Jonathan Sussman scite author profile

The importance of diversity is self-evident in medicine and medical research. Not only does diversity result in more impactful scientific work, but diverse teams of researchers and clinicians are necessary to address health disparities and improve the health of underserved communities. MD/PhD programs serve an important role in training physician-scientists, so it is critical to ensure that MD/PhD students represent diverse backgrounds and experiences. Groups who are underrepresented in medicine and the biomedical sciences include individuals from certain racial and ethnic backgrounds, individuals with disabilities, individuals from disadvantaged backgrounds, and women. However, underrepresented students are routinely discouraged from applying to MD/PhD programs due to a range of factors. These factors include the significant cost of applying, which can be prohibitive for many students, the paucity of diverse mentors who share common experiences, as well as applicants’ perceptions that there is inadequate support and inclusion from within MD/PhD programs. By providing advice to students who are underrepresented in medicine and describing steps programs can take to recruit and support minority applicants, we hope to encourage more students to consider the MD/PhD career path that will yield a more productive and equitable scientific and medical community.

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Rapid in vivo multiplexed editing (RIME) of the adult mouse liver

Katsuda

Cure

Sussman

et al. 2022

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Background & Aims: Assessing mammalian gene function in vivo has traditionally relied on manipulation of the mouse genome in embryonic stem cells or peri-zygotic embryos. These approaches are time consuming and require extensive breeding when simultaneous mutations in multiple genes is desired. The aim of this study is to introduce a Rapid In vivo Multiplexed Editing (RIME), and to provide a proof-of-concept of this system.Approach & Results: RIME, a system wherein CRISPR/Cas9 technology, paired with adenoassociated viruses (AAVs), permits the inactivation of one or more genes in the adult mouse liver.The method is quick, requiring as little as 1 month from conceptualization to knockout (KO), and highly efficient, enabling editing in >95% of target cells. To highlight its utility, we used this system to inactivate, alone or in combination, genes with functions spanning metabolism, mitosis, mitochondrial maintenance, and cell proliferation. Conclusion:RIME enables the rapid, efficient, and inexpensive analysis of multiple genes in the mouse liver in vivo..

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AKT but not MYC promotes reactive oxygen species-mediated cell death in oxidative culture

Zheng

Sussman

Jeon

et al. 2020

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Oncogenes can create metabolic vulnerabilities in cancer cells. We tested how AKT (herein referring to AKT1) and MYC affect the ability of cells to shift between respiration and glycolysis. Using immortalized mammary epithelial cells, we discovered that constitutively active AKT, but not MYC, induced cell death in galactose culture, where cells rely on oxidative phosphorylation for energy generation. However, the negative effects of AKT were temporary, and AKT-expressing cells recommenced growth after ∼15 days in galactose. To identify the mechanisms regulating AKT-mediated cell death, we used metabolomics and found that AKT-expressing cells that were dying in galactose culture had upregulated glutathione metabolism. Proteomic profiling revealed that AKT-expressing cells dying in galactose also upregulated nonsense-mediated mRNA decay, a marker of sensitivity to oxidative stress. We therefore measured levels of reactive oxygen species (ROS) and discovered that galactose-induced ROS exclusively in cells expressing AKT. Furthermore, ROS were required for galactoseinduced death of AKT-expressing cells. We then confirmed that galactose-induced ROS-mediated cell death in breast cancer cells with upregulated AKT signaling. These results demonstrate that AKT but not MYC restricts the flexibility of cancer cells to use oxidative phosphorylation. This article has an associated First Person interview with the first author of the paper.

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