Your search keyword '"Shiva Razavi"' showing total 6 results

1. Actuator, a Listeria-Inspired Molecular Tool for Manipulation of Intracellular Organizations

Author

Elmer Rho, Hideaki Matsubayashi, Hideki Nakamura, Shiva Razavi, Satoshi Watanabe, Takanari Inoue, and Daqi Deng

Subjects

symbols.namesake, Stress granule, Chemistry, Regulator, Biophysics, symbols, Mitochondrion, Golgi apparatus, Protein Dimerization, Actin, Function (biology), Intracellular

Abstract

At all levels in biology, form and function are closely interdependent. Mitochondria have particularly attracted attention since their altered morphology is often observed under pathophysiological conditions including heart failure and Alzheimer’s disease. Despite the physiological significance, assessing the direct causal relationship between mitochondrial morphology and function has been out of reach, primarily due to limitations of the existing experimental technologies such as optical tweezers and atomic force microscopy in manipulating the morphology of this submicron length-scale entity deep inside living cells. By engineering an actin regulator, ActA, derived from Listeria monocytogenes , and coupling it with protein dimerization schemes, we first established molecular tools collectively termed ActuAtor that can trigger actin polymerization to exert constrictive forces at subcellular locations of choice in a rapidly inducible manner. The ActuAtor-mediated forces drove striking movement and/or deformation of target intracellular structures including mitochondria, Golgi apparatus, and nucleus, as well as non-membrane-bound biomolecular condensates such as stress granules. We then implemented ActuAtor in functional assays of mitochondria, uncovering that fragmented mitochondria are more susceptible to degradation, while none of the other essential functions tested like ATP synthesis are morphology dependent. The modular and genetically-encoded features of ActuAtor should enable its applications in de novo studies of the interplay between form and function at various intracellular and subcellular spaces.

Published

2021

2. ActuAtor, a molecular tool for generating force in living cells: Controlled deformation of intracellular structures

Author

Hideaki Matsubayashi, Shiva Razavi, Daqi Deng, Takanari Inoue, Hideki Nakamura, and Elmer Rho

Subjects

symbols.namesake, Mechanobiology, Chemistry, Organelle, Biophysics, symbols, Golgi apparatus, Actuator, Protein Dimerization, Actin, Intracellular, Actin nucleation

Abstract

SummaryMechanical force underlies fundamental cell functions such as division, migration and differentiation. While physical probes and devices revealed cellular mechano-responses, how force is translated inside cells to exert output functions remains largely unknown, due to the limited techniques to manipulate force intracellularly. By engineering an ActA protein, an actin nucleation promoting factor derived fromListeria monocytogenes, and implementing this in protein dimerization paradigms, we developed a molecular tool termed ActuAtor, with which actin polymerization can be triggered at intended subcellular locations to generate constrictive force in a rapidly inducible manner. The ActuAtor operation led to striking deformation of target intracellular structures including mitochondria, Golgi apparatus, nucleus, and non-membrane-bound RNA granules. Based on functional analysis before and after organelle deformation, we found the form-function relationship of mitochondria to be generally marginal. The modular design and genetically-encoded nature enable wide applications of ActuAtor for studies of intracellular mechanobiology processes.

Published

2020

3. Intracellular production of hydrogels and synthetic RNA granules by multivalent molecular interactions

Author

Brian Huang, Shiva Razavi, Albert A. Lee, Shigeki Watanabe, Robert DeRose, Allison Suarez, William Hong, Elmer Rho, Hideki Nakamura, Takanari Inoue, Sandra B. Gabelli, Diana Bobb, John Goutsias, Yu Chun Lin, Makoto Tanigawa, and Ali Sobhi Afshar

Subjects

0301 basic medicine, Polymers, Biocompatible Materials, macromolecular substances, 010402 general chemistry, complex mixtures, 01 natural sciences, Article, 03 medical and health sciences, Chlorocebus aethiops, Animals, General Materials Science, RNA metabolism, Molecular interactions, COS cells, Extramural, Chemistry, Mechanical Engineering, technology, industry, and agriculture, RNA, Hydrogels, General Chemistry, Condensed Matter Physics, Biocompatible material, Molecular biology, 0104 chemical sciences, 030104 developmental biology, Mechanics of Materials, COS Cells, Self-healing hydrogels, Biophysics, Intracellular

Abstract

Non-membrane bound, hydrogel-like entities, such as RNA granules, nucleate essential cellular functions through their unique physico-chemical properties. However, these intracellular hydrogels have not been as extensively studied as their extracellular counterparts, primarily due to technical challenges in probing these materials in situ. Here, by taking advantage of a chemically inducible dimerization paradigm, we developed iPOLYMER, a strategy for rapid induction of protein-based hydrogels inside living cells. A series of biochemical and biophysical characterizations, in conjunction with computational modeling, revealed that the polymer network formed in the cytosol resembles a physiological hydrogel-like entity that behaves as a size-dependent molecular sieve. We studied several properties of the gel and functionalized it with RNA binding motifs that sequester polyadenine-containing nucleotides to synthetically mimic RNA granules. Therefore, we here demonstrate that iPOLYMER presents a unique and powerful approach to synthetically reconstitute hydrogel-like structures including RNA granules in intact cells.

Published

2017

4. Very Fast CRISPR on Demand

Author

Bin Wu, Roger S. Zou, Shiva Razavi, Taekjip Ha, Shuaixin He, Yuta Nihongaki, and Yang Liu

Subjects

Computer science, On demand, Biophysics, CRISPR, Computational biology

Published

2020

5. Intracellular production of hydrogels and synthetic RNA granules by multivalent enhancers

Author

Elmer Rho, Brian Huang, Shiva Razavi, Shigeki Watanabe, Yu Chun Lin, Makoto Tanigawa, Robert DeRose, Ali Sobhi Afshar, William Hong, Takanari Inoue, Allison Suarez, Diana Bobb, Albert A. Lee, John Goutsias, Sandra B. Gabelli, and Hideki Nakamura

Subjects

chemistry.chemical_classification, technology, industry, and agriculture, RNA, macromolecular substances, Biology, Synthetic biology, Cytosol, chemistry, Biochemistry, Self-healing hydrogels, Biophysics, Extracellular, Nucleotide, Enhancer, Intracellular

Abstract

Non-membrane bound, hydrogel-like entities, such as RNA granules, nucleate essential cellular functions through their unique physico-chemical properties. However, these intracellular hydrogels have not been as extensively studied as their extracellular counterparts, primarily due to technical challenges in probing these materialsin situ.Here, by taking advantage of a chemically inducible dimerization paradigm, we developed iPOLYMER, a strategy for rapid induction of protein-based hydrogels inside living cells. A series of biochemical and biophysical characterizations, in conjunction with computational modeling, revealed that the polymer network formed in the cytosol resembles a physiological hydrogel-like entity that behaves as a size-dependent molecular sieve. We studied several properties of the gel and functionalized it with RNA binding motifs that sequester polyadenine-containing nucleotides to synthetically mimic RNA granules. Therefore, we here demonstrate that iPOLYMER presents a unique and powerful approach to synthetically reconstitute hydrogel-like structures including RNA granules in intact cells.

Published

2017

6. Conformational Switching Mechanisms Underlying the Activation of Stromal Interaction Molecule 1 (STIM1)

Author

Sam Seymour, Anjana Rao, Yubin Zhou, Paul Meraner, Patrick G. Hogan, and Shiva Razavi

Subjects

inorganic chemicals, Conformational change, Voltage-dependent calcium channel, Cytoplasm, Chemistry, Endoplasmic reticulum, T-cell receptor, Biophysics, STIM1, STIM2, Receptor, Cell biology

Abstract

Physiological Ca2+ signalling in T lymphocytes and various other mammalian cells depends on the STIM-ORAI pathway of store-operated Ca2+ entry. STIM1 and STIM2 are Ca2+ sensors located in the endoplasmic reticulum (ER) membrane, with ER-luminal domains that monitor cellular Ca2+ stores and cytoplasmic domains that gate ORAI channels in the plasma membrane. Physiological stimulation_ through the T cell receptor, the Fce receptor of mast cells, or various G protein-coupled receptors in other cells_ initiates a sequence of ER Ca2+ depletion, dimerization or oligomerization of the STIM luminal domain, and targeting of STIM to ER-plasma membrane junctions. STIM at ER-plasma membrane junctions recruits and directly activates the ORAI channel. Here we demonstrate that dimerization of STIM1 ER-luminal domains triggered by dissociation of Ca2+ initiates an extensive conformational change in STIM1 cytoplasmic domains that involves apposition of the predicted coiled-coil 1 (CC1) regions, physical extension of the STIM1 cytoplasmic domain, and increased exposure of the STIM1 polybasic C-terminal tail. Together these conformational changes promote interaction of the STIM1 C-terminal region with the plasma membrane, the first essential step for communication of STIM1 with ORAI calcium channels in the plasma membrane.

Published

2013