First name,Last name,Preferred title,Overview,Position,Department,Individual
Rodolfo,Aramayo,Associate Professor,"My current research primarily focuses on understanding the organization, distribution, and comparison of information in Biological Systems. Our work encompasses two key levels of investigation:
Molecular Genetics: We employ the filamentous fungus Neurospora crassa as a model organism to uncover and comprehend the intricate molecular components responsible for sequence-based comparisons between homologous chromosomes, leading to the initiation of Meiotic Silencing, a phenomenon driven by RNA-mediated processes. Currently, our primary focus centers on the exploration of whether genes recognized for their significance in Meiotic Transvection/Silencing also contribute to the occurrence of Repeat Induced Point Mutation (RIP) phenomena.
Computational Analysis: We are developing novel computational pipelines dedicated to detecting sequence variations within related genomes. We are particularly intrigued by the prospect of simplifying (i.e., digitizing) the information present in DNA, RNA, and Proteins so as to simplify its manipulation and analysis. We think that digitizing emerging genomic data will not only enable us to use this data effectively but also to integrate it into Artificial Intelligence, Data Clustering, and Image Recognition Algorithms, in ways not done before. We posit that this process of converting biological features into digital equivalents has the potential to simplify genomic information, making it easier to uncover previously unnoticed patterns through complex computational comparisons. This approach has already yielded promising results by revealing unexpected informational patterns across various organisms' chromosomes. We believe that it will streamline and enhance our ability to comprehend different cellular and organismal states. Moreover, it holds significant promise in revolutionizing our understanding of diseases, particularly Cancer and Metagenomics. This informational perspective also contributes to our comprehension of genome evolution, especially in the field of comparative genomics and microbial metagenomics.",Associate Professor,Biology,https://scholars.library.tamu.edu/vivo/display/n14287b36
Deborah,Bell-Pedersen,Professor,"Research in the Bell-Pedersen lab focuses on determining how the circadian clock functions in organisms to regulate daily rhythms in gene expression, behavior, and physiology. The molecular clock in higher eukaryotes involves a master clock in the brain regulating clocks in peripheral tissues, posing significant obstacles for understanding circadian output mechanisms. Thus, a major strength of our work is using a single-celled model eukaryote, Neurospora crassa, to elucidate the underlying mechanisms of rhythmic gene expression and protein synthesis. Clock dysfunction in humans is associated with a wide range of diseases, including cardiovascular disease, cancer, metabolic disorders, mental illness, sleep disorders, and aging. In addition, daily changes in metabolism and cell division rates influence the efficacy and toxicity of many pharmaceuticals, including cancer drugs. Therefore, knowing how clocks work to control rhythmic gene expression, and what they regulate, is critical for the development of therapeutics. Research to understand clock-controlled rhythmic gene expression has focused primarily on transcriptional mechanisms, and little was known about posttranscriptional control. We discovered that the clock regulates highly conserved translation initiation and elongation factors, tRNA synthetase levels, and ribosome heterogeneity. This regulation determines what mRNAs are rhythmically translated and the accuracy of the translation process (translation fidelity). We are capitalizing on these exciting discoveries to determine how the clock regulates translation fidelity. These studies will provide the foundation for understanding the impact of daily rhythms in translation fidelity on protein diversity beyond what is encoded for in the genome.",Professor and Associate Department Head,Biology,https://scholars.library.tamu.edu/vivo/display/n2a2bfb97
Luis,Garcia,Professor,"I am interested in understanding how behavioral states are regulated at the molecular and genetic level. My lab addresses this complex question in the well-studied nematode Caenorhabditis elegans. Several physical aspects of this worm make it convenient for integrating whole organism system biology studies with genetic/molecular analysis of neurobiology and behavior. C. elegans is an anatomically simple organism; it is 1mm in size, and it contains ~ 1000 somatic cells, a third of which are neurons. The worm is also transparent, and thus every cell can be visualized by light microscopy. Behavioral mutants can be efficiently generated through standard chemical mutagenesis. In addition, gene functions involved in motivational and behavioral regulation can be determined by transgenic techniques.
My lab investigates the interplay between feeding and sex-specific mating behavior to understand how chemo/mechano-sensory and motor outputs are controlled under various physiological conditions. We study male mating by using genetics to de-construct this behavior into its fundamental sensory-motor components. We then use a combination of transgenics, pharmacology, classical genetics and laser microsurgery to understand how individual motor sub-behaviors are coordinated to produce gross behaviors during periods when the animal is food deprived, and when it is food satiated.",Professor,Biology,https://scholars.library.tamu.edu/vivo/display/n4cd2f794
Christine,Merlin,Associate Professor,"Our research broadly lies in understanding how organisms respond and adapt to changing environments, with an emphasis on circadian biology. Organisms from bacteria to humans use circadian clocks to control a plethora of biochemical, physiological and behavioral rhythms. These clocks are synchronized to daily and seasonal environmental changes to allow organisms to tune specific activities at the appropriate times of day or year.
In our laboratory, we use the eastern North American migratory monarch butterfly (Danaus plexippus) as a model system to study animal clock mechanisms and the role of circadian clocks and clock genes in a fascinating biological output, the animal long-distance migration. Every fall, like clockwork, millions of monarch butterflies start migrating thousands of miles from North America to reach their overwintering sites in central Mexico. During their journey south, migrating monarchs use a time-compensated sun compass orientation mechanism to maintain a constant flight bearing. Circadian clocks located in the antennae provide the critical internal timing device for compensation of the sun movement across the sky over the course of the day. The recent sequencing of the monarch genome and the establishment of genetic tools to knockout clock genes (and others) in vivo using nuclease-mediated gene targeting approaches provides us with a unique opportunity to uncover the molecular and cellular underpinnings of the butterfly clockwork, its migratory behavior and their interplay.",Assistant Professor,Biology,https://scholars.library.tamu.edu/vivo/display/n5a23a5d7
Terry,Thomas,Professor,"My interests are evolutionarily broad and include animals, plants and fungi. A major focus of the lab is the genomic analysis of gene expression programs during plant gene expression programs, particularly during embryogenesis and seed development, and the underlying regulatory mechanisms required for the initiation and maintenance of these programs. This work has illustrated the combinatorial interactions of cis and trans -acting factors that result in specific gene regulatory events. We are also using genomics tools to study the interaction of the rice blast fungus, Magnaporthe grisea , with plant hosts; the circadian control of gene expression; and the development of the vertebrate retina. An additional focal area is the utilization of molecular and cellular approaches for crop improvement. As part of these research activities, we have developed or adapted high throughput genomics approaches to accelerate the gene discovery process and subsequent analysis of gene expression and function.",Professor,Biology,https://scholars.library.tamu.edu/vivo/display/n79201ac5
Alex,Keene,Professor and Department Head,,Professor and Department Head,Biology,https://scholars.library.tamu.edu/vivo/display/n8650c3cf
Alan,Pepper,Associate Professor,"My laboratory uses genetic, molecular, and genomic tools to study how terrestrial plants adapt, both in a short-term sense (phenotypic plasticity) and in a long-term sense (adaptive evolution), to the vast diversity of environments found on our planet.
My laboratory is studying the molecular and physiological mechanisms of 'downstream' developmental responses to light using genetic and molecular tools available in the model plant Arabidopsis thaliana. In another project, we are using comparative genomics to investigate the genetic basis of the evolution-under-domestication of developmental processes in cultivated cottons (Gossypium spp.) and their wild relatives. Gossypium is in the Malvaceae family and, as such, shares a recent common ancestor with Arabidopsis and other plants in the Brassicaceae family.
We are also investigating the genetic mechanisms of plant adaptation to the stresses of extreme environments such as drought, low mineral nutrients (N,P,K) and heavy metals, in wild relatives of Arabidopsis, such as the rare endemic plant Caulanthus amplexicaulis (Brassicaceae.) This work has led us to become more broadly interested in the conservation and ecological genetics of rare plants, particularly geoendemics.",Associate Professor,Biology,https://scholars.library.tamu.edu/vivo/display/ndc106a4d
Deborah,Siegele,Associate Professor,"Phenotypes are observable characteristics of an organism that result from the expression of a particular genotype in a particular environment. Examples of phenotypic traits in microbes are motility, sporulation, ability to perform anaerobic respiration, and resistance/sensitivity to an antibiotic.
Until recently, phenotypic information has been captured as free text descriptions in research papers. Ambiguities in natural language confound attempts to retrieve information across sources. For example, ""serotype"" and ""serovar"" both refer to the same phenotype, but a simple text-based query with either word alone would miss the other. Or a single term, such as ""sporulation"" is used to refer to multiple, distinct processes in different organisms. Issues such as these hamper the ability to integrate different phenotypic data sets for the same organism or to use phenotypic information in one organism to predict possible phenotypes in another organism. Ideally, phenotype information should be stored in a consistent, computable format for ease of data integration and mining.
Controlled vocabularies are used to provide both consistent terminology and a structured data format for the capture of biological information. Ontologies are controlled vocabularies of defined terms with unique identifiers and precise relationships to each other. There are phenotype ontologies available for many eukaryotic organisms, including fungi. However, when the OMP project was initiated, none of the existing ontologies was appropriate to comprehensively capture phenotypes for Bacteria or Archaea or to enable comparisons across microbial taxa.
The Siegele lab and our collaborators at TAMU and the Univ. of Maryland (IGS) are developing a formal Ontology of Microbial Phenotypes (OMP). Our lab is focused on term development and annotating microbial phenotypes. OMP can be accessed at microbialphenotypes.org. Releases of OMP are available at github.com/microbialphenotypes.",Associate Professor,Biology,https://scholars.library.tamu.edu/vivo/display/ne333d587
Paul,Hardin,Distinguished Professor,"A diverse array of organisms including prokaryotic and eukaryotic microbes, plants, and animals display daily rhythms in physiology, metabolism and/or behavior. These rhythms are not passively driven by environmental cycles of light and temperature, but are actively controlled by endogenous circadian clocks that are set by environmental cycles, keep time in the absence of environmental cues, and activate overt physiological, metabolic and behavioral rhythms at the appropriate time of day. This remarkable conservation of circadian clock function through evolution suggests that maintaining synchrony with the environment is of fundamental importance. Our understanding of the circadian clock is particularly important for human health and well-being. The clearest examples of circadian clock dysfunction are those that result in abnormal sleep-wake cycles, but clock disturbances are also associated with other ailments including epilepsy, cerebrovascular disease, depression, and seasonal affective disorder. The realization that disorders of the sleep-wake cycle such as Familial Advanced Sleep Phase Syndrome can result from alterations in clock gene function underscores the clinical importance of understanding the molecular organization of the circadian system.
Work in my laboratory focuses on defining the molecular mechanisms that drive circadian clock function in the fruit fly, Drosophila melanogaster. We previously found that the core timekeeping mechanism is based on core and interlocked transcriptional feedback loops. Our studies currently focus on (1) defining post-translational regulatory mechanisms that operate in the core loop to set the 24 hour period, (2) determining whether interlocked loops are important for circadian timekeeping and/or output, (3) understanding how circadian oscillator cells are determined during development, and (4) defining mechanisms that control rhythms in olfactory and gustatory physiology and behavior.",Distinguished Professor,Biology,https://scholars.library.tamu.edu/vivo/display/nf27056c4
Richard,Gomer,Distinguished Professor,"Our laboratory is working on three areas of biomedicine, trying to move observations from basic research into the clinic. First, we are studying how the sizes of tissues and tumors are regulated, and how this can be manipulated for therapeutic purposes. As a model system, we are using the simple eukaryote Dictyostelium discoideum, which allows us to combine techniques such as biochemistry, genetics, computer modeling, and cell biology to study tissue size regulation. We have found that a secreted protein as well as the unusual molecule polyphosphate are signals in negative feedback loops that inhibit Dictyostelium cell proliferation, and we are studying the signal transduction pathway to understand similar mechanisms in humans.
Second, we are studying how some secreted proteins can make cells move away from the source of the signal. We found such a signal (called a chemorepellent) in Dictyostelium, and then found a similar signal in humans. We are working to understand the signal transduction pathway for both. The human signal repels neutrophils, and we found that this can be used therapeutically in mouse models of neutrophil-driven diseases such as rheumatoid arthritis and acute respiratory distress syndrome.
Third, we have found that a human blood protein called Serum Amyloid P (SAP) regulates a key step in the formation of scar tissue as well as the formation of the scar-like lesions in fibrosing diseases such as congestive heart failure and pulmonary fibrosis. We are studying this mechanism, and a biotech company (Promedior, now sold to Roche) we co-founded is testing SAP as a therapy for fibrosis in patients in a Phase 3 trials.",Distinguished Professor,Biology,https://scholars.library.tamu.edu/vivo/display/nf41f3898
James,Erickson,Associate Professor,"Alternative developmental fates are often determined by small differences in the concentrations of signaling molecules. In many cases, cells respond to these signals within narrowly defined temporal windows and are unresponsive to the same signal molecules at other times in development. A number of aspects of Drosophila sex determination make it an ideal experimental system to study how strict temporal controls and small quantitative differences in protein concentration can elicit different developmental fates.",Associate Professor,Biology,https://scholars.library.tamu.edu/vivo/display/nf4575bc8