Robert Liddington Archives - Sanford Burnham Prebys

Tag: Robert Liddington

Institute News

Drug reverses type 2 diabetes in mice

AuthorJessica Moore
Date

March 30, 2017

insulin syringes

Type 2 diabetes is a massive public health challenge. About eight percent of the world’s adult population has it, and the complications are serious—increased risk of heart attack and stroke, kidney problems, hearing and vision loss and painful nerve damage. Managing blood sugar with diet, routine monitoring and insulin helps prevent these issues, but that takes more time and effort than many patients have.

A new experimental drug developed with the help of scientists at Sanford Burnham Prebys Medical Discovery Institute (SBP) may spell the end of insulin reliance. A study published in Nature Chemical Biology shows that the compound, which can be given as a pill, restores blood sugar control in a mouse model of diet-induced diabetes.

“By targeting an enzyme that controls insulin receptor signaling, we found a way to recover cells’ ability to respond to insulin,” says Anthony Pinkerton, PhD, director of medicinal chemistry at SBP’s Conrad Prebys Center for Chemical Genomics and a contributor to the research. “This could lead to a new treatment approach for type 2 diabetes.”

The candidate drug blocks an enzyme called low molecular weight protein tyrosine phosphatase (LMPTP), which regulates the insulin receptor. Human genetic studies suggested that individuals with lower LMPTP activity were protected from type 2 diabetes, but the mechanism of protection remained unclear.

The new investigation, led by Nunzio Bottini, MD, PhD, professor at UC San Diego, found that LMPTP has direct actions on the insulin receptor that reduce its signaling activity, making cells less sensitive to insulin. Turning off the LMPTP gene prevented mice from becoming diabetic when they were fed a high-fat diet, so the research team screened compounds to identify LMPTP inhibitors. Chemical improvements to the best compound gave a potent, orally available drug that improved glucose control in mice with type 2 diabetes.

“This is still a few steps away from clinical trials,” says Robert Liddington, PhD, professor at SBP who also collaborated on the study. “No adverse events were noted in mice who received the drug for a month, and the compound is highly selective for LMPTP, but considerably more optimization and testing has to be done to show that it’s safe when taken long-term and is likely to work in humans.”

Institute News

The search for new anthrax treatments isn’t over

AuthorJessica Moore
Date

October 5, 2016

Bacillus anthracis, the bacterium that causes anthrax

A bioterror attack using virulent anthrax would be nearly as deadly today as it was in 2001, when anthrax spores sent through the mail killed five people. Even with aggressive treatment, only about half of those who breathe anthrax spores survive because the bacterium rapidly produces huge amounts of deadly toxins.

To inform future therapies, the lab of Robert Liddington, PhD, professor in the Bioinformatics and Structural Biology Program, examined how toxins enter cells. Their new study, published in the Journal of General Physiology, shows that the bacterial toxin is remarkably efficient at getting across cell membranes.

“When we pushed the system to its limit, we found that the pore formed by the toxin is incredibly robust,” said Liddington. “It acts like a ‘conveyer belt,’ continuously feeding toxic enzymes across the membrane.”

During anthrax infections, the bacterium Bacillus anthracis secretes a three-unit toxin: two enzymes named lethal factor (LF) and edema factor (EF) and a third protein called protective antigen (PA). After they’re engulfed by cells, they’re contained within membrane-bound acid baths (vesicles) that they have to escape to avoid being broken down. To do that, the PA proteins link together to form a pore across the membrane, allowing LF and EF to be transported into the interior of the cell. There, they wreck signals that would alert other cells to the presence of the bacteria, eventually causing the cell to die.

Liddington’s lab teamed with Isabelle Rouiller, PhD, and her group at McGill University, using a cutting-edge high-resolution imaging technique called cryo-electron microscopy to build a three-dimensional map of the “pre-pore” complex. The map showed seven PA proteins surrounding a narrow pore, with three LF molecules perched at the rim, ready to be moved across. As well as binding to the PA subunits, each LF molecule also bound to its neighbor.

The team hopes that these new findings will aid the development of better treatments for anthrax infection. “By identifying new interactions between different parts of the toxin, our findings suggest new ways to thwart toxin entry,” explained Liddington. “That might allow us to design new antitoxins that work better than or in combination with the two that have been approved by the FDA.”

This post is based in part on a press release from the Journal of General Physiology.

The paper is available online here.