First name,Last name,Preferred title,Overview,Position,Department,Individual
James,Womack,Distinguished Professor,"Comparative mammalian genomics with emphasis on bovids and laboratory animals. Study of evolution of gene families and genomic variation underlying disease resistance. Investigation of genetic mechanisms in innate immunity with focus on livestock, select agents, and agricultural biosecurity.",Distinguished Professor,Veterinary Pathobiology,https://scholars.library.tamu.edu/vivo/display/n0e1a49e2
Timothy,Devarenne,Associate Professor,"We study the biochemical and molecular mechanisms underlying the control of programmed cell death (PCD) in plants and how PCD is manipulated during plant-pathogen interactions. Specifically we study the interaction between tomato and Pseudomonas syringae pv. tomato (Pst) the causative agent of bacterial spot disease. Resistance to this disease is conferred by the host Pto serine/threonine protein kinase which recognizes Pst strains expressing the type III effector protein AvrPto.
PCD is induced during both resistant and susceptible plant-pathogen interactions. In the case of a resistant interaction, PCD induced by the plant, known as the hypersensitive response (HR), and acts to limit the spread of the pathogen. In susceptible plant-pathogen interactions plant PCD is induced by the pathogen after infection leading to death of the host. Studies have indicated that the genes controlling host PCD during the HR are the same genes that are manipulated by the pathogen during susceptible interactions. The difference lies in the timing of controlling the activity of these genes; HR PCD occurs within 12 hours of pathogen recognition while pathogen-induced PCD occurs several days after infection.
Many of these genes that control plant PCD are serine/threonine (S/T) protein kinase. We are interested in studying a specific class of S/T protein kinases that control PCD in plants called AGC kinases and how they are regulated in both resistant and susceptible plant-pathogen interactions. Additionally, when plants are not attacked by pathogens, PCD is a process that requires constant control so that cell death does not occur. We are looking at the signaling mechanisms and pathways employed to keep PCD under check in non-pathogen challenged plants.",Faculty Affiliate||Associate Professor,Energy Institute||Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/n11411275
Blanca,Lupiani,Professor,"Research in my laboratory focuses on better understanding the molecular mechanisms of pathogenesis of Marek's disease virus, a chicken oncogenic alphaherpesvirus. We study gene function using biochemical techniques and by introducing mutations into the viral genome. The knowledge obtained from these studies is used to develop vaccines to control this critical poultry pathogen. In addition, we are investigating the use of Marek's disease vaccines as viral vectors to control other viral diseases of poultry.",Professor,Veterinary Pathobiology,https://scholars.library.tamu.edu/vivo/display/n255741f6
Sanjay,Reddy,Professor,"The long-term goal of my laboratory is to understand the molecular basis of pathogenesis of Marek's disease virus (MDV), a potent oncogenic herpesvirus that causes T-cell tumors in chickens. MDV codes for a protein (Meq), which shares significant resemblance with the Jun/Fos family of transcriptional factors. We have shown that this gene plays a critical role in latency and transformation of T-lymphocytes. Understanding the basic mechanism of viral pathogenesis will aid in the development of improved vaccine. We are also interested in other important poultry disease like avian influenza.",Professor,Veterinary Pathobiology,https://scholars.library.tamu.edu/vivo/display/n28054661
David,Russell,Professor,"My research focuses on proteomics, lipidomics, biophysical chemistry and application and development of mass spectrometry, such as ""label-free"" nano-particle based biosensors and novel peptide/protein isolation and purification strategies. We are also investigating the structure(s) of model peptides in an effort to better describe folding/unfolding and structure of membrane and intrinsically disordered (IDP) proteins. Peptides take on very different 2?, 3? and 4? structure, which determine or influence bio-activity. In the presence of lipid vesicles peptides can exist as solution-phase species, ""absorbed"" on lipid bilayers or ""inserted"" (as a monomer or multimer) in lipid bilayers. By what mechanism do peptides interact with lipid membranes to affect these structural changes, how do peptide-lipid interactions promote self-assembly to form intermediates that eventually yield aggregates, i.e., amyloid fibrils, or how does metal ion coordination affect the structure of metalloproteins? Mass spectrometry-based experiments, hydrogen/deuterium (H/D) exchange, chemical 'foot-printing' and gas-phase (ion-molecule and ion-ion reaction chemistry) and solution-phase chemical modifications, have expanded our abilities to address such questions, and new instrumental approaches, esp. ion mobility spectrometry (IMS) combined with enhanced molecular dynamics simulations (MDS), have become standard tools for structural-mass spectrometry studies. Over the past several years we have either acquired or developed novel, next-generation IM-MS instruments that are redefining cutting-edge structural-mass spectrometry research as well as cutting-edge computational tools essential to carry out these studies. Our new laboratories in the Interdisciplinary Life Sciences Building (ILSB) provides exciting opportunities for collaborative, interdisciplinary research with chemical-biologists, biochemists and other chemists.",Professor,Chemistry,https://scholars.library.tamu.edu/vivo/display/n280e03e6
Loren,Skow,Professor,Comparative genomics of mammals with emphasis on organization and evolution of the mammalian genome; molecular analysis of the major histocompatibility complex of hoofed animals; genetic mechanisms of inherent resistance to infectious diseases.,Professor,Veterinary Integrative Biosciences,https://scholars.library.tamu.edu/vivo/display/n4326eaa3
Mark,Burow,Professor,"Goals of the program are, in collaboration with peanut breeding programs in College Station and Stephenville to
(1) release new cultivars for Texas growers, incorporating:
high yield
improved edible seed quality -early maturity, high oleic oil
resistance to water deficit, heat, and salt stress
resistance to disease and pests, especially leafspot, nematodes, and Sclerotinia blight
(2) Participate in the International Peanut Genome Initiative, and use genomics technology in cultivar
development
(3) Participate in international collaborations with scientists, especially in Ghana and Burkina Faso
through a Peanut and Mycotoxin Innovation Lab/ USAID project",Professor||Professor,Soil and Crop Sciences||Lubbock Research and Extension Center,https://scholars.library.tamu.edu/vivo/display/n57d1bc41
Guan,Zhu,Professor,"Our laboratory conducts translational research with an ultimate goal to discover new anti-parasitic therapeutics by targeting metabolic enzymes and other molecules critical or essential to the parasite infection, survival and development, such as those involved in the lipid and energy metabolisms and interacting with host cells in Cryptosporidium and other protozoan parasites. Other research areas include functional genomics and molecular evolution of apicomplexan parasites, and parasitic diseases important to the conservation of wild animals.",Professor,Veterinary Pathobiology,https://scholars.library.tamu.edu/vivo/display/n6d62f33b
Michael,Thomson,Professor,"My research expertise is in plant molecular breeding with an emphasis on rice genetics and genomics, international agriculture, and developing CRISPR-based gene editing approaches for efficient gene validation and trait development. My primary objective is to apply new genetics discoveries to rice improvement to help Texas producers and rice farmers around the world produce higher yields of superior quality rice in an environmentally sustainable manner. I am also leading the AgriLife Research Crop Genome Editing Lab to optimize high-throughput gene editing across a number of diverse crop species.",Professor,Soil and Crop Sciences,https://scholars.library.tamu.edu/vivo/display/n74c30954
Leslie,Adams,Senior Professor,"My research is focused on the: 1) investigation of the comparative molecular pathogenesis of zoonotic intracellular bacterial pathogens in natural animal models, particularly brucellosis, salmonellosis, and mycobacterial diseases; 2) development of vaccines and host gene expression-based diagnostics for zoonotic and select agent caused diseases, and especially 3) development of in silico host:pathogen interactome predictive models based upon bi-directional in vivo host (bovine/murine) and Brucella spp., Mycobacterium spp.and Salmonella enterica Typhimurium interactions. We developed an in silico computational infection biology model based on actuall temporal in vivo bovine model microarray-based transcriptomic and proteomic profiling of the acute infectious process. We developed a systems biology analysis of both host and pathogen comprehensive transcriptomic and proteomic datasets derived from our in vivo biological model. We computationally fused the datasets based on actual Salmonella, Brucella and Mycobacterium data and computationally predicted bovine host structural proteins to identify maximum likelihoods of host and pathogen protein:protein interactions as the basis for our preliminary in silico interactome model to predict mechanistic genes and linked perturbed cellular pathways.",Senior Professor,Veterinary Pathobiology,https://scholars.library.tamu.edu/vivo/display/n75fee121
Fuller,Bazer,Distinguished Professor,"Dr. Bazer's research in reproductive biology focuses on uterine biology and pregnancy, particularly pregnancy recognition signaling from the conceptus to the maternal uterus by interferon tau and estrogen from ruminant and pig conceptuses, respectively. The roles of uterine secretions as transport proteins, regulatory molecules, growth factors and enzymes and endocrine regulation of their secretion is another major research interest. The endocrinology of pregnancy, especially the roles of lactogenic and growth hormones in fetal-placental development and uterine functions are being studied. The mechanism(s) of action and potential therapeutic value of conceptus interferons and uterine-derived hematopoietic growth factors are areas of research with both pigs and sheep as models for human disease.",Distinguished Professor,Animal Science,https://scholars.library.tamu.edu/vivo/display/n7ad91d50
James,Sacchettini,Professor,"My lab uses X-ray crystallography to better understand the relationship between proteins and ligands. Tiny differences in the structure of a molecule can radically change the interaction between a protein and ligand and we are only begining to understand how many factors play a role in this interaction. By manipulating the individual components of a compound it is possible to create a chemical that binds to the protein better than the natural substrate, and prevent the natural reaction from occurring. This is the basis for rational drug design. Our efforts have lead us to collaborations with other labs and scientists in many disciplines as our approach to directed compound design has applications not only in basic research but also in pesticide development, health research and clinical research.",Professor,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/n90385563
Nancy,Ing,Professor,"Dr. Ing's research interests focus on understanding how hormones regulate gene expression in animal tissues. Current research projects investigate the earliest days of pregnancy in the sheep uterus and the regulation of estrogen receptor gene expression, as well as stress hormone effects on gene expression in the stallion testes. Most recently, we have been studying the RNAs in sperm from stallions and honey bees in order to find a pattern consistent with high fertility.",Professor,Animal Science,https://scholars.library.tamu.edu/vivo/display/n98a4a111
Leif,Andersson,Professor,,Professor,Veterinary Integrative Biosciences,https://scholars.library.tamu.edu/vivo/display/ne8ae2a28
Albert,Mulenga,"Professor and Interim head, Veterinary Pathobiology","For generations ticks and tick borne diseases have had significant impact of animal health and livestock productivity around the world. In public health the effect of ticks and tick borne diseases is also tremendous. Since the 1980s when the causative agent of Lyme disease was described, numerous human tick borne diseases have been reported. In absence of effective vaccines against major tick borne diseases, prevention of animal and human tick borne disease infections relies on the use chemicals (acaricides) to kill ticks. Although acaricide based tick control methods are effective in the short-term, they do not offer a permanent solution because of serious limitations such as ticks developing resistance and contamination of the environment and the food chain. Immunization of animals against is a validated alternative tick control method. The attraction is that tick vaccines will be effective against both acaricide resistant and susceptible tick populations. The major limiting factor is the availability of effective tick vaccine targets. The tick cannot cause damage to host or transmit disease agents without successful feeding. Thus, our plan is to understand molecular mechanisms of how ticks accomplish feeding. In this way we will find targets that will be used for development of effective tick vaccines. We are currently studying the feeding physiology of the blacklegged tick (Ixodes scapularis) and the Lone Star tick (Amblyomma americanum). According to the US Centers for Disease Control, these two medically important tick species transmit a combined nine of the 14 human tick borne disease agents in the United States. Major work is on discovery and characterization of proteins that the Lone Star and the Blacklegged tick into animals every 24h through out feeding. The area of particular emphasis is to understanding roles of serine protease inhibitors (serpins) the blacklegged tick and the Lone Star tick inject into animals during feeding. We have identified serpins",Professor and associate head||Professor & Interim Head,School of Veterinary Medicine and Biomedical Sciences||Veterinary Pathobiology,https://scholars.library.tamu.edu/vivo/display/ne8f0c620
Ryland,Young,Professor,"Most bacterial viruses (phages) cause lysis of their host cell to release the progeny virions. Large phages elaborate an enzyme (""endolysin"") to degrade the cell wall and also a small membrane protein (""holin""). The holin accumulates in the membrane and then, at a precisely scheduled time, suddenly forms a hole to allow release of endolysin through the cytoplasmic membrane to gain access to the wall. We use molecular genetics and biochemistry to study how this small protein is able to act as a molecular ""clock"" and punch holes in membranes. Small phages make single proteins which cause host lysis in a different way. This strategy is to target the host cell wall synthesis machinery; that is, the virus makes a ""protein antibiotic"" that causes lysis in the same way as antibiotics like penicillin by inhibiting an enzyme in the multi-step pathway of murein biosynthesis. Thus, when the infected cell tries to divide, it blows up, or lyses, because it can't make the new cell wall between the daughter cells. Remarkably, each of three different, small phages blocks a different step in the pathway. These small lysis proteins are models for a completely new class of antibacterial antibiotics. Also, the E. coli SlyD protein is required for this mode of lysis in one case. SlyD is a member of an ubiquitous family of proteins related to human ""immunophilins,"" the targets of immune-suppression drugs. We study SlyD to learn about the role of this class of proteins in biology.",Professor,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/nea775348
John,Mullet,Professor,"Functional genomics, bioinformatics, and DNA chip technology are fundamentally changing research on biological systems. Knowledge of complete genome sequences and high resolution genome technology provide an extraordinary opportunity to understand complex biological processes and to relate detailed understanding of protein structure and biochemical mechanism to the function of whole organisms and biological systems in nature.
Our research team is helping to build genome maps and DNA diagnostic microarrays/chips for analysis of global gene expression and biodiversity. This new technology is being used to explore the molecular basis of several fundamental plant responses: (1) light responsive genetic systems that help protect plants from damage by high intensity UV/blue light; (2) genetic systems that allow plants to adapt to the environment; (3) genes and signal transduction pathways that help protect plants from insects and disease; and (4) genes that regulate plant development (flowering time, fertility restoration, chloroplast development/number).",Professor,Biochemistry and Biophysics,https://scholars.library.tamu.edu/vivo/display/nf1c81fcb