Wednesday, April 10, 2013

CHAPEL HILL, N.C. – Researchers at the University of North Carolina at Chapel Hill School of Medicine have “rationally rewired” some of the cell’s smallest components to create proteins that can be switched on or off by command. These “protein switches” can be used to interrogate the inner workings of each cell, helping scientists uncover the molecular mechanisms of human health and disease.

In the first application of this approach, the UNC researchers showed how a protein called Src kinase influences the way cells extend and move, a previously unknown role that is consistent with the protein’s ties to tumor progression and metastasis.

Nikolay Dokholyan, PhD

The research was published online ahead of print in the Proceedings of the National Academy of Sciences. In the study, Dokholyan created a “switch” that would make a protein wobbly and unable to do its job unless it was flipped “on” by a drug called rapamycin, which would stabilize the protein and let it perform its function.

The approach is a simpler and more reliable version of a protein engineering system pioneered three years ago by Dokholyan and Klaus Hahn, professor of pharmacology at UNC, called rapamycin regulated or RapR.  In the old approach, the switching mechanism depended on two proteins and the drug. The first protein – the one the researchers wanted to study – was given the RapR modification and put in cells in tissue culture. The second protein was placed in the cells as well, but simply floated around until the addition of drug caused it to latch on to the modification in the first protein and turn it on. The problem with the approach was that some cells would have a lot of the first protein and less of the second, or vice versa.

“It became the Achilles heel of the technique, because there was variability in the results due to the different ratios between the proteins,” said Hahn. “What Dokholyan was able to do, which was extremely challenging from a protein engineering standpoint, was to combine the two parts into one.” Dokholyan and Hahn are members of the UNC Lineberger Comprehensive Cancer Center.

Dokholyan and his colleagues took the two proteins and broke them apart into their individual components, structures called alpha helices and beta sheets. They then rewired them together to make a whole new protein where the parts could interact with each other. When researchers compared this system, called uniRapR, with the previous approach, they found the new one gave cleaner, more reliable and more consistent results.

They then applied the technique to study Src kinase, a protein involved in the metastasis or spread of tumor cells. Scientists had postulated that Src kinase plays a role in cell motility, but previous methods have not allowed them to isolate its activity from other similar proteins.

Working both in cultured human cells and in the model organism zebrafish, the researchers showed that turning on Src causes the cell to extend its edges as part of cell movement. Now that they have dissected the role of one protein, the researchers plan to look at a variety of other kinases to understand their roles in the development, progression, and spread of cancer.

The research was funded in by the National Institutes of Health, the National Institute of Environmental Health Sciences, and the National Cancer Institute. Study co-authors from UNC were Onur Dagliyan; David Shirvanyants, PhD; Andrei V. Karginov, PhD; Feng Deng, PhD; Lanette Fee; and Srinivas N. Chandrasekaran. Co-authors from the University of Wisconsin, Madison, were Christina M. Freisinger, Gromoslaw A. Smolen, and Anna Huttenlocher.

CELEBRATING GRADUATE RESEARCH PAST AND PRESENT

THURSDAY, MAY 16, 2013

10:30 AM - 4:00 PM

G202 MBRB

Gerald R. Crabtree, MD is a HHMI Investigator and Professor of Pathology and Developmental Biology at Stanford University, School of Medicine. He received is MD from Temple University and began his research career at Dartmouth and the NIH. He has been a faculty member at Stanford since 1985 and with HHMI since 1987. Dr. Crabtree was inducted into the National Academy of Science in 1997 and is a Fellow of the American Association for the Advancement of Science.

Dr. Crabtree's laboratory studies the interaction between the signaling pathways and genetic circuits regulating embryonic development. To modulate and explore these circuits, his lab also designs and synthesizes small molecules that rapidly and reversibly activate or inhibit the products of specific genes critical to these circuits, thereby allowing precise temporal analysis of their functions. Learn more

Since coming to UNC, Dr. Kuhlman has earned distinction as a Keck Foundation Distinguished Young Scholar in Medical Research (2005-2010), Searle Scholar (2004-2007), Beckman Young Investigator (2004-2007), and Alfred P. Sloan Fellow (2004) just to name a few.

The research in the Kuhlman lab involves the development and application of computational methods for protein design. Currently they are focusing on a variety of design goals including the creation of novel protein-protein interactions, protein structures and light activatable protein switches. Central to all of their projects is the Rosetta program for protein modeling. In collaboration with developers from a variety of universities, they are continually adding new features to Rosetta as well as testing it on new problems. Please visit their group site to learn more.

ACS Postdoctoral Fellowships provide up to three years of initial funding to support training of researchers interested in an independent career in cancer research (including basic, preclinical, clinical, cancer control, psychosocial, behavioral, epidemiology, health services and health policy research). During the second or third year of the award, ACS Postdoctoral Fellows are invited to attend a Fellows Symposium to present their work, meet with senior leaders in cancer research, and develop additional professional skills important in their transition to independent research careers.

Dr. Rothbart is currently a postdoctoral fellow training in the lab of Dr. Brian Strahl, associate professor of Biochemistry and Biophysics. Dr. Rothbart's research focuses on the regulation of chromatin-templated biological processes by the 'histone code'. Particularly, he is interested in the biochemistry and biology of a chromatin-interacting protein, UHRF1, as a bridging molecule at the interface of histone post-translational modifications and DNA methylation.

For this project titled "Deciphering histone and protein codes in response to DNA damage", Dr. Rothbart aims to advance our understanding of the role of post-translational modification 'codes' on histones and the tumor suppressor protein p53 in DNA damage signaling and repair.

Other recent news on Dr. Rothbart

“However, protein methylation is challenging to study,” said Waters, “largely because we lack the right tools to study it. The goal of this grant is to help us develop the tools to better characterize this phenomenon – how many proteins are methylated in different cells, what happens when protein methylation goes awry, and how this influences other chemical interactions that regulate gene expression.”

The new tools will provide researchers with a map of these chemical tags and the patterns with which these tags decorate the surface of different proteins. A visual and/or chemical representation of these patterns may provide breakthrough insights into why certain cells become diseased while others stay healthy. Furthermore, Waters and her co-principal investigators, Drs. Brian D. Strahl and Xian Chen, associate professors in the department of biochemistry and biophysics in UNC’s School of Medicine, plan to use these new tools to pinpoint precisely which molecular interactions within cells break down and lead to disease. This could open the door to the development of highly specific and targeted therapies.

“Mapping differences in the protein methylation process in normal and diseased cells may provide key information for the development of future treatments,” said Waters.

Drs. Chen and Strahl are also members of the UNC Lineberger Comprehensive Cancer Center.

College of Arts and Sciences contact: Dee Reid, (919) 843-6339, deereid@unc.edu
UNC News Services contact: Thania Benios, (919) 962-8596, thania_benios@unc.edu

Dr. Zhang, a member of the UNC Lineberger Comprehensive Cancer Center, will be provided with $150,000 over two years to support research into understanding the biogenesis of an essential microRNA in cardiovascular development and disease.

Cardiovascular disease is the leading cause of death in the world, and congenital heart disease is the leading cause of infant death related to birth defects. The long-term goal of the research is to develop microRNA-based therapies for the treatment of cardiovascular disease.

Dr. Zhang obtained his Ph.D. degree in chemistry from the University of Michigan, and received postdoctoral training in UCLA as a Baltimore Family Postdoctoral Fellow of the Life Sciences Research Foundation.

Although it is understood that epigenetics is responsible for turning genes “on” and “off” at defined times during cellular development, the precise mechanisms controlling this delicate process are less well understood.

“This finding has important implications for both stem cell biology and cancer development, as the same regulatory circuits controlled by PCL’s in stem cells are often mis-regulated in tumors,” said Dr. Greg Wang, senior author of the study and Assistant Professor of Biochemistry and Biophysics in the UNC School of Medicine and a member of UNC Lineberger Comprehensive Cancer Center.

The study, led by postdoctoral research fellows Drs. Ling Cai and Rui Lu in the Wang lab, and Dr. Scott Rothbart, a Lineberger postdoctoral fellow in the lab of Dr. Brian Strahl, Associate Professor of Biochemistry and Biophysics in the UNC School of Medicine and a member of UNC Lineberger Comprehensive Cancer Center, identified that PCL’s interact with an epigenetic signal associated with genes that are turned on to recruit a group of proteins called the PRC2 complex which then turn genes off.

“In stem cells, the PRC2 complex turns genes off that would otherwise promote reprogramming into specialized cells of organs like the heart or lungs,” said Wang.

In addition to its fundamental role in cellular development, elevated levels of PRC2 have been found in cancers of the prostate, breast, lung, and blood, and pharmaceutical companies are already developing drugs to target PRC2. Wang and colleagues determined that the same mechanisms controlling PRC2 function in stem cells also applies in human cancers.

“The identification of a specific PCL in controlling PRC2 in cancer cells suggests we may be able to develop drugs targeting this PCL to regulate PRC2 function in a more controlled manner that may maintain PRC2 function in stem cells while inhibiting it in the tumor,” said Wang.

This research was funded by the National Institutes of Health grants (GM085394 and GM068088), the Department of Defense, the V Foundation for Cancer Research, and the University Cancer Research Fund, and was performed in collaboration with scientists at the University of California at Riverside, Rockefeller University, Memorial Sloan-Kettering Cancer Center, and the Albert Einstein College of Medicine. Study co-authors from UNC also included Bowen Xu, a student in the Wang Lab, and Ashutosh Tripathy, a Research Professor in the Department of Biochemistry and Biophysics.

2012 Biochemistry and Biophysics Newsletter

***Learn more about IRA charitable giving - deadline extended to February 1, 2013***

Election as a fellow of the American Association for the Advancement of Science (AAAS), the world’s largest general scientific society, is an honor bestowed upon members by their peers. Fellows are recognized for meritorious efforts to advance science or its applications.  At the 2012 AAAS Fellows induction ceremony on February 16, 2013 (held in Boston, Massachussetts), Dr. Carter will be presented with his Fellowship Rosette and Certificate.

Learn more: Carter Lab

UNC School of Medicine News Release:
http://news.unchealthcare.org/news/2012/november/four-aaas-2012-fellows-among-unc-school-of-medicine-faculty

UNC News Release:
http://uncnews.unc.edu/content/view/5738/74/

AAAS Fellows News Release:
http://www.aaas.org/aboutaaas/fellows/2012.shtml

The American Physical Society is one of the leading non-profit membership organizations working to advance and diffuse the knowledge of physics through its outstanding research journals, scientific meetings, and education, outreach, advocacy and international activities. All APS members are eligible for nomination and election to Fellowship. The criterion for election is exceptional contributions to the physics enterprise; e.g., outstanding physics research, important applications of physics, leadership in or service to physics, or significant contributions to physics educat ion. Fellowship is a distinct honor signifying recognition by one's professional peers. Dr. Dokholyan's nomination was brought forth from the APS Division of Biological Physics.

Learn more: Dokholyan Lab

APS Fellows Search:

http://www.aps.org/programs/honors/fellowships/archive-all.cfm?initial=D&year=2012&unit_id=&institution=

www.brimr.org/NIH_Awards/2012/NIH_Awards_2012.htm

Mouse embryonic stem cells (blue, green) lose DNA methylation (red) in the absence of UHRF1. Source: Strahl Lab, UNC School of Medicine.

Over the last two decades, scientists have come to understand that the genetic code held within DNA represents only part of the blueprint of life. The rest comes from specific patterns of chemical tags that overlay the DNA structure, determining how tightly the DNA is packaged and how accessible certain genes are to be switched on or off.

As researchers have uncovered more and more of these “epigenetic” tags, they have begun to wonder how they are all connected. Now, research from the University of North Carolina School of Medicine has established the first link between the two most fundamental epigenetic tags -- histone modification and DNA methylation -- in humans.

The study, which was published Sept. 30, 2012 by the journal Nature Structural & Molecular Biology, implicates a protein called UHRF1 in the maintenance of these epigenetic tags. Because the protein has been found to be defective in cancer, the finding could help scientists understand not only how microscopic chemical changes can ultimately affect the epigenetic landscape but also give clues to the underlying causes of disease and cancer.

“There's always been the suspicion that regions marked by DNA methylation might be connected to other epigenetic tags like histone modifications, and that has even been shown to be true in model organisms like fungus and plants,” said senior study author Brian Strahl, PhD, associate professor of biochemistry and biophysics in the UNC School of Medicine and a member of UNC Lineberger Comprehensive Cancer Center. “But no one has been able to make that leap in human cells. It's been controversial in terms of whether or not there's really a connection. We have shown there is.”

Strahl, along with his postdoctoral fellow Scott Rothbart, honed in on this discovery by using a highly sophisticated technique developed in his lab known as next generation peptide arrays. First the Strahl lab generated specific types of histone modifications and dotted them on tiny glass slides called “arrays.” They then used these “arrays” to see how histone modifications affected the docking of different proteins. One protein – UHRF1 – stood out because it bound a specific histone modification (lysine 9 methylation on histone H3) in cases where others could not.

Strahl and his colleagues focused the rest of their experiments on understanding the role of UHRF1 binding to this histone modification. They found that while other proteins that dock on this epigenetic tag are ejected during a specific phase of the cell cycle, mitosis, UHRF1 sticks around. Importantly, the protein’s association with histones throughout the cell cycle appears to be critical to maintaining another epigenetic tag called DNA methylation.  The result was surprising because researchers had previously believed that the maintenance of DNA methylation occurred exclusively during a single step of the cell cycle called DNA replication.

“This role of UHRF1 outside of DNA replication is certainly unexpected, but I think it is just another way of making sure we don't lose information about our epigenetic landscape,” said Strahl.

The research was funded by the National Institutes of Health and the North Carolina Biotechnology Center. Study co-authors from UNC were Scott B. Rothbart, PhD, a postdoc in Strahl’s lab at UNC; Krzysztof Krajewski, PhD, research assistant professor; and Jorge Y. Martinez, a former student in Strahl’s lab.

Media contact: Tom Hughes, (919) 966-6047, tahughes@unch.unc.edu

RELATED NEWS RELEASES:

http://www.cancer.gov/newscenter/cancerresearchnews/2012/EpigeneticCodeMissingLink