This research develops engineered ultrasonic reporters that allow ultrasound imaging to detect molecular activity rather than only anatomical structure. By targeting biological signals associated with cancer progression and cellular communication, the work aims to distinguish aggressive disease earlier and improve precision medicine through real-time, noninvasive monitoring of underlying cellular behavior.

This research investigates how SUMO protein labeling regulates DNA repair after damage caused by sunlight and other stresses. Using yeast as a model organism, the study shows that SUMO helps recruit and remove repair proteins at damaged DNA sites. Understanding these signaling mechanisms may improve cancer prevention and treatment strategies.

This research investigates feronia, a plant protein essential for heat adaptation. By studying how feronia regulates auxin signaling and plant growth under temperature stress, the work aims to uncover mechanisms that could support the development of heat-resilient crops, improving agricultural productivity and food security in a warming global climate.

Intestinal cells protect us from harmful bacteria by forming a physical barrier and raising immune danger signals when needed. This research reveals a nuclear “knight” molecule that suppresses unnecessary immune activation during metabolic stress, helping maintain intestinal health and preventing excessive inflammation.