Arun Sharma, PhD

The current focus of my work is modeling cardiovascular diseases and disorders in-vitro using a combination of iPSCs, CRISPR/Cas9, and microfluidic organ chips. I have utilized hiPSC-derived cardiomyocytes to model diseases such as viral myocarditis (and recently, infection of the heart by the COVID-19 virus SARS-CoV-2), examine the developmental mechanisms underlying congenital heart disease, and understand ways to alleviate the cardiac toxicity caused by cancer drugs.

I find my work rewarding because I can see the impact that stem cell biology can have towards understanding and alleviating cardiovascular disease, which is the leading cause of mortality in the world. And plus, it's also really fun to watch stem cell-derived human heart cells beat in a dish.

I was fortunate to be raised in an environment where science, learning, and diversity were valued, with my father being a physics professor at a historically black college in Alabama. I've tried my best to follow in his footsteps and be a passionate scientist, educator, and advocate for underrepresented groups in science. I also grew up in the Rocket City of Huntsville, Alabama, home to the Marshall Space Flight Center and a huge aerospace influence. As a result, and to be completely honest, astronomy was my first love in science, and during grade school, I was prepping for a career in that field. But when I heard about induced pluripotent stem cells in college, I was captivated. The ability to transform human tissue into stem cells and then into whatever cell type you're interested in...that seemed like science fiction to me! And I could immediately see the translational application. So iPSCs were the catalyst for my career in stem cell research.

I'm excited by the prospect of making in vitro biology as close as possible to the in vivo. There are so many incredible technologies that have become available that make genetic and cellular manipulation of stem cells cheap, easy, and accessible. I am incredibly excited by technologies that can intersect with stem cell biology, such as CRISPR and organ-chips, because they take in-vitro disease modeling to the next level. Genome editing allows for the creation of custom iPSC lines harboring any patient-specific mutation of interest, or more intricate fluorescent reporters that enable precise visual interrogation of protein function. And organ chips enable all-in-one systems that can further mature hiPSC-derived cells while harboring multiple cell types, a more realistic representation of what's actually going on the body. Better in vitro model systems is a great goal to strive for in this field.

Be passionate about the work that you choose to do as an academic trainee, but also be open to the opportunities that are just exploding outside of academia, around the world. We are living in a golden age in biotechnology, and stem cell biology is poised to make a translational impact when intersected appropriately with the technologies that I've mentioned.

The scientist who inspires me the most in my stem cell work is the late Yoshiki Sasai. The visionary scientist who, with his endless intuition, knowledge, and creativity, has transformed the stem cell field and led the way in establishing protocols for generating human pluripotent stem cell-derived organoids.

My mentor, Paola Arlotta, Professor at Harvard University, has greatly impacted my growth as a scientist and human being. In addition to being a spectacular scientist blazing new paths at the interface between developmental neurobiology and stem cell biology, Paola understands women scientists' struggle very well. She is a powerful role model for a woman scientist that never tires in her efforts to innovate, inspire change, and train others while also being a caring mother.

We just had our first child in 2020. He is a real spark of light in the dark times that we have all lived through recently. I spend my free time playing with him, watching him grow, and sleeping a few hours whenever possible!

I may have spoiled the answer earlier, but I absolutely love space, and always have since my childhood. This is also probably not a big secret to anyone who gets to know me. I had the opportunity in graduate school to send a sample of hiPSC-derived cardiomyocytes to the International Space Station to study the effects of microgravity on the human heart. To date, it's still coolest science project I've ever been a part of, and I'm constantly trying to figure out ways to integrate space science into my career as a biologist.

I've been an ISSCR member for many years now as a trainee, and what I value most is the community. I still mark the ISSCR annual meeting as my favorite conference to attend (hopefully in person soon), because of the amazing friendships and connections that I've made there. Plus, it always seems like there's a presentation every year that just takes your breath away. I love the stem cell community, and the way that the ISSCR has brought us all together.