L'article ci-dessous indique très bien ce sur quoi il travaillait. Des plus révélateur......commençons notre enquête ici. Pour que vous puissiez comprendre les implications ou les buts de ces assassinat ou suicides assistés, hum, ces tous derniers temps et avant qu'on en entende plus parler, comprenez bien que tout ceci fait parti du génocide humain et de la cueillette des génies de cette planète de gré ou de force (une fois le cerveau bien lavé) au service de sa Majesté Céleste. Même si l'article est en anglais, utilisez Alta Vista ou bien il est temps de vous munir d'un logiciel de traduction, haha. Amitié, Nenki

 Structural Biology of Viruses and the Human Immune System

Summary: Don Wiley studies the atomic structure and biochemical functions of membrane glycoproteins on viral and human cellular surfaces that are involved in infectivity and human immune responses.

My research group studies how proteins from the surfaces of viruses initiate viral infections and how proteins of the human cellular immune system respond by presenting antigens and mobilizing defensive cells. We use x-ray crystallography to determine the atomic structures of proteins isolated from viruses and human cells. The structures provide us with a framework for determining how the molecules carry out their biological functions. We focus on the function of viral membrane glycoproteins, especially their functions in receptor binding, viral entry by membrane fusion, and evolution to evade the host immune response. We study proteins from influenza, HIV-1, herpes, and human respiratory syncytial viruses. We also study the functions of a number of human membrane glycoproteins that are involved in presenting antigens as part of the human cellular immune response, including T cell receptors (TCRs), major histocompatibility complex (MHC) glycoproteins, antigen peptide transporters (TAPs), and the proteins involved in trafficking and loading of antigenic peptides onto MHC molecules (Ii, tapasin, and DM).

In the past year, our studies of virus proteins have included determining the structure of a complex between a human cytomegalovirus protein (US2) and a human class I MHC molecule (with Hidde Ploegh, Harvard Medical School), showing how the virus subverts antigen presentation to avoid destruction by the immune system, and determining the structure of a complex between the HIV-1 glycoprotein responsible for viral entry into cells (gp41) and a synthetic inhibitor of that membrane fusion event that we had discovered earlier in collaboration with Stuart Schreiber and Stephen Harrison (both HHMI, Harvard University). (HIV-1 studies were supported in part by a grant from the National Institutes of Health). We have also found methods for producing large quantities of the soluble trimer of SIV-1 glycoprotein gp140, closely related to the HIV-1 gp140, which is responsible for initiating AIDS infections (in collaboration with Harrison and Ellis Reinherz, Harvard University). (These studies were partially funded by the National Institutes of Health.)

We also determined the three-dimensional structures of avian H5 and swine H9 influenza hemagglutinin glycoproteins (HAs) from viruses closely related to those that caused outbreaks of human disease in Hong Kong in 1997 (which caused 6 fatalities of 18 known cases) and 1999, and bound them to avian and human cell receptor analogs (in collaboration with John Skehel, National Institute for Medical Research, London, and with support from the National Institutes of Health). Emerging influenza pandemics have been accompanied by the evolution of receptor-binding specificity—from the preference of avian viruses for sialic acid receptors in a2,3 linkage to the preference of human viruses for a2,6 linkages. When compared with our previously reported crystal structures of HA/sialoside complexes of the H3 subtype that caused the 1968 Hong Kong influenza virus pandemic, the new structures make clearer how receptor-binding sites of HAs from avian viruses evolve as the virus adapts to humans.

To understand how viruses enter cells by membrane fusion, we have studied influenza, HIV-1, and Ebola virus in the past and found they share many elements of their atomic mechanism. While continuing to study those mechanisms, we have also begun to study human herpes simplex virus and human respiratory syncytial virus (HRSV), which initiate membrane fusion differently. This year we determined the structure of a complex of the herpes glycoprotein gD with one of its cellular receptors, a member of the tumor necrosis factor receptor family (in collaboration with Roselyn Eisenberg and Gary Cohen, University of Pennsylvania; partial funding from the National Institutes of Health). These studies revealed a conformational change induced upon receptor binding, which we are now studying. Herpes viruses are a major human health problem: HSV-1 infections become latent, emerging sporadically to cause oral lesions in humans; HSV-2 causes genital lesions. Glycoprotein gD of herpes virus is required for infection and the cell-to-cell spread involved in emergence from latency. This is the first of the 11 glycoproteins of any herpes virus to be seen at atomic detail. Our studies on HRSV, in collaboration with John Skehel (London) and Jose Molero (Madrid), used biochemistry and electron microscopy to define two conformations of the membrane fusion glycoprotein F and to show that two proteolytic processing events are required before this glycoprotein is able to be activated for membrane fusion.

In the past few years we have determined five structures of human abTCRs bound to class I MHC molecules presenting peptides, revealing an atomic picture of the recognition event that occurs between a cytotoxic (killer) T cell and an antigen-presenting cell (in collaboration with William Biddison, National Institutes of Health). In the past year we determined a similar complex but with a TCR recognizing a class II MHC molecule presenting an influenza virus peptide, which showed the intercellular recognition event that a T helper (CD4+) cell would make with an antigen-presenting cell during an influenza virus infection. Despite these structures and a few from other research groups, it remains unclear how the T cell knows that an MHC-peptide complex has bound to an MHC molecule. In one study last year using an array of physical chemical methods, we showed that the soluble TCR-MHC complexes do not dimerize; dimer formation had been favored as the mechanism of signal transduction. Our work, repeating experiments from other laboratories and extending the study by applying other methods, indicates that the results from two previously published studies cannot be generalized to the two different TCR-MHC complexes we studied. It remains possible that the entire (not just ab) TCR in membranes will form dimers once bound to MHC-peptide complexes between cells. The new result thus serves to focus our efforts on the more complicated membrane-bound forms of the TCR.

Susceptibility to autoimmune diseases such as multiple sclerosis and insulin-dependent diabetes (IDDM) is linked to specific class II MHC molecules. Recently, in collaboration with Kai Wucherpfennig (Dana-Farber Cancer Institute), we determined the structure of the class II MHC molecule most closely associated with IDDM, DQ8, complexed with a peptide from insulin. Comparisons and modeling of peptide-binding pockets suggest DQ8 is similar to other human allelic products and the mouse MHC molecule associated with autoimmune diabetes. These similarities suggest that diabetes is caused by the same antigen-presentation event(s) in humans and the non-obese diabetic (NOD) mice and provide evidence that the NOD mouse is a good model for the human disease. The structure also suggests the locations on the DQ molecule that might be blocked specifically to inhibit antigen presentation of DQ. In a related study we also determined the structure of another class II MHC molecule, DR1, with a hybrid-peptide inhibitor blocking its antigen-binding site (in collaboration with Gary Olson [Provid Research]; David Bolin [Hoffmann-LaRoche]; and Andrew Benowitz, Paul Sprengeler, Amos Smith III, and Ralph Hirschmann [University of Pennsylvania]).

We also recently determined the structure of human MHC class I molecules complexed with modified peptides from antigens presented by melanomas. Such peptides are candidates for antimelanoma vaccines. (This work was a collaboration with Olivier Michielin, Jean-Charles Cerottini, Immanuel Luescher, and Pedro Romero, from Strasbourg and Lausanne, and Martin Karplus, from Harvard University).

Antigenic peptides are transported into the endoplasmic reticulum to be loaded on MHC class I molecules by an ATP-dependent transporter, TAP. To determine how this membrane-bound peptide-loading machinery operates, we recently determined the structure of one of its pieces, the TAP1 ATPase domain. The structure revealed how TAP1 binds ADP and provided a framework for experiments on its activity.

Last updated: November 5, 2001

Photo: Kay Chernush

 Don C. Wiley ( R.I.P. )

Department of Molecular and Cellular Biology Harvard University 7 Divinity Avenue Cambridge, MA 02138

12 postdoctoral fellows, 2 graduate students

Tel 1: 617-495-1808 Fax 1: 617-495-9613 ____________________________

Department of Medicine

We are studying the mechanism of action of the envelope glycoprotein and membrane channels of lipid enveloped viruses, HIV-1, SIV-1, Influenza virus, Herpes Simplex virus, Respiratory Syncititial virus, and Ebola virus. We have determined the three-dimensional structures of glycoproteins from influenza virus and HIV-1 by X-ray crystallography and carried out site-directed mutagenesis, protein engineering, NMR, and biochemical experiments directed at understanding:

1.how viruses interact with their receptors 2.how their antigenic structures vary to escape the host immune response 3.how they enter cells by fusing their membranes with cellular membranes.

We have also determined the structure of the Herpes Virus gD glycoprotein bound to its cellualr receptor, HveA.

Our goal is to understand the molecular mechanisms that initiate viral infections at the atomic level and to search for methods to intervene in the processes. We are also interested in using combinatorial chemistry and structure-based design to discover inhibitors both to viral-cell binding and to the conformational change of the envelope glycoproteins necessary for their membrane fusion activities during viral entry.

We also study the molecular mechanisms underlying antigen presentation and T cell recognition in the cellular immune response. We have determined the structures of human class I and class II histocompatibility glycoproteins and intercellular recognition complexes of a T cell receptors (TCR) bound to MHC molecules presenting viral antigens. We also study the structure and mechanism of action of molecules that load class I and class II MHC molecules in intracellular vesicles and we are investigating the basis of immune tolerance by studying TCR/MHC interactions and a number of MHC molecules implicated in autoimmune disorders.

References: Weissenhorn, W., Dessen, A., Harrison, S.C., Skehel, J.J. and Wiley, D.C. "Atomic Structure of an Ectodomain from HIV-1 gp41", Nature, 387, 426-430, 1997. Rosenthal, P.B., Zhang, X., Formanowski, F., Fitz, W., Wong, C-H., Meier-Ewert, H., Skehel, J.J. Three Dimensional Structure of the Haemagglutinin-Esterase-Fusion Glycoprotein of Influenza C. Virus. Nature 396, 92-96, 1998. Chen, J., Skehel, J.J. and Wiley, D.C. N- and C-Terminal Residues combine in the Fusion-pH Influenza HA2 to form a Novel N-Cap that Terminates the Triple-Stranded Coiled Coil. Proc. of the Natl Acad of Sci. USA 96, 8967-8972, 1999. Skehel, J. & Wiley, D. Receptor Binding and Membrane Fusion in Virus Entry: The Influenza Hemagglutinin. Ann Rev of Biochem 69, 531-569, 2000. Chen, B., Zhou, G., Kim, M., Chishti, Y., Hussey, R.E., Ely, B., Skehel, J.J., Reinherz, E.L., Harrison, S.C. and Wiley, D.C. Expression, Purification, and Characterization of gp160e, the Soluble, Trimeric Ectodomain of the Simian Immunodeficiency Virus Envelope Glycoprotein, gp160. J Biol Chem. 275; 34946-34953, 2000.

 Dr. Don C. Wiley, a Hughes investigator at Harvard University, and Jack L. Strominger, a biochemist also from Harvard, have been awarded the 1995 Albert Lasker Basic Medical Research Award. The prize was awarded this year to five scientists who have advanced the field of immunology. Wiley and Strominger were honored for their solution of the structure of major histocompatability (MHC) proteins and their peptide complexes. MHC proteins bind to foreign peptides thereby making the foreign proteins recognizable to T-cells which stimulate an immune response.

A citation issued to Wiley by the Albert and Mary Lasker Foundation states that "Dr. Wiley's extraordinary accomplishments have changed the ground rules of immunology. By providing a precise picture of MHC-peptide binding, he has made the rational design of specific molecules for antiviral vaccines a reality. Research into tumor antigens, allograft rejection, and autoimmune diseases as diverse as multiple sclerosis, rheumatoid arthritis and diabetes mellitus, has made essential advances that originate in the achievements of Don Wiley."

An immune response against invading organisms is initiated by T lymphocytes, called helper T-cells, whose outer membranes carry MHC molecules unique to each individual. Class II MHC molecules, found in macro-phages and other antigen-presenting cells, bind to foreign protein fragments (peptides) inside the macrophage, and then transport these peptides to the cell membrane.

The complex of MHC molecule plus peptide functions as a signal for T-cells which recognize the complex as foreign and initiate the immune response. Class I MHC molecules, found in all body cells, perform the same function, but their complexes are recognized by killer T-cells which destroy the infected host cell.

Strominger's early research in isolating and purifying Class I MHC proteins provided the framework for the crucial collaboration with Wiley. A renowned X-ray crystallographer, Wiley, in collaboration with Strominger and Pamela Bjorkman, who is now a Hughes investigator at Caltech, determined the crystal structure of HLA-A2. The structure of HLA-A2 provided the first glimpse of how antigens could be presented by MHC molecules.

Subsequent work by Wiley and Strominger and a number of co-workers has given researchers a better picture of how MHC Class I and II molecules mediate the immune response. Such structural studies have advanced understanding of the molecular basis of immune recognition, and they continue to impact the study of autoimmune diseases, bacterial and viral infections, and the field of organ transplantation.

Rajout de dernière heure: 22-12-01 20:00 hres Montréal.
Source: http://www.msnbc.com/news/676245.asp?cp1=1

DR. WILEY, 57, HAD BEEN missing since Nov. 16, when his rental car was found abandoned with the keys in the ignition on a Mississippi River bridge in Memphis.The body was discovered Thursday snagged on a tree near a hydroelectric plant at Vidalia, La., across the river from Natchez, Miss, about 300 miles south of Memphis. A wallet containing Wiley’s identification was found on the body, police said. Shelby County medical examiner O.C. Smith began an autopsy on the body Friday. The body was identified through dental records, police Lt. Walter Norris said. Authorities said the cause of death may be determined in the coming week. No evidence of foul play was found in the car.
‘VERY UPBEAT’ Wiley was in Memphis for a scientific conference hosted by St. Jude Children’s Research Hospital. He was last seen publicly at a conference banquet, and colleagues said he showed no evidence of emotional distress. “He was very upbeat, very engaging and in great spirits,” said Jerry Chipman, a St. Jude spokesman. Wiley’s disappearance raised concerns about a possible terrorist connection since he had done research on a number of potentially deadly viruses, including Ebola, a highly contagious and lethal fever. The FBI said it was leaving the investigation to the Memphis police. Authorities have disclosed no evidence of connection between Wiley’s work and his disappearance. Scientific organizations, including St. Jude, posted rewards totaling $26,000 for information leading to the “arrest and charge” of anyone responsible for Wiley’s disappearance.

and from:http://www.msnbc.com/local/rtmem/m129436.asp

Mississippi River

REUTERS

MEMPHIS, Tenn., Dec. 21 - The body of a Harvard scientist missing for more than a month since his rental car was left parked on a bridge over the Mississippi River has been found downstream, police said on Friday.

WORKERS AT A hydroelectric plant in Louisiana found the body of Don Wiley on Thursday, about 300 miles (490 kms) south of where the molecular biologist was last seen on Nov. 18 at a medical meeting in Memphis, Tennessee. Authorities had yet to determine the cause of death, Memphis police said. Police had speculated that Wiley committed suicide, though his family and colleagues said he showed no signs of unhappiness. His rental car was found on the bridge, its gas tank full and the keys in the ignition. Wiley's disappearance triggered alarm bells because of his expertise in deadly viruses such as Ebola amid U.S. fears of possible bioterrorism following the Sept. 11 attacks and subsequent anthrax mailings.