Your search keyword '"Deok Ho Kim"' showing total 3 results

1. Spaceflight-induced contractile and mitochondrial dysfunction in an automated heart-on-a-chip platform.

Author

Mair, Devin B., Tsui, Jonathan H., Ty Higashi, Koenig, Paul, Zhipeng Dong, Chen, Jeffrey F., Meir, Jessica U., Smith, Alec S. T., Lee, Peter H. U., Eun Hyun Ahn, Countryman, Stefanie, Sniadecki, Nathan J., and Deok-Ho Kim

Subjects

HUMAN space flight, RNA sequencing, OXIDATIVE stress, SPACE stations, SPACE flight

Abstract

With current plans for manned missions to Mars and beyond, the need to better understand, prevent, and counteract the harmful effects of long-duration spaceflight on the body is becoming increasingly important. In this study, an automated heart-on-a-chip platform was flown to the International Space Station on a 1-mo mission during which contractile cardiac function was monitored in real-time. Upon return to Earth, engineered human heart tissues (EHTs) were further analyzed with ultrastructural imaging and RNA sequencing to investigate the impact of prolonged microgravity on cardiomyocyte function and health. Spaceflight EHTs exhibited significantly reduced twitch forces, increased incidences of arrhythmias, and increased signs of sarcomere disruption and mitochondrial damage. Transcriptomic analyses showed an up-regulation of genes and pathways associated with metabolic disorders, heart failure, oxidative stress, and inflammation, while genes related to contractility and calcium signaling showed significant down-regulation. Finally, in silico modeling revealed a potential link between oxidative stress and mitochondrial dysfunction that corresponded with RNA sequencing results. This represents an in vitro model to faithfully reproduce the adverse effects of spaceflight on three-dimensional (3D)-engineered heart tissue. [ABSTRACT FROM AUTHOR]

Published

2024

2. Mechanochemical feedback underlies coexistence of qualitatively distinct cell polarity patterns within diverse cell populations.

Author

JinSeok Park, Holmes, William R., Sung Hoon Lee, Hong-Nam Kim, Deok-Ho Kim, Moon Kyu Kwak, Chiaochun Joanne Wang, Edelstein-Keshet, Leah, and Levchenko, Andre

Subjects

CELL polarity, MECHANICAL chemistry, CELL populations, CELL migration, EXTRACELLULAR matrix

Abstract

Cell polarization and directional cell migration can display random, persistent, and oscillatory dynamic patterns. However, it is not clear whether these polarity patterns can be explained by the same underlying regulatory mechanism. Here, we show that random, persistent, and oscillatory migration accompanied by polarization can simultaneously occur in populations of melanoma cells derived from tumors with different degrees of aggressiveness. We demonstrate that all of these patterns and the probabilities of their occurrence are quantitatively accounted for by a simple mechanism involving a spatially distributed, mechanochemical feedback coupling the dynamically changing extracellular matrix (ECM)-cell contacts to the activation of signaling downstream of the Rho-family small GTPases. This mechanism is supported by a predictive mathematical model and extensive experimental validation, and can explain previously reported results for diverse cell types. In melanoma, this mechanism also accounts for the effects of genetic and environmental perturbations, including mutations linked to invasive cell spread. The resulting mechanistic understanding of cell polarity quantitatively captures the relationship between population variability and phenotypic plasticity, with the potential to account for a wide variety of cell migration states in diverse pathological and physiological conditions. [ABSTRACT FROM AUTHOR]

Published

2017

3. Engineering neuronal growth cones to promote axon regeneration over inhibitory molecules.

Author

Eun-Mi Hur, In Hong Yang, Deok-Ho Kim, Byun, Justin, Wen-Lin Xu, Nicovich, Philip R., Cheong, Raymond, Levchenko, Andre, Thakor, Nitish, and Feng-Quan Zhou

Subjects

NEURON development, CENTRAL nervous system, AXONS, AXONAL transport, INHIBITION (Chemistry)

Abstract

Neurons in the central nervous system (CNS) fail to regenerate axons after injuries due to the diminished intrinsic axon growth capacity of mature neurons and the hostile extrinsic environment composed of a milieu of inhibitory factors. Recent studies revealed that targeting a particular group of extracellular inhibitory factors is insufficient to trigger long-distance axon regeneration. Instead of antagonizing the growing list of impediments, tackling a common target that mediates axon growth inhibition offers an alternative strategy to promote axon regeneration. Neuronal growth cone, the machinery that derives axon extension, is the final converging target of most, if not all, growth impediments in the CNS. In this study, we aim to promote axon growth by directly targeting the growth cone. Here we report that pharmacological inhibition or genetic silencing of nonmuscle myosin II (NMII) markedly accelerates axon growth over permissive and nonpermissive substrates, including major CNS inhibitors such as chondroitin sulfate proteoglycans and myelin-associated inhibitors. We find that NMII inhibition leads to the reorganization of both actin and microtubules (MTs) in the growth cone, resulting in MT reorganization that allows rapid axon extension over inhibitory substrates. In addition to enhancing axon extension, we show that local blockade of NMII activity in axons is sufficient to trigger axons to grow across the permissive-inhibitory border. Together, our study proposes NMII and growth cone cytoskeletal components as effective targets for promoting axon regeneration. [ABSTRACT FROM AUTHOR]

Published

2011