, Joris R., additional, Kirchhof, Paulus, additional, and Fabritz, Larissa, additional

Published

2020

28. Regulation of A disintegrin and metalloproteinase (ADAM) family sheddases ADAM10 and ADAM17: The emerging role of tetraspanins and rhomboids

Author

Matthews, Alexandra L., Noy, Peter J., Reyat, Jasmeet S., and Tomlinson, Michael G.

Subjects

platelet, ADAM17, Tetraspanins, Disintegrins, ADAM10, iRhom, Review, ADAM17 Protein, ADAM10 Protein, tetraspanin, Special Review Section: Platelet Receptor Shedding, TspanC8, Animals, Humans

Abstract

A disintegrin and metalloprotease (ADAM) 10 and ADAM17 are ubiquitous transmembrane “molecular scissors” which proteolytically cleave, or shed, the extracellular regions of other transmembrane proteins. ADAM10 is essential for development because it cleaves Notch proteins to induce Notch signaling and regulate cell fate decisions. ADAM17 is regarded as a first line of defense against injury and infection, by releasing tumor necrosis factor α (TNFα) to promote inflammation and epidermal growth factor (EGF) receptor ligands to maintain epidermal barrier function. However, the regulation of ADAM10 and ADAM17 trafficking and activation are not fully understood. This review will describe how the TspanC8 subgroup of tetraspanins (Tspan5, 10, 14, 15, 17, and 33) and the iRhom subgroup of protease-inactive rhomboids (iRhom1 and 2) have emerged as important regulators of ADAM10 and ADAM17, respectively. In particular, they are required for the enzymatic maturation and trafficking to the cell surface of the ADAMs, and there is evidence that different TspanC8s and iRhoms target the ADAMs to distinct substrates. The TspanC8s and iRhoms have not been studied functionally on platelets. On these cells, ADAM10 is the principal sheddase for the platelet collagen receptor GPVI, and the regulatory TspanC8s are Tspan14, 15, and 33, as determined from proteomic data. Platelet ADAM17 is the sheddase for the von Willebrand factor (vWF) receptor GPIb, and iRhom2 is the only iRhom that is expressed. Induced shedding of either GPVI or GPIb has therapeutic potential, since inhibition of either receptor is regarded as a promising anti-thrombotic therapy. Targeting of Tspan14, 15, or 33 to activate platelet ADAM10, or iRhom2 to activate ADAM17, may enable such an approach to be realized, without the toxic side effects of activating the ADAMs on every cell in the body.

Published

2016

29. Post-translational polymodification of β1 tubulin regulates motor protein localisation in platelet production and function

Author

Khan, Abdullah O., primary, Slater, Alexandre, additional, Maclachlan, Annabel, additional, Nicolson, Phillip L.R., additional, Pike, Jeremy A., additional, Reyat, Jasmeet S., additional, Yule, Jack, additional, Stapley, Rachel, additional, Thomas, Steven G., additional, and Morgan, Neil V., additional

Published

2019

30. Tspan18 is a novel regulator of the Ca2+ channel Orai1 and von Willebrand factor release in endothelial cells

Author

Noy, Peter J., primary, Gavin, Rebecca L., additional, Colombo, Dario, additional, Haining, Elizabeth J., additional, Reyat, Jasmeet S., additional, Payne, Holly, additional, Thielmann, Ina, additional, Lokman, Adam B., additional, Neag, Georgiana, additional, Yang, Jing, additional, Lloyd, Tammy, additional, Harrison, Neale, additional, Heath, Victoria L., additional, Gardiner, Chris, additional, Whitworth, Katharine M., additional, Robinson, Joseph, additional, Koo, Chek Z., additional, Di Maio, Alessandro, additional, Harrison, Paul, additional, Lee, Steven P., additional, Michelangeli, Francesco, additional, Kalia, Neena, additional, Rainger, G. Ed, additional, Nieswandt, Bernhard, additional, Brill, Alexander, additional, Watson, Steve P., additional, and Tomlinson, Michael G., additional

Published

2018

31. ADAM10-Interacting Tetraspanins Tspan5 and Tspan17 Regulate VE-Cadherin Expression and Promote T Lymphocyte Transmigration

Author

Reyat, Jasmeet S., primary, Chimen, Myriam, additional, Noy, Peter J., additional, Szyroka, Justyna, additional, Rainger, G. Ed, additional, and Tomlinson, Michael G., additional

Published

2017

32. TspanC8 Tetraspanins and A Disintegrin and Metalloprotease 10 (ADAM10) Interact via Their Extracellular Regions

Author

Noy, Peter J., primary, Yang, Jing, additional, Reyat, Jasmeet S., additional, Matthews, Alexandra L., additional, Charlton, Alice E., additional, Furmston, Joanna, additional, Rogers, David A., additional, Rainger, G. Ed, additional, and Tomlinson, Michael G., additional

Published

2016

33. Regulation of A disintegrin and metalloproteinase (ADAM) family sheddases ADAM10 and ADAM17: The emerging role of tetraspanins and rhomboids.

Author

Matthews, Alexandra L., Noy, Peter J., Reyat, Jasmeet S., and Tomlinson, Michael G.

Subjects

DISINTEGRINS, METALLOPROTEINASE regulation, METALLOPROTEINASE genetics, TUMOR necrosis factors, CELL membranes

Abstract

A disintegrin and metalloprotease (ADAM) 10 and ADAM17 are ubiquitous transmembrane “molecular scissors” which proteolytically cleave, or shed, the extracellular regions of other transmembrane proteins. ADAM10 is essential for development because it cleaves Notch proteins to induce Notch signaling and regulate cell fate decisions. ADAM17 is regarded as a first line of defense against injury and infection, by releasing tumor necrosis factor α (TNFα) to promote inflammation and epidermal growth factor (EGF) receptor ligands to maintain epidermal barrier function. However, the regulation of ADAM10 and ADAM17 trafficking and activation are not fully understood. This review will describe how the TspanC8 subgroup of tetraspanins (Tspan5, 10, 14, 15, 17, and 33) and the iRhom subgroup of protease-inactive rhomboids (iRhom1 and 2) have emerged as important regulators of ADAM10 and ADAM17, respectively. In particular, they are required for the enzymatic maturation and trafficking to the cell surface of the ADAMs, and there is evidence that different TspanC8s and iRhoms target the ADAMs to distinct substrates. The TspanC8s and iRhoms have not been studied functionally on platelets. On these cells, ADAM10 is the principal sheddase for the platelet collagen receptor GPVI, and the regulatory TspanC8s are Tspan14, 15, and 33, as determined from proteomic data. Platelet ADAM17 is the sheddase for the von Willebrand factor (vWF) receptor GPIb, and iRhom2 is the only iRhom that is expressed. Induced shedding of either GPVI or GPIb has therapeutic potential, since inhibition of either receptor is regarded as a promising anti-thrombotic therapy. Targeting of Tspan14, 15, or 33 to activate platelet ADAM10, or iRhom2 to activate ADAM17, may enable such an approach to be realized, without the toxic side effects of activating the ADAMs on every cell in the body. [ABSTRACT FROM PUBLISHER]

Published

2017

34. Increased atrial effectiveness of flecainide conferred by altered biophysical properties of sodium channels

Author

O' Brien, Sian, Holmes, Andrew P., Johnson, Daniel M., Kabir, S. Nashitha, O' Shea, Christopher, O' Reilly, Molly, Avezzu, Adelisa, Reyat, Jasmeet S., Hall, Amelia W., Apicella, Clara, Ellinor, Patrick T., Niederer, Steven, Tucker, Nathan R., Fabritz, Larissa, Kirchhof, Paulus, Pavlovic, Davor, O' Brien, Sian, Holmes, Andrew P., Johnson, Daniel M., Kabir, S. Nashitha, O' Shea, Christopher, O' Reilly, Molly, Avezzu, Adelisa, Reyat, Jasmeet S., Hall, Amelia W., Apicella, Clara, Ellinor, Patrick T., Niederer, Steven, Tucker, Nathan R., Fabritz, Larissa, Kirchhof, Paulus, and Pavlovic, Davor

Abstract

Atrial fibrillation (AF) affects over 1% of the population and is a leading cause of stroke and heart failure in the elderly. A feared side effect of sodium channel blocker therapy, ventricular pro-arrhythmia, appears to be relatively rare in patients with AF. The biophysical reasons for this relative safety of sodium blockers are not known. Our data demonstrates intrinsic differences between atrial and ventricular cardiac voltage-gated sodium currents (INa), leading to reduced maximum upstroke velocity of action potential and slower conduction, in left atria compared to ventricle. Reduced atrial INa is only detected at physiological membrane potentials and is driven by alterations in sodium channel biophysical properties and not by NaV1.5 protein expression. Flecainide displayed greater inhibition of atrial INa, greater reduction of maximum upstroke velocity of action potential, and slowed conduction in atrial cells and tissue. Our work highlights differences in biophysical properties of sodium channels in left atria and ventricles and their response to flecainide. These differences can explain the relative safety of sodium channel blocker therapy in patients with atrial fibrillation.

35. ADAM10-Interacting Tetraspanins Tspan5 and Tspan17 Regulate VE-Cadherin Expression and Promote T Lymphocyte Transmigration.

Author

Noy, Peter J., Szyroka, Justyna, Reyat, Jasmeet S., Tomlinson, Michael G., Chimen, Myriam, and Ed Rainger, G.

Subjects

*TETRASPANIN, *LEUCOCYTES, *BLOOD cells, *T cells, *LYMPHOCYTE transformation

Abstract

The recruitment of blood leukocytes across the endothelium to sites of tissue infection is central to inflammation, but also promotes chronic inflammatory diseases. A disintegrin and metalloproteinase 10 (ADAM10) is a ubiquitous transmembrane molecular scissor that is implicated in leukocyte transmigration by proteolytically cleaving its endothelial substrates. These include VE-cadherin, a homotypic adhesion molecule that regulates endothelial barrier function, and transmembrane chemokines CX3CL1 and CXCL16, which have receptors on leukocytes. However, a definitive role for endothelial ADAM10 in transmigration of freshly isolated primary leukocytes under flow has not been demonstrated, and the relative importance of distinct ADAM10 substrates is unknown. Emerging evidence suggests that ADAM10 can be regarded as six different molecular scissors with different substrate specificities, depending on which of six TspanC8 tetraspanins it is associated with, but TspanC8s remain unstudied in leukocyte transmigration. In the current study, ADAM10 knockdown on primary HUVECs was found to impair transmigration of freshly isolated human peripheral blood T lymphocytes, but not neutrophils or B lymphocytes, in an in vitro flow assay. This impairment was due to delayed transmigration rather than a complete block, and was overcome in the presence of neutrophils. Transmigration of purified lymphocytes was dependent on ADAM10 regulation of VE-cadherin, but not CX3CL1 and CXCL16. Tspan5 and Tspan17, the two most closely related TspanC8s by sequence, were the only TspanC8s that regulated VE-cadherin expression and were required for lymphocyte transmigration. Therefore endothelial Tspan5- and Tspan17-ADAM10 complexes may regulate inflammation by maintaining normal VE-cadherin expression and promoting T lymphocyte transmigration. [ABSTRACT FROM AUTHOR]

Published

2017

36. PITX2 deficiency leads to atrial mitochondrial dysfunction.

Author

Reyat JS, Sommerfeld LC, O'Reilly M, Cardoso VR, Thiemann E, Khan AO, O'Shea C, Harder S, Müller C, Barlow J, Stapley RJ, Chua W, Kabir SN, Grech O, Hummel O, Hübner N, Kääb S, Mont L, Hatem SN, Winters J, Zeemering S, Morgan NV, Rayes J, Gehmlich K, Stoll M, Brand T, Schweizer M, Piasecki A, Schotten U, Gkoutos GV, Lorenz K, Cuello F, Kirchhof P, and Fabritz L

Abstract

Aim: Reduced left atrial PITX2 is associated with atrial cardiomyopathy and atrial fibrillation. PITX2 is restricted to left atrial cardiomyocytes in the adult heart. The links between PITX2 deficiency, atrial cardiomyopathy and atrial fibrillation are not fully understood., Methods and Results: To identify mechanisms linking PITX2 deficiency to atrial fibrillation, we generated and characterized PITX2-deficient human atrial cardiomyocytes derived from human induced pluripotent stem cells (hiPSC) and their controls. PITX2-deficient hiPSC-derived atrial cardiomyocytes showed shorter and disorganised sarcomeres and increased mononucleation. Electron microscopy found an increased number of smaller mitochondria compared to the control. Mitochondrial protein expression was altered in PITX2-deficient hiPSC-derived atrial cardiomyocytes. Single-nuclear RNA-sequencing found differences in cellular respiration pathways and differentially expressed mitochondrial and ion channel genes in PITX2-deficient hiPSC-derived atrial cardiomyocytes. PITX2 repression in hiPSC-derived atrial cardiomyocytes replicated dysregulation of cellular respiration. Mitochondrial respiration was shifted to increased glycolysis in PITX2-deficient hiPSC-derived atrial cardiomyocytes. PITX2-deficient human hiPSC-derived atrial cardiomyocytes showed higher spontaneous beating rates. Action potential duration was more variable with an overall prolongation of early repolarization, consistent with metabolic defects. Gene expression analyses confirmed changes in mitochondrial genes in left atria from 42 patients with atrial fibrillation compared to 43 patients in sinus rhythm. Dysregulation of left atrial mitochondrial (COX7C) and metabolic (FOXO1) genes was associated with PITX2 expression in human left atria., Conclusions: In summary, PITX2 deficiency causes mitochondrial dysfunction and a metabolic shift to glycolysis in human atrial cardiomyocytes. PITX2-dependent metabolic changes can contribute to the structural and functional defects found in PITX2-deficient atria., (© The Author(s) 2024. Published by Oxford University Press on behalf of the European Society of Cardiology.)

Published

2024

37. Human Bone Marrow Organoids for Disease Modeling, Discovery, and Validation of Therapeutic Targets in Hematologic Malignancies.

Author

Khan AO, Rodriguez-Romera A, Reyat JS, Olijnik AA, Colombo M, Wang G, Wen WX, Sousos N, Murphy LC, Grygielska B, Perrella G, Mahony CB, Ling RE, Elliott NE, Karali CS, Stone AP, Kemble S, Cutler EA, Fielding AK, Croft AP, Bassett D, Poologasundarampillai G, Roy A, Gooding S, Rayes J, Machlus KR, and Psaila B

Subjects

Humans, Bone Marrow Cells physiology, Bone Marrow Transplantation, Organoids, Tumor Microenvironment, Bone Marrow, Hematologic Neoplasms

Abstract

A lack of models that recapitulate the complexity of human bone marrow has hampered mechanistic studies of normal and malignant hematopoiesis and the validation of novel therapies. Here, we describe a step-wise, directed-differentiation protocol in which organoids are generated from induced pluripotent stem cells committed to mesenchymal, endothelial, and hematopoietic lineages. These 3D structures capture key features of human bone marrow-stroma, lumen-forming sinusoids, and myeloid cells including proplatelet-forming megakaryocytes. The organoids supported the engraftment and survival of cells from patients with blood malignancies, including cancer types notoriously difficult to maintain ex vivo. Fibrosis of the organoid occurred following TGFβ stimulation and engraftment with myelofibrosis but not healthy donor-derived cells, validating this platform as a powerful tool for studies of malignant cells and their interactions within a human bone marrow-like milieu. This enabling technology is likely to accelerate the discovery and prioritization of novel targets for bone marrow disorders and blood cancers., Significance: We present a human bone marrow organoid that supports the growth of primary cells from patients with myeloid and lymphoid blood cancers. This model allows for mechanistic studies of blood cancers in the context of their microenvironment and provides a much-needed ex vivo tool for the prioritization of new therapeutics. See related commentary by Derecka and Crispino, p. 263. This article is highlighted in the In This Issue feature, p. 247., (©2022 The Authors; Published by the American Association for Cancer Research.)

Published

2023

38. Post-translational polymodification of β1-tubulin regulates motor protein localisation in platelet production and function.

Author

Khan AO, Slater A, Maclachlan A, Nicolson PLR, Pike JA, Reyat JS, Yule J, Stapley R, Rayes J, Thomas SG, and Morgan NV

Subjects

Blood Platelets metabolism, Humans, Megakaryocytes metabolism, Protein Processing, Post-Translational, Thrombopoiesis, Induced Pluripotent Stem Cells metabolism, Tubulin genetics, Tubulin metabolism

Abstract

In specialised cells, the expression of specific tubulin isoforms and their subsequent post-translational modifications drive and coordinate unique morphologies and behaviours. The mechanisms by which β1-tubulin, the platelet and megakaryocyte (MK) lineage restricted tubulin isoform, drives platelet production and function remains poorly understood. We investigated the roles of two key post-translational tubulin polymodifications (polyglutamylation and polyglycylation) on these processes using a cohort of thrombocytopenic patients, human induced pluripotent stem cell (iPSC) derived MKs, and healthy human donor platelets. We find distinct patterns of polymodification in MKs and platelets, mediated by the antagonistic activities of the cell specific expression of Tubulin Tyrosine Ligase Like (TTLLs) and Cytosolic Carboxypeptidase (CCP) enzymes. The resulting microtubule patterning spatially regulates motor proteins to drive proplatelet formation in megakaryocytes, and the cytoskeletal reorganisation required for thrombus formation. This work is the first to show a reversible system of polymodification by which different cell specific functions are achieved.

Published

2022

39. Tspan18 is a novel regulator of the Ca 2+ channel Orai1 and von Willebrand factor release in endothelial cells.

Author

Noy PJ, Gavin RL, Colombo D, Haining EJ, Reyat JS, Payne H, Thielmann I, Lokman AB, Neag G, Yang J, Lloyd T, Harrison N, Heath VL, Gardiner C, Whitworth KM, Robinson J, Koo CZ, Di Maio A, Harrison P, Lee SP, Michelangeli F, Kalia N, Rainger GE, Nieswandt B, Brill A, Watson SP, and Tomlinson MG

Subjects

Animals, B-Lymphocytes cytology, B-Lymphocytes drug effects, B-Lymphocytes metabolism, Chickens, Disease Models, Animal, Gene Expression Regulation, HEK293 Cells, HeLa Cells, Histamine pharmacology, Human Umbilical Vein Endothelial Cells cytology, Human Umbilical Vein Endothelial Cells drug effects, Human Umbilical Vein Endothelial Cells metabolism, Humans, Ion Transport drug effects, Jurkat Cells, Mice, Mice, Inbred C57BL, Mice, Knockout, Myocardial Reperfusion Injury metabolism, Myocardial Reperfusion Injury pathology, NFATC Transcription Factors genetics, NFATC Transcription Factors metabolism, ORAI1 Protein metabolism, Signal Transduction, Tetraspanins metabolism, Thrombin pharmacology, Venous Thrombosis metabolism, Venous Thrombosis pathology, von Willebrand Factor metabolism, Calcium metabolism, Myocardial Reperfusion Injury genetics, ORAI1 Protein genetics, Tetraspanins genetics, Venous Thrombosis genetics, von Willebrand Factor genetics

Abstract

Ca 2+ entry via Orai1 store-operated Ca 2+ channels in the plasma membrane is critical to cell function, and Orai1 loss causes severe immunodeficiency and developmental defects. The tetraspanins are a superfamily of transmembrane proteins that interact with specific 'partner proteins' and regulate their trafficking and clustering. The aim of this study was to functionally characterize tetraspanin Tspan18. We show that Tspan18 is expressed by endothelial cells at several-fold higher levels than most other cell types analyzed. Tspan18-knockdown primary human umbilical vein endothelial cells have 55-70% decreased Ca 2+ mobilization upon stimulation with the inflammatory mediators thrombin or histamine, similar to Orai1-knockdown. Tspan18 interacts with Orai1, and Orai1 cell surface localization is reduced by 70% in Tspan18-knockdown endothelial cells. Tspan18 overexpression in lymphocyte model cell lines induces 20-fold activation of Ca 2+ -responsive nuclear factor of activated T cell (NFAT) signaling, in an Orai1-dependent manner. Tspan18-knockout mice are viable. They lose on average 6-fold more blood in a tail-bleed assay. This is due to Tspan18 deficiency in non-hematopoietic cells, as assessed using chimeric mice. Tspan18-knockout mice have 60% reduced thrombus size in a deep vein thrombosis model, and 50% reduced platelet deposition in the microcirculation following myocardial ischemia-reperfusion injury. Histamine- or thrombin-induced von Willebrand factor release from endothelial cells is reduced by 90% following Tspan18-knockdown, and histamine-induced increase of plasma von Willebrand factor is reduced by 45% in Tspan18-knockout mice. These findings identify Tspan18 as a novel regulator of endothelial cell Orai1/Ca 2+ signaling and von Willebrand factor release in response to inflammatory stimuli., (Copyright© 2019 Ferrata Storti Foundation.)

Published

2019

40. Utilizing Lentiviral Gene Transfer in Primary Endothelial Cells to Assess Lymphocyte-Endothelial Interactions.

Author

Reyat JS, Tomlinson MG, and Noy PJ

Subjects

Cell Adhesion genetics, Cell Line, Endothelial Cells virology, HEK293 Cells, Human Umbilical Vein Endothelial Cells, Humans, Lymphocytes virology, Plasmids genetics, RNA, Small Interfering genetics, Transduction, Genetic methods, Transfection methods, Endothelial Cells physiology, Genetic Vectors genetics, Lentivirus genetics, Lymphocytes physiology

Abstract

A major impediment when studying primary human endothelial cell function is the resistance of these cells to gene transfer. Here we describe methods for transferring genes into primary endothelial cells prior to incorporation into a static adhesion assay to analyze the adhesion and migration of isolated lymphocytes. Human embryonic kidney (HEK)-293T (HEK-293 cells expressing the large T-antigen of simian virus 40) cells are initially transfected with plasmids containing the lentiviral packaging and envelope genes and the target sequence, such as a gene of interest or short hairpin loop RNA (shRNA). These cells produce lentivirus packaged with this target sequence and are used to transduce primary human umbilical vein endothelial cells (HUVECs). Human peripheral blood lymphocytes (PBLs) isolated from venous blood are co-incubated with lentivirally transduced cytokine-stimulated endothelial cells to assess lymphocyte adhesion in a static adhesion assay. Direct observations of lymphocyte adhesion and migration over a time course can also be made. In general, lentiviral transduction of primary endothelial cells provides an invaluable system to manipulate gene expression levels when studying the cellular adhesion dynamics that regulate leukocyte adhesion and extravasation.

Published

2017