genes

IRP’s Julie Segre Elected to the National Academy of Medicine

NIH Researcher Recognized for Investigation into the Skin Microbiome

Dr. Julie Segre

The National Academy of Medicine (NAM), first established in 1970 by the National Academy of Sciences as the Institute of Medicine (IOM), is comprised of more than 2,000 elected members from around the world who provide scientific and policy guidance on important matters relating to human health. Election to the NAM is considered one of the highest honors in the fields of health and medicine that recognizes individuals who have not only made critical scientific discoveries but have also demonstrated a laudable commitment to public service.

IRP senior investigator Julie Segre, Ph.D., was one of four IRP researchers elected to the NAM in 2019. Dr. Segre leads the Translational and Functional Genomics Branch at the National Human Genome Research Institute (NHGRI), where she studies the way in which the skin forms a barrier between the body and the environment. In particular, her research uses genetic sequencing to understand the bacterial and fungal microbes that live on human skin.

Medical Research Scholars Reflect on Their NIH Journeys

Future Physician-Scientists Spent a Year in IRP Labs

MRSP participant working in the lab

Many doctors not only treat patients directly, but also make valuable contributions to research that will improve medical care in the future. Each one of these talented ‘physician-scientists’ began his or her research career under the guidance of a more senior scientist. At the NIH, the Medical Research Scholars Program (MRSP) provides just such an experience to promising young medical students from all across the United States.

Innovation Awards Spark New Intramural Collaborations

Program Boosts Initiatives Supporting Researchers Across NIH

scientists talking in a lab

From Superbowl-winning football teams to comic book cohorts like The Avengers, combining the efforts of multiple talented individuals is a proven strategy for achieving remarkable results. It may come as no surprise, then, that the NIH’s Intramural Research Program (IRP) strongly encourages collaborations that breach the boundaries of its 24 Institutes and Centers. One example of these efforts is the Director’s Challenge Innovation Awards Program, which since 2009 has funded high-impact scientific projects that bring together researchers from across the IRP.

The Virus vs the Machine

IRP Leverages Supercomputing to Combat Coronavirus

rows of computer servers

Over the past six months, a tiny virus has completely upended life in the United States and many other countries. To combat this microscopic threat, some IRP researchers have turned to a tool the size of a small building.

Biowulf, the NIH’s supercomputer, is supporting more than a dozen different IRP research projects focused on the novel coronavirus. As the world’s most powerful supercomputer solely dedicated to biomedical research, Biowulf allows scientists to analyze data and run simulations at unprecedented speed. Two weeks ago, a blog post described how IRP investigators are using Biowulf to elucidate the structure of the novel coronavirus and simulate how potential therapeutics might interact with it. Picking up where that post left off, this blog will explore the application of Biowulf to important questions about the spread of COVID-19 and the way that its genes, along with our own, might influence its impact on the body.

Psychological Stress Damages Brain’s Blood Vessels

Mouse Study Illuminates Potential Mechanism Behind Mood and Anxiety Disorders

red blood cells flowing through a blood vessel

Millions of Americans suffered from depression and anxiety even before COVID-19 began upending their lives. To make matters worse, the stresses of living through a pandemic might not only worsen mental health but could also wreak havoc on the brain itself. New IRP research has found that psychological stress damages blood vessels in the brains of mice and dramatically alters the behavior of genes in certain blood vessel cells.

A Multi-Front Effort to Combat Coronavirus

IRP Research Examines Pandemic From All Angles

scientist working in the lab

The sheer number of labs and wide variety of scientific perspectives in the IRP make it particularly well-suited to combating a disease like COVID-19, which is affecting patients’ health and the world around them in a huge number of ways. IRP researchers specializing in psychology, genetics, epidemiology, and many other disciplines are pursuing an array of strategies to learn more about the novel coronavirus.

Pandemic Brings All Hands on Deck

IRP Investigators Begin Hundreds of New Coronavirus-Related Studies

coronavirus particles (gold) emerging from an infected cell

Within just a few months after COVID-19 began spreading in the United States, IRP researchers had already made numerous important contributions to the fight against the deadly virus. Scientific knowledge about the disease continues to expand at a unprecedented pace, and the IRP will continue to play a major role in this effort over the coming months and years. In fact, nearly 300 new intramural research projects related to the novel coronavirus are currently starting up or have already begun.

IRP’s Luigi Notarangelo Elected to National Academy of Medicine

NIH Researcher Recognized for Insights into Genetic Immune System Diseases

Dr. Luigi Notarangelo

The National Academy of Medicine (NAM), first established in 1970 by the National Academy of Sciences as the Institute of Medicine (IOM), is comprised of more than 2,000 elected members from around the world who provide scientific and policy guidance on important matters relating to human health. Election to the NAM is considered one of the highest honors in the fields of health and medicine and recognizes individuals who have not only made critical scientific discoveries but have also demonstrated a laudable commitment to public service.

IRP senior investigator Luigi Notarangelo, M.D., was one of four IRP researchers recently elected to the NAM. As the head of the Immune Deficiency Genetics Section and the Laboratory of Clinical Immunology and Microbiology at the National Institute of Allergy and Infectious Diseases (NIAID), Dr. Notarangelo investigates the cellular and molecular roots of genetic conditions called primary immune deficiencies that compromise the immune system. These illnesses leave patients — many of whom are children — highly vulnerable to infections and can also lead to autoimmune problems caused when the immune system attacks the body’s own tissues. Some of Dr. Notarangelo’s patients have known genetic mutations, while for others the source of their disease remains a mystery.

Remembrances: Phil Leder (1934-2020)

Phil Leder at a chalkboard

Our friend and former colleague Phil Leder, among the world's most accomplished molecular geneticists, died on Sunday, February 2, at age 85. His work with Marshall Nirenberg — namely, the famed Nirenberg and Leder experiments starting at the NIH in 1964, which definitively elucidated the triplet nature of the genetic code and culminated in its full deciphering — helped set the stage for the revolution in molecular genetic research that Phil himself would continue to lead for the next three decades.

Mothers’ Smoking Leaves Unique Marks on Infants’ DNA

Smoking While Pregnant Affects a Woman’s Genes Differently From Her Baby’s

baby holding an adult's finger

Decades of public health campaigns have made the health consequences of smoking common knowledge. However, for the few women who smoke while pregnant, the habit can affect not only their own bodies but also those of their unborn children. Intriguingly, according to a new study led by IRP researchers, so-called ‘epigenetic’ changes to DNA that can alter the behavior of genes differ significantly in smoking mothers compared to their babies, suggesting that maternal smoking may have unique, long-lasting effects on the way a child’s body functions.