Researchers create genetic map tied to kidney disease
The creation of the most complete map of more than 1,000 genes that influence kidney function could help experts diagnose and design targeted treatments for kidney disease.
Over 1,000 genes may serve as possible treatment targets for individuals with kidney disease, according to a new study published in Science from researchers at the Perelman School of Medicine. By creating the most complete and detailed genetic “map” of kidney function to date, the researchers have paved the way for more precise diagnosing of kidney disease, strategies to prevent it, and ways to treat it. In addition, they also created a “Kidney Disease Genetic Score card” that doctors can use with their patients to see what specific genes and variants may be most likely tied to a particular patient’s kidney disease.
“Kidney dysfunction is a major global health issue, and our findings shed new light on the specific genes and biological pathways that underlie disease risk,” says co-senior author Katalin Susztak, leader of the Penn/CHOP Kidney Innovation Center, and a professor of renal-electrolyte and hypertension at Penn. “Studying close to 1,000 human kidney samples and hundreds of thousands of kidney cells one by one was key to offering a clearer picture of what is going on ‘behind the scenes.’”
Among the findings, Susztak and her colleagues discovered that proximal tubule cells are one “hotbed” of disease-causing variants. These cells play various kidney-function roles including reabsorption of water and electrolytes, and secretion of different chemicals and compounds, so variants in these cells could lead to disease by impeding these essential functions.
“It’s critical to pinpoint which cells are truly relevant for disease,” says first author Hongbo Liu, a former postdoctoral fellow in the division of renal electrolyte and hypertension at Penn who is now an assistant professor at the University of Rochester. “By creating single-cell profiles of thousands of kidney cells, we were able to ‘zoom in’ and find how certain genetic variants disrupt the regulatory machinery in key kidney cell types.”
In addition to zooming in, researchers also looked at the bigger picture and saw some gene regions had two kinds of variants, variants in the coding or instructions to build essential bodily proteins, and variants that don’t code for a protein or change its sequence that can control how much of a protein is made.
“That was a key breakthrough from this study,” says Liu. “More than 600 genes had these two variant types, and having more than one variant type makes us strongly suspect the genes as causes of kidney disease. Among the genes we highlighted, genes with both variant types should be the first to be studied further.”
These findings set the stage for research that could directly impact the clinical care of people with or at risk of kidney disease. In fact, there are FDA-approved drugs, for other conditions, that are also known to influence some of the genes from this study. That means scientists should study whether repurposing or refining some already available drugs could potentially halt this disease’s progression or even repair the kidneys.
Griffin Pitt, right, works with two other student researchers to test the conductivity, total dissolved solids, salinity, and temperature of water below a sand dam in Kenya.
Griffin Pitt’s upbringing made her passionate about water access and pollution, and Penn has given her the opportunity to explore these issues back home in North Carolina and abroad.
Helping robots work together to explore the Moon and Mars
Penn Engineers, NASA, and five other universities tested robotic systems designed to help unmanned explorers cooperate in the dunes of White Sands, New Mexico, paving the way for Moon and Mars exploration.
From framework to actions: Provost John L. Jackson Jr. talks Penn Forward
In a Q&A, Provost John L. Jackson Jr. explains the relationship between the strategic framework In Principle and Practice and Penn Forward—a new University-wide process and action plan that will advance Penn forward for the next decade and beyond.
