Kyle Jewhurst scite author profile

KillerRed (KR) is a recently discovered fluorescent protein that, when activated with green light, releases reactive oxygen species (ROS) into the cytoplasm, triggering apoptosis in a KR-expressing cell. This property allows for the use of KR as a means of killing cells in an organism with great temporal and spatial specificity, while minimizing the nonspecific effects that can result from mechanical or chemical exposure damage techniques. Such optogenetic control of cell death, and the resulting ability to induce the targeted death of specific tissues, is invaluable for regeneration/repair studies—particularly in Xenopus laevis, where apoptosis plays a key role in regeneration and repair. We here describe a method by which membrane-bound KR, introduced to Xenopus embryos by mRNA microinjection, can be activated with green light to induce apoptosis in specific organs and tissues, with a focus on the developing eye and pronephric kidney.

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Beyond the Mammalian Heart: Fish and Amphibians as a Model for Cardiac Repair and Regeneration

Jewhurst¹,

McLaughlin²

2015

JDB

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The epidemic of heart disease, the leading cause of death worldwide, is made worse by the fact that the adult mammalian heart is especially poor at repair. Damage to the mammal heart—such as that caused by myocardial infarction—leads to scarring, resulting in cardiac dysfunction and heart failure. In contrast, the hearts of fish and urodele amphibians are capable of complete regeneration of cardiac tissue from multiple types of damage, with full restoration of functionality. In the last decades, research has revealed a wealth of information on how these animals are able to perform this remarkable feat, and non-mammalian models of heart repair have become a burgeoning new source of data on the morphological, cellular, and molecular processes necessary to heal cardiac damage. In this review we present the major findings from recent research on the underlying mechanisms of fish and amphibian heart regeneration. We also discuss the tools and techniques that have been developed to answer these important questions.

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Recovery of the Xenopus laevis heart from ROS‐induced stress utilizes conserved pathways of cardiac regeneration

Jewhurst

McLaughlin

2019

Dev Growth Differ

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Urodele amphibians and some fish are capable of regenerating up to a quarter of their heart tissue after cardiac injury. While many anuran amphibians like Xenopus laevis are not capable of such feats, they are able to repair lesser levels of cardiac damage, such as that caused by oxidative stress, to a far greater degree than mammals. Using an optogenetic stress induction model that utilizes the protein KillerRed, we have investigated the extent to which mechanisms of cardiac regeneration are conserved during the restoration of normal heart morphology post oxidative stress in X. laevis tadpoles. We focused particularly on the processes of cardiomyocyte proliferation and dedifferentiation, as well as the pathways that facilitate the regulation of these processes. The cardiac response to KillerRed‐induced injury in X. laevis tadpole hearts consists of a phase dominated by indicators of cardiac stress, followed by a repair‐like phase with characteristics similar to mechanisms of cardiac regeneration in urodeles and fish. In the latter phase, we found markers associated with partial dedifferentiation and cardiomyocyte proliferation in the injured tadpole heart, which, unlike in regenerating hearts, are not dependent on Notch or retinoic acid signaling. Ultimately, the X. laevis cardiac response to KillerRed‐induced oxidative stress shares characteristics with both mammalian and urodele/fish repair mechanisms, but is nonetheless a unique form of recovery, occupying an intermediate place on the spectrum of cardiac regenerative ability. An understanding of how Xenopus repairs cardiac damage can help bridge the gap between mammals and urodeles and contribute to new methods of treating heart disease.

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High flow cooled air can decrease brain temperature without injuring the snout or brain in Swine

Stonko

Richmond

Edwards

et al. 2023

Surgery in Practice and Science

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Kyle Jewhurst

Optogenetic Control of Apoptosis in Targeted Tissues of Xenopus laevis Embryos

Beyond the Mammalian Heart: Fish and Amphibians as a Model for Cardiac Repair and Regeneration

Recovery of the Xenopus laevis heart from ROS‐induced stress utilizes conserved pathways of cardiac regeneration

High flow cooled air can decrease brain temperature without injuring the snout or brain in Swine

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