The Case of the Recurring Fever
An elderly man had symptoms no one could explain – until Amy Berger, MD, PhD, and her team investigated.
University of California San Francisco
Give to UCSFAn elderly man had symptoms no one could explain – until Amy Berger, MD, PhD, and her team investigated.
Hidden autoimmunity may explain how the coronavirus wreaks such widespread and unpredictable harm.
The viruses that cause polio and COVID-19 mutate, but treatments for the diseases don’t. For over 20 years, UCSF and Gladstone Institutes scientist Leor Weinberger, PhD, has been thinking of ways to make vaccines work more efficiently by being adaptive, rather than static.
Scientists now have shown that the weakening of an astronaut’s immune system during space travel is likely due in part to abnormal activation of immune cells called T regulator cells.
Sophie Dumont, winner of the 2021 Byers Award for Basic Science, focuses on finding out how, as well whether therapeutic targets exist to ensure equal – and healthy – division of chromosomes.
UCSF researchers have figured out precisely what receptor tyrosine kinases are, how they form and their role in cancer.
Researchers at UCSF have demonstrated how to engineer smart immune cells that are effective against solid tumors, opening the door to treating a variety of cancers that have long been untouchable with immunotherapies.
Scientists have figured out how to modify CRISPR’s basic architecture to extend its reach beyond the genome and into what’s known as the epigenome.
Cancer starts with mutations in a cell’s DNA, but new UCSF research shows that the endurance of a tumor relies on its ability to rapidly evolve and adapt to challenges brought about by the environment in which it grows.
In a new study, UCSF and Stanford researchers have identified a central switch that appears to control when neural progenitor cells stop multiplying and start differentiating into mature neurons.
UCSF researchers found that mice in which activity of a protein called eIF4E is diminished, either genetically or pharmaceutically, gain only half the weight of other mice, even if all the mice eat a high-fat diet.
We turned to UCSF scientists to better understand probiotics and the human microbiome they aim to influence.
Susan Acton discovered ACE2 while searching for new cardiovascular drugs. Decades later, she was surprised to see it popping up in the news once COVID took hold.
A UCSF team has engineered a tiny antibody capable of neutralizing the coronavirus.
UCSF and BridgeBio Pharma, Inc. today announced a partnership to drive the advancement of academic innovations in genetically driven diseases into potential therapeutics for patients.
A group at Gladstone Institutes and UCSF has demonstrated that a large-scale and systematic genetic approach can indeed yield reliable and detailed information on the structure of protein complexes.
We asked several UCSF experts for a personal take on what will convince them that a vaccine is safe.
Giant lizards with superpowered hearts. Hairless rodents that don’t seem to age. Songbirds that babble like human babies. These and other scurrying, soaring, and slithering wonders are teaching scientists how our own bodies work – and how to fix them.
In the new study, UCSF researchers showed rapid restoration of youthful cognitive abilities in aged mice, accompanied by a rejuvenation of brain and immune cells that could help explain improvements in brain function.
Every fall, Matt Jacobson relives his Parkinson’s diagnosis so future pharmacists perceive the patient behind the prescription.
Finding medicines that can kill cancer cells while leaving normal tissue unscathed is a Holy Grail of oncology research.
SARS-CoV-2 uses its distinctive spike to latch onto a receptor called ACE2 on the surface of a human cell. Once there it prompts the human cell to ferry the virus inside. Then, the virus co-opts human enzymes to make copies of itself and spread to other cells.
For a tiny embryo to develop into an adult organism, its cells must develop in precise patterns and interact with their neighbors in carefully orchestrated ways. To create complex tissues and organs –
An international team of researchers studied the three lethal coronaviruses SARS-CoV-2, SARS-CoV-1 and MERS-CoV in order to identify commonly hijacked cellular pathways and detect promising targets for broad coronavirus inhibition.
Researchers at UCSF are tackling antibiotic resistance using a different approach: redesigning existing antibiotic molecules to evade a bacterium’s resistance mechanisms
UCSF scientists have devised a novel approach to halting the spread of SARS-CoV-2, the virus that causes the disease.