Search Labs

We have two major areas of research: respiratory viruses and newly emerging pathogens. 

The primary research focus of the Karner lab is to create and utilize novel mouse genetic models to study the role of cellular metabolism during skeletal development and disease. 

Research in the Kim lab is focused on developing computer algorithms and statistical methods that enable accurate and rapid analysis of biological data, in particular sequencing data.

Kim (Jaehyup) lab studies the mechanism of immune regulatory receptor regulation with a special focus on ligand identification and modulation.

The James Kim Lab examines the communication between epithelia and stroma through the lens of fundamental developmental pathways such as Hedgehog, Wnt, and Notch pathways.

Kitamura Lab's research aims to provide a biophysically-based mechanistic understanding of the neural process for learning and memory in the mouse brain.

The ultimate goal of the Kittler Lab's research is to develop novel therapeutic approaches that target transcription factors, which play important roles in common solid tumors (brain, breast, lung and prostate cancer) and could therefore have translational potential.

We are investigating how protein homeostasis (the maturation and turnover of enzymes) interacts with lipid homeostasis.

We are broadly interested in understanding how resident intestinal microorganisms (particularly bacteria and fungi and collectively referred to as the gut microbiome) influence the health of human cancer and stem cell transplant patients.

The Kohler research group is committed to developing and implementing new tools optimized for the study of glycosylated molecules.

Kong lab aims to harness the cutting-edge technologies in human genetics and genomics, immunology, and molecular biology to better understand the pathogenesis of gastrointestinal inflammation.

We are taking a comparative genomics approach to identify genes that have been modified in the human brain.

Our research focuses on two main areas: hyperpolarized 13C, 15N, 89Y and 107, 109Ag compounds, and conventional lanthanide-based T1 shortening and paraCEST imaging agents.

The goal of the Krämer laboratory is to understand the molecular mechanisms that regulate responses to diverse cellular stresses.

The Kraus Lab is interested in the basic mechanisms of nuclear signaling and gene regulation by small molecules and how these signaling pathways relate to human physiology and disease states.