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We do this in the Department of Biochemistry and Molecular Biophysics at Washington University School of Medicine using a combination of physics-based simulations, computational biology, and experimental approaches.
TL/DR: A large fraction of proteins and protein-regions are classified as ‘intrinsically disordered’. These regions have historically been hard to study, but play key roles in wide variety of cellular function. Furthermore, these regions are strongly implicated in many diseases. In the Holehouse lab, we integrate a range of computational approaches (simulations, bioinformatics, systems biology) with experimental data to uncover how intrinsically disordered regions mediate cellular function, with a particular interest in biological phase separation.
安卓软件-免费软件站-快连vρn加速器-KAGOOrouter7天试用
We often think of proteins as tiny well-defined machines that mediate biological function in a way that is inherently linked to their 3D structure. However, a large fraction of protein regions are referred to as ‘intrinsically disordered’ - regions that don’t fold into a well-defined 3D shape, but instead exist in an ensemble of conformations.
These intrinsically disordered regions (IDRs) play key roles in a wide variety of cellular functions, including gene expression, signal transduction, and the stress response. They are also frequently mutated in diseases, from neurodegenerative conditions to cancer. Despite their cellular importance and clinical significance, we lack effective generalizable ways to predict and understand function from sequence.
Our lab is focussed on combining bioinformatics with statistical physics and quantitative cell biology to uncover the general principles that underlie how function is encoded into disordered proteins. We do this by performing simulations and/or sequence-based analysis, and then testing predictions that come from these computational approaches experimentally. Of particular interest is how IDRs can act in a regulatory capacity, how and why IDRs evolve, and how intracellular phase transitions contribute to cellular fitness and function
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A major goal of our group is to create an environment that is safe and supportive for lab members from all communities and backgrounds. Diversity in experience, perspective, and culture is a major asset, and one that can only be realized through an inclusive environment that promotes and supports the success of scientists from groups that are traditionally underrepresented in science, technology, engineering and mathematics (STEM). This support extends beyond our physical lab space to all members of the broader scientific community, and trainees from groups underrepresented in STEM should feel welcome to contact Alex or another member of the lab for support and advice.