A research paper published in September 2015 by MCDB professor Mike Mahan and his team was selected as one of the top papers of the year in the journal EbioMedicine. The title of the paper is "Host-dependent Induction of Transient Antibiotic Resistance: A Prelude to Treatment Failure” and the two joint first authors are Jessica Kubicek-Sutherland and Douglas Heithoff. MCDB professor Jamey Marth also contributed to this study.
In an important step toward creating a practical underwater glue, researchers led by MCDB professor Herb Waite have designed a synthetic material that combines the key functionalities of interfacial mussel foot proteins, creating a single, low-molecular-weight, one-component adhesive. Their findings appear in the journal Nature Communications.
Fruit flies (Drosophila melanogaster) are used as model organisms for studying a variety of physiological functions. The fly tongue includes 68 so-called “gustatory receptors” (GRs) that play important roles in sensing sugars as well as bitter compounds. Nonetheless, determining which combination of GRs contributes to detecting a particular noxious compound remains difficult because they are composed of many subunits. Now, MCDB’s Craig Montell and colleagues have identified three fruit fly GRs required for a response to the noxious amino acid L-canavanine. The principal nonprotein amino acid of certain leguminous plants such as clover and alfalfa, L-canavanine is used as an insecticide and is toxic to fruit flies. The researchers’ findings appear in the journal Nature Communications.
Physiological processes in the body are in large part determined by the composition of secreted proteins found in the circulatory systems, including the blood. Each of the hundreds of proteins in the blood has a specific life span that determines its unique range of abundance. In fact, measurements of their quantities and activities contribute to many clinical diagnoses. However, the way in which normal protein concentrations in the blood are determined and maintained has been a mystery for decades. Biomedical scientists led by MCDB professor Jamey Marth have now discovered a mechanism by which secreted proteins age and turn over at the end of their life spans. Their findings, which shed light on a crucial aspect of health and disease, appear today in the Proceedings of the National Academy of Sciences.
An animal’s ability to perceive light incorporates many complex processes. Now, researchers in Craig Montell’s lab in the MCDB department have used fruit flies and mice to make novel discoveries about sensory physiology at both cellular and molecular levels that are important for light processing. Their most recent findings, which improve the scientific understanding of the signaling cascade necessary for phototransduction — the process by which light is converted into electrical signals in the photoreceptor cells in the retina of the eye — appear today in the journal Cell Reports.
An interdisciplinary team lead by MCDB professor Mike Mahan discovered an unexpected resistance mechanism in pathogenic bacteria that may warrant changes in the way antibiotics are developed, tested and prescribed. Their findings appear in the journal EBioMedicine.
MCDB professor Craig Montell is the recipient of a 2015 National Institutes of Health (NIH) Director’s Pioneer Award worth $500,000 per annum over five years. The Pioneer Award supports individual scientists of exceptional creativity, who propose pioneering and transforming approaches to major challenges in biomedical science.
Dr. Simpson was a Group Leader at HHMI/Janelia, and moved to UCSB in August of 2015. Her research focuses on mapping neural circuit in the fly brain that coordinate motor behaviors, such as grooming.
Flashing calamari? The California market squid (Doryteuthis opalescens) has amazing light-manipulating abilities. While this species shares the gift of camouflage with most other cuttlefish, octopus and squid in the cephalopod family, it can also communicate and signal underwater through intricate changes in the patterns of color flashing from its skin.
Stem cells have a multitude of uses, not the least of which is to create tissue models that reflect human physiology. Such stem cell-derived models have enormous potential in research and application. One possible use, developed by a team of scientists led by MCDB professor James Thomson, involves reducing the number of drug failures in clinical trials and offering a cost-effective approach for assessing chemical safety.