Browsing by Author "Musah, Samira"
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Item Open Access A Personalized Glomerulus Chip Engineered from Stem Cell-Derived Epithelium and Vascular Endothelium(Micromachines) Roye, Yasmin; Bhattacharya, Rohan; Mou, Xingrui; Zhou, Yuhao; Burt, Morgan A; Musah, SamiraProgress in understanding kidney disease mechanisms and the development of targeted therapeutics have been limited by the lack of functional in vitro models that can closely recapitulate human physiological responses. Organ Chip (or organ-on-a-chip) microfluidic devices provide unique opportunities to overcome some of these challenges given their ability to model the structure and function of tissues and organs in vitro. Previously established organ chip models typically consist of heterogenous cell populations sourced from multiple donors, limiting their applications in patient-specific disease modeling and personalized medicine. In this study, we engineered a personalized glomerulus chip system reconstituted from human induced pluripotent stem (iPS) cell-derived vascular endothelial cells (ECs) and podocytes from a single patient. Our stem cell-derived kidney glomerulus chip successfully mimics the structure and some essential functions of the glomerular filtration barrier. We further modeled glomerular injury in our tissue chips by administering a clinically relevant dose of the chemotherapy drug Adriamycin. The drug disrupts the structural integrity of the endothelium and the podocyte tissue layers, leading to significant albuminuria as observed in patients with glomerulopathies. We anticipate that the personalized glomerulus chip model established in this report could help advance future studies of kidney disease mechanisms and the discovery of personalized therapies. Given the remarkable ability of human iPS cells to differentiate into almost any cell type, this work also provides a blueprint for the establishment of more personalized organ chip and ‘body-on-a-chip’ models in the future.Item Open Access A Stem Cell-Based Strategy for Modeling Human Kidney Disease and Discovering Novel Therapeutics(2022) Burt, Morgan AlexandraChronic kidney disease (CKD) is a degenerative disorder that affects millions of people worldwide and there are no targeted therapeutics. Given the global burden and increasing prevalence of CKD, the kidneys represent an attractive target for regenerative medicine. The most severe forms of CKD involve irreversible damage to kidney glomerular podocytes - the specialized epithelial cells that encase glomerular capillaries and regulate the removal of toxins and waste from blood. Therefore, the goal of this research proposal was to develop a novel strategy to protect or promote repair of injured human kidney tissues with an initial focus on glomerular podocytes. To achieve this goal, we leveraged advances in the directed differentiation of stem cells and in vitro disease modeling techniques to develop translationally relevant human models of podocyte injury. We used these models to identify potential biomarkers of early onset podocyte dysfunction, endogenous therapeutic targets, and reno-protective drug candidates, with a particular emphasis on studying pathways implicated in biomechanical signaling. Our studies revealed that the mechanosensitive proteins YAP, CTGF, and Cyr61 may be viable endogenous therapeutic targets, while CTGF and Cyr61 expression could serve as biomarkers of podocyte mechanical integrity and cell health. Additionally, our preliminary high-throughput drug screens have identified promising podocyte-protective drug candidates, which will be the subject of future studies.
Item Embargo Engineering Pluripotent Stem Cells to Uncover the Mechanisms of Human Kidney Diseases(2024) Bhattacharya, RohanChronic Kidney Disease (CKD) is a global health crisis for which successful targeted therapies remain elusive. In the United States, ~15% of the adult population suffers from CKD, costing ~$48 billion/year to treat <1% of the affected population. Clinical investigations have recently established that mild to moderate cardiovascular anomalies in humans enhance the risk for an abnormal Glomerular Filtration Rate. Although there is a growing recognition that Congenital Heart Disease (CHD) alters the predictive ability of risk factors involved in CKD, an in-depth understanding of the reasons behind this is still a mystery. From a developmental standpoint, the patterning of the human heart and kidneys is highly orchestrated and relies on shared molecular signaling pathways. Consequently, mutations in genes involved in organ patterning (e.g., SMAD2) can lead to a wide variety of congenital defects, notably within the heart and the kidneys. Here, I hypothesized that SMAD2 mutations may also cause abnormalities in kidney development and function. To address that, we introduced loss-of-function mutations in the SMAD2 gene in human induced pluripotent stem (iPS) cells, and by devising a method for directed differentiation towards major lineages, I illuminated mechanisms involved in cell-fate specifications at a defined developmental window. I discovered that loss of SMAD2 leads to biased lineage conversion and engages altered developmental gene regulatory networks to drive immature cell types through embryonic intermediates. Next, I modeled a kidney filtration barrier by developing a personalized kidney-chip, interfacing isogenic kidney podocytes and endothelial cells differentiated from the same iPS cells in an organ-on-a-chip device, and demonstrated that patients with SMAD2 mutations will develop early proteinuria. Building on my previous work, I realized that studying congenital kidney disease is crucial because if a child is born with impaired kidney function, their mortality rate is especially high. Recent GWAS studies reflect the challenge posed by the high aetiological and phenotypic heterogeneity of genetic Glomerulopathies, which makes it difficult to identify and treat disease subtypes on the basis of their molecular pathogenesis. Among those genes, patients with TRPC6 mutations are usually diagnosed with CKD in the first decade of their life. At this crossroad, I hypothesized that the pathogenicity of the TRPC6 might primarily occur in kidney podocytes – the specialized epithelium that encases kidney glomerular capillaries. By extending our podocyte differentiation strategy, I discovered that mutated TRPC6 disrupts protein trafficking of podocyte-lineage markers from the endoplasmic reticulum to the foot processes (FPs) due to defective endoplasmic reticulum (ER). Using high-resolution microscopy, I observed Podocin aggresomes near the nucleus. I also found that TRPC6-mutant podocytes fail to translocate Nephrin to the FPs. My work unraveled an unknown function of TRPC6, where its mutation stalls the proteostasis of Nephrin and Podocin from the ER to the FPs, further disturbing Nephrin localization to the FPs of the patients’ podocytes. I also found that TRPC6 mutations can disrupt autophagy in podocytes, forming protein aggresomes. Through a series of drug screenings and organ-on-a-chip experiments, I discovered that co-treatment with Sildenafil and Losartan can be used to increase proteostasis and repair ER while simultaneously reducing Podocin aggresomes, thereby favoring Nephrin-Podocin cuddling at the FPs. Using stem cell-based models and organ-on-a-chip technology, I illuminated the molecular mechanisms of genetic CKD. My work provides a viable platform for future therapeutic discovery.
Item Open Access Guided Differentiation of Mature Kidney Podocytes from Human Induced Pluripotent Stem Cells Under Chemically Defined Conditions(Journal of Visualized Experiments) Burt, Morgan; Bhattachaya, Rohan; Okafor, Arinze E; Musah, SamiraItem Open Access Harnessing developmental plasticity to pattern kidney organoidsMusah, Samira; Bhattacharya, Rohan; Bonner, MakenzieItem Open Access Introductions to the Community: Early-Career Researchers in the Time of COVID-19.(Cell stem cell, 2020-08) Shahbazi, Marta; Musah, Samira; Sharma, Ankur; Bajaj, Jeevisha; Donati, Giacomo; Zhang, WeiqiCOVID-19 has unfortunately halted lab work, conferences, and in-person networking, which is especially detrimental to researchers just starting their labs. Through social media and our reviewer networks, we met some early-career stem cell investigators impacted by the closures. Here, they introduce themselves and their research to our readers.Item Open Access SARS-CoV-2 Employ BSG/CD147 and ACE2 Receptors to Directly Infect Human Induced Pluripotent Stem Cell-Derived Kidney Podocytes(Frontiers in Cell and Developmental Biology) Kalejaiye, Titilola D; Bhattacharya, Rohan; Burt, Morgan A; Travieso, Tatianna; Okafor, Arinze E; Mou, Xingrui; Blasi, Maria; Musah, SamiraSevere acute respiratory syndrome coronavirus 2 (SARS-CoV-2) causes the Coronavirus disease 2019 (COVID-19), which has resulted in over 5.9 million deaths worldwide. While cells in the respiratory system are the initial target of SARS-CoV-2, there is mounting evidence that COVID-19 is a multi-organ disease. Still, the direct affinity of SARS-CoV-2 for cells in other organs such as the kidneys, which are often targeted in severe COVID-19, remains poorly understood. We employed a human induced pluripotent stem (iPS) cell-derived model to investigate the affinity of SARS-CoV-2 for kidney glomerular podocytes, and examined the expression of host factors for binding and processing of the virus. We studied cellular uptake of the live SARS-CoV-2 virus as well as a pseudotyped virus. Infection of podocytes with live SARS-CoV-2 or spike-pseudotyped lentiviral particles revealed cellular uptake even at low multiplicity of infection (MOI) of 0.01. We found that direct infection of human iPS cell-derived podocytes by SARS-CoV-2 virus can cause cell death and podocyte foot process retraction, a hallmark of podocytopathies and progressive glomerular diseases including collapsing glomerulopathy observed in patients with severe COVID-19 disease. We identified BSG/CD147 and ACE2 receptors as key mediators of spike binding activity in human iPS cell-derived podocytes. These results show that SARS-CoV-2 can infect kidney glomerular podocytes in vitro via multiple binding interactions and partners, which may underlie the high affinity of SARS-CoV-2 for kidney tissues. This stem cell-derived model is potentially useful for kidney-specific antiviral drug screening and mechanistic studies of COVID-19 organotropism.