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Elizabeth P. Carpenter | |
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Alma mater | University of Cambridge Birkbeck, University of London |
Scientific career | |
Institutions | University of Oxford Imperial College London Diamond Light Source |
Elizabeth P. Carpenter is a British structural biologist who is a professor at the Nuffield Department of Medicine in Oxford. She solved the three-dimensional structure of human membrane proteins using X-ray crystallography. Carpenter uses X-ray crystallography to understand the atomic positions within proteins.
Carpenter studied biochemistry at the University of Cambridge. She moved to Birkbeck, University of London for doctoral research, where she studied biochemistry and crystallography. [1] After completing her doctorate, Carpenter moved to the National Institute for Health Research, which was based at Imperial College London and solved the structures of proteins involved in DNA repair. [1] She also investigated toxoplasmosis and muste movement. [1]
Carpenter is interested in understanding the structure and function of proteins. She studies proteins embedded within cell membranes. [1] The proteins are large hydrophobic surfaces, and understanding their structure is an important step in unravelling the processes of molecules and signals across cell membranes. [1] [2] She established the Membrane Protein Laboratory at the Diamond Light Source in 2007. [1] [3] In 2009, she moved to the Structural Genomics Consortium at the University of Oxford. [1]
Carpenter was the first to describe the structure of the human ABC-transporter ABC10. ABC10 is a mitrochonridal protein that is important in the production of heme. She has studied premature ageing syndromes that are caused by failure of the lamin proteins, and the role of the metalloprotease ZMPSTE24. [4] She has also studied human ion channels, including TREK-2, a K2P protein that gives rise to the background leak current that contributes to membrane potential. [4]
Structural biology is a field that is many centuries old which, as defined by the Journal of Structural Biology, deals with structural analysis of living material at every level of organization. Early structural biologists throughout the 19th and early 20th centuries were primarily only able to study structures to the limit of the naked eye's visual acuity and through magnifying glasses and light microscopes.
An integral, or intrinsic, membrane protein (IMP) is a type of membrane protein that is permanently attached to the biological membrane. All transmembrane proteins are IMPs, but not all IMPs are transmembrane proteins. IMPs comprise a significant fraction of the proteins encoded in an organism's genome. Proteins that cross the membrane are surrounded by annular lipids, which are defined as lipids that are in direct contact with a membrane protein. Such proteins can only be separated from the membranes by using detergents, nonpolar solvents, or sometimes denaturing agents.
Membrane proteins are common proteins that are part of, or interact with, biological membranes. Membrane proteins fall into several broad categories depending on their location. Integral membrane proteins are a permanent part of a cell membrane and can either penetrate the membrane (transmembrane) or associate with one or the other side of a membrane. Peripheral membrane proteins are transiently associated with the cell membrane.
A transmembrane protein (TP) is a type of integral membrane protein that spans the entirety of the cell membrane. Many transmembrane proteins function as gateways to permit the transport of specific substances across the membrane. They frequently undergo significant conformational changes to move a substance through the membrane. They are usually highly hydrophobic and aggregate and precipitate in water. They require detergents or nonpolar solvents for extraction, although some of them (beta-barrels) can be also extracted using denaturing agents.
Bacteriorhodopsin (Bop) is a protein used by Archaea, most notably by haloarchaea, a class of the Euryarchaeota. It acts as a proton pump; that is, it captures light energy and uses it to move protons across the membrane out of the cell. The resulting proton gradient is subsequently converted into chemical energy.
A membrane transport protein is a membrane protein involved in the movement of ions, small molecules, and macromolecules, such as another protein, across a biological membrane. Transport proteins are integral transmembrane proteins; that is they exist permanently within and span the membrane across which they transport substances. The proteins may assist in the movement of substances by facilitated diffusion or active transport. The two main types of proteins involved in such transport are broadly categorized as either channels or carriers. The solute carriers and atypical SLCs are secondary active or facilitative transporters in humans. Collectively membrane transporters and channels are known as the transportome. Transportomes govern cellular influx and efflux of not only ions and nutrients but drugs as well.
The ATP-binding cassette transporters are a transport system superfamily that is one of the largest and possibly one of the oldest gene families. It is represented in all extant phyla, from prokaryotes to humans. ABC transporters belong to translocases.
In biochemistry, a conformational change is a change in the shape of a macromolecule, often induced by environmental factors.
In biology, a transporter is a transmembrane protein that moves ions across a biological membrane to accomplish many different biological functions including, cellular communication, maintaining homeostasis, energy production, etc. There are different types of transporters including, pumps, uniporters, antiporters, and symporters. Active transporters or ion pumps are transporters that convert energy from various sources—including adenosine triphosphate (ATP), sunlight, and other redox reactions—to potential energy by pumping an ion up its concentration gradient. This potential energy could then be used by secondary transporters, including ion carriers and ion channels, to drive vital cellular processes, such as ATP synthesis.
Sir Thomas Leon Blundell, is a British biochemist, structural biologist, and science administrator. He was a member of the team of Dorothy Hodgkin that solved in 1969 the first structure of a protein hormone, insulin. Blundell has made contributions to the structural biology of polypeptide hormones, growth factors, receptor activation, signal transduction, and DNA double-strand break repair, subjects important in cancer, tuberculosis, and familial diseases. He has developed software for protein modelling and understanding the effects of mutations on protein function, leading to new approaches to structure-guided and Fragment-based lead discovery. In 1999 he co-founded the oncology company Astex Therapeutics, which has moved ten drugs into clinical trials. Blundell has played central roles in restructuring British research councils and, as President of the UK Science Council, in developing professionalism in the practice of science.
Proteins of the Proton-dependent Oligopeptide Transporter (POT) Family are found in animals, plants, yeast, archaea and both Gram-negative and Gram-positive bacteria, and are part of the major facilitator superfamily. The transport of peptides into cells is a well-documented biological phenomenon which is accomplished by specific, energy-dependent transporters found in a number of organisms as diverse as bacteria and humans. The proton-dependent oligopeptide transporter (PTR) family of proteins is distinct from the ABC-type peptide transporters and was uncovered by sequence analyses of a number of recently discovered peptide transport proteins. These proteins that seem to be mainly involved in the intake of small peptides with the concomitant uptake of a proton.
Sir David Ian Stuart is a Medical Research Council Professor of Structural Biology at the Wellcome Trust Centre for Human Genetics at the University of Oxford where he is also a Fellow of Hertford College, Oxford. He is best known for his contributions to the X-ray crystallography of viruses, in particular for determining the structures of foot-and-mouth disease virus, bluetongue virus and the membrane-containing phages PRD1 and PM2. He is also director of Instruct and Life Sciences Director at Diamond Light Source.
Christopher G. TateFRS is an English membrane protein biochemist and molecular biologist who works at the Medical Research Council Laboratory of Molecular Biology in Cambridge, UK. Tate is known for his contributions to the understanding of G protein-coupled receptors.
Andrew P. Carter is a British structural biologist who works at the Medical Research Council (MRC) Laboratory of Molecular Biology (LMB) in Cambridge, UK. He is known for his work on the microtubule motor dynein.
Renee Elizabeth Sockett is a professor and microbiologist in the School of Life Sciences at the University of Nottingham. She is a world-leading expert on Bdellovibrio bacteriovorus, a species of predatory bacteria.
Tracey Maureen Gloster is a chemist at the University of St Andrews UK. Her research interests are in structural biology, chemical biology, glycobiology and carbohydrate processing enzymes.
Carla M. Koehler is an American biochemist who is a professor at the University of California, Los Angeles. Her research considers mitochondria and the processes which import proteins to their appropriate locations in the organelles. She was elected Fellow of the American Association for the Advancement of Science in 2018.
Susan Mary Lea is a British biologist who serves as chief of the center for structural biology at the National Cancer Institute. Her research investigates host-pathogen interactions and biomolecular pathways. She was elected a Fellow of the Royal Society in 2022.
Bonnie Ann Wallace, FRSC is a British and American biophysicist and biochemist. She is a professor of molecular biophysics in the department of biological sciences, formerly the department of crystallography, at Birkbeck College, University of London, U.K.
Olga Boudker is a Russian born physicist who is a professor of physiology and biophysics at the Weill Cornell Medicine. She looks to understand the mechanisms of membrane transporters in cellular function. She was elected a fellow of the National Academy of Sciences in 2022.