drug screening Archives - Sanford Burnham Prebys
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High-throughput screening against a new target for Alzheimer’s drugs

AuthorJessica Moore
Date

March 27, 2017

More than 5 million people in the U.S. have Alzheimer’s, and by 2050 that number could rise as high as 16 million. There are currently no treatments that slow the advance of this cruel disease that slowly destroys a person’s memory and reason. Given the overwhelming need for drugs that prevent or limit the brain degeneration caused by Alzheimer’s, scientists are attacking the problem from all angles.

A new strategy for finding possible Alzheimer’s therapeutics has recently been developed by Nicholas Cosford, PhD, professor at Sanford Burnham Prebys Medical Discovery Institute (SBP), in collaboration with Varghese John, PhD, associate professor at UCLA. The high-throughput screening method, reported in Frontiers in Pharmacology, identified several compounds worthy of further investigation.

“We looked for inhibitors of a process that isn’t the standard target in drug screening for Alzheimer’s,” says Cosford. “This process—generation of a toxic peptide called APP (amyloid precursor protein) delta C31, or the 31 amino acids at the end of APP—may be especially important at early stages of Alzheimer’s, before neurons start to die.”

APP delta C31, which kills neurons, is made when APP is first cut by an enzyme called gamma secretase to form amyloid beta (the best-studied contributor to brain deterioration in Alzheimer’s) and the remaining portion of APP is then further cut by an intracellular caspase enzyme. Amyloid beta—also toxic—sticks together in clumps that clog up the spaces between brain cells. Most of the drugs that have recently been tested in Alzheimer’s patients are intended to eliminate amyloid beta or prevent it from being created, but so far none have been successful in clinical studies.

Cosford and John’s team found several compounds that inhibit production of APP delta C31. “A few of these compounds block signaling pathways not previously implicated in Alzheimer’s—so this is really a new avenue of research that we are pursuing,” adds Cosford.

Worryingly, generation of APP delta C31 is enhanced by statins, drugs that are widely used to lower blood cholesterol. In fact, statins were used in this study to bump up production of APP delta C31 and make reductions in levels of the peptide easier to detect. However, statins also protect against other damaging processes in Alzheimer’s.

“We speculate that whether statins are good or bad in the context of Alzheimer’s may depend on the stage of the disease,” notes Cosford.

“The next step for us is to test the most promising compounds in animal models of Alzheimer’s,” Cosford adds. “We also plan to use the same approach to screen another library of molecules to identify more potential drugs.”

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Consortium awarded $15 million to unravel bipolar disorder and schizophrenia

AuthorSusan Gammon
Date

August 31, 2016

Sanford Burnham Prebys Medical Discovery Institute (SBP), the Johns Hopkins University School of Medicine, the Salk Institute for Biological Studies, and the University of Michigan will embark on a $15.4 million effort to develop new systems for quickly screening libraries of drugs for potential effectiveness against schizophrenia and bipolar disorder, the National Institute of Mental Health (NIMH) has announced. The consortium, which includes two industry partners, will be led by Hongjun Song, PhD, of Johns Hopkins and Rusty Gage, PhD, of Salk.

Bipolar disorder affects more than 5 million Americans, and treatments often help only the depressive swings or the opposing manic swings, not both. And though schizophrenia is a devastating disease that affects about 3 million Americans and many more worldwide, scientists still know very little about its underlying causes — which cells in the brain are affected and how — and existing treatments target symptoms only.

With the recent advance of induced pluripotent stem cell (iPSC) technology, researchers are able to use donated cells, such as skin cells, from a patient and convert them into any other cell type, such as neurons. Generating human neurons in a dish that are genetically similar to patients offers researchers a potent tool for studying these diseases and developing much-needed new therapies.

“IPSCs are a powerful platform for studying the underlying mechanisms of disease,” says Gage, a professor of genetics at Salk. “Collaborations that bring together academic and industry partners, such as this one enabled by NIMH, will greatly facilitate the improvement of iPSC approaches for high-throughput diagnostic and drug discovery.”

A major aim of this collaboration is to improve the quality of iPSC technology, which has been limited in the past by a lack of standards in the field and inconsistent practices among different laboratories. “There has been a bottleneck in stem cell research,” says Gage, a professor of genetics at Salk. “Every lab uses different protocols and cells from different patients, so it’s really hard to compare results. This collaboration gathers the resources needed to create robust, reproducible tests that can be used to develop new drugs for mental health disorders.”

The teams will use iPSCs generated from more than 50 patients with schizophrenia or bipolar disorder so that a wide range of genetic differences is taken into account. By coaxing iPSCs to become four different types of brain cells, the teams will be able to see which types are most affected by specific genetic differences and when those effects may occur during development.

First the researchers must figure out, at the cellular level, what features characterize a given illness in a given brain cell type. To do that, they will assess the cells’ shapes, connections, energy use, division and other properties. They will then develop a way of measuring those characteristics that works on a large scale, such as recording the activity of cells under hundreds of different conditions simultaneously.

“SBP’s Conrad Prebys Center for Chemical Genomics will play a key role in this initiative,” says Anne Bang, PhD, a director at the Center. “We will be developing assays and testing prototype drug compounds to see if they induce the desired response in iPSC disease models from the consortium. Our goal is to establish assays suitable for high throughput drug screening, ultimately leading to discovery of drugs for preclinical and clinical studies.”

Once a reliable, scalable and reproducible test system has been developed, the industry partners will have the opportunity to use it to identify or develop drugs that might combat mental illness. “This exciting new research has great potential to expedite drug discovery by using human cells from individuals who suffer from these devastating illnesses. Starting with a deeper understanding of each disorder should enable the biopharmaceutical industry to design drug discovery strategies that are focused on molecular pathology,” says Husseini K. Manji, MD, F.R.C.P.C., global therapeutic area head of neuroscience for Janssen Research & Development.

The researchers also expect to develop a large body of data that will shed light on the molecular and genetic differences between bipolar disorder and schizophrenia. And, since other mental health disorders share some of the genetic variations found in schizophrenia and bipolar disorder, the data will likely inform the study of many illnesses.

The National Cooperative Reprogrammed Cell Research Groups program, which is funding the research, was introduced by the National Institute of Mental Health in 2013 to overcome barriers to collaboration by creating precompetitive agreements that harness the unique strengths of academic and industry research.

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Deeper dive into emerging cancer drugs’ actions

AuthorJessica Moore
Date

April 28, 2016

A major challenge in developing cancer drugs is finding ways to kill tumors without damaging healthy tissue. It’s tough—since cancer cells share the same cellular machinery as normal cells, scientists have to be mindful about the targets they choose. One way to balance these concerns is to target cellular processes—such as protein synthesis and degradation—that tumors frequently overuse to support their rapid and aberrant growth. Continue reading “Deeper dive into emerging cancer drugs’ actions”