First name,Last name,Preferred title,Overview,Position,Department,Individual
Bruce,Riley,Professor,"My lab studies inner ear development in zebrafish. A prominent feature of our research is to investigate how cell-cell signaling and downstream gene-interactions control development. One project in the lab focuses on how cell signaling regulates ectodermal patterning during gastrulation to establish the otic placode, the precursor of the inner ear. Our recent work shows that localized Fgf signaling is especially critical for inducing formation of the otic placode, and members of the Pax2/5/8 family of transcription factors are important mediators of Fgf signaling. During later stages of inner ear development, we are exploring how sensory hair cells and neurons are regulated. Our studies address how these cells initially form, how they are genetically maintained, and how they become specialized for hearing vs. balance. We are also investigating how zebrafish can replace dead and damaged hair cells, an ability that mammals have lost. The inability to regenerate hair cells explains why humans show progressive irreversible hearing loss as we age. It is hoped that activating or augmenting human homologs of genes shown to operate in zebrafish might help restore hearing and balance in humans.",Professor,Biology,https://scholars.library.tamu.edu/vivo/display/n0dbb8253
Benjamin,Neuman,Professor,,Professor,Biology,https://scholars.library.tamu.edu/vivo/display/n193ea580
Charles,Criscione,Professor,"I examine fundamental ecological and evolutionary questions in parasite systems and consider my research to be at the interface of ecology, evolution, and genetics. Parasitology provides a rich subject area for studies of ecology and evolutionary biology. Numerous topics such as ecosystem dynamics, mating systems, or coevolution can be addressed because parasites are extremely diverse. By diversity, I include not only the myriad of taxa that have independently evolved a parasitic lifestyle, but also the diversity in life cycles, modes of reproduction, host species, and ecosystems utilized by parasites. This diversity also allows for comparative studies to address theories or unifying principles that span ecosystems or taxonomic groups. Furthermore, there are many practical applications such as studying the evolution of drug resistance, or using parasite community structure to assess ""ecosystem health"". My research interests address both basic and applied questions, and span three overlapping subject areas: 1) Evolution: Population Genetics, Mating Systems, and Molecular Epidemiology, 2) Ecology: Biodiversity, Conservation, and Natural History, and 3) Genetics and Ecological Genomics.",Professor,Biology,https://scholars.library.tamu.edu/vivo/display/n41a8b584
Mary,Wicksten,Professor,"I am studying the Thoridae, a family of small-sized marine shrimp that are remarkably diverse in the cold waters of the North Pacific. Evidence suggests that these shrimp may be losing range due to global warming. They may be replaced by members of a different family, the Palaemonidae, a group of more aggressive predatory shrimp. But to study such a replacement, one must identify the shrimp. The last major study was in 1906. All previous work has been morphological. Evidence from my own work and that of Greg Jensen, University of Washington, suggests that not only have species been confused (one species is actually two, three species actually are only one) but the generic designation may depend on temperature-dependent features. With a small start-up grant from the Arctic Biodiversity Study, I am collaborating with Luis Hurtado,, Department of Wildlife and Fisheries Science, to obtain some molecular data on genetic affinities within the Thoridae and potentially allied shrimp taxa. These data may at least indicate which of the supposed genera are distinct or even if the Thoridae is indeed a natural group. Examination of the 150 or more presumed species will begin following an assessment of the genera.",Professor,Biology,https://scholars.library.tamu.edu/vivo/display/n48bee4d6
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
Michael,Smotherman,Professor,"Evolution and Neurobiology of Communication
Communication is an essential part of sociality, and an animal's vocal communications provide a window into their cognitive capabilities, motivations, and behavioral ecology. Communication is also a important model of sensorimotor neurobiology because vocalizations are the motor output of a sophisticated suite of brain pathways that integrate across multiple sensory modalities and time scales. Vocal communication systems are highly diverse because they have been shaped by intense natural and sexual selection. Studying the evolution of communication networks in the brain provides important insight into how environment and ecology molded the social brain.
Our lab studies bats because of their biosonar capabilities and their unusually broad repertoire of communication calls and songs.
Echolocation provides an exciting model system for exploring how multiple brain pathways interact to control behavior on a millisecond time scale. Our neural studies investigate the neurocircuits that guide delicate changes in sonar pulse acoustics. Our behavioral studies of bats echolocating in groups has shed light on how they coordinate their sonar systems to minimize interference with one another. This research has direct relevance to man-made sonar and wireless communications systems.
Singing by bats offers exiting new opportunities to young investigators to explore how mammals and birds converged upon a similar behavior via different neural mechanisms. Identifying and characterizing the functional neurocircuitry of the bat's song production network is a major component of our research.",Professor,Biology,https://scholars.library.tamu.edu/vivo/display/n5bebea24
Uel,Mcmahan,Professor,"McMahan and his research group provide one of the cornerstones for Texas A&M's new Interdisciplinary Life Sciences Building and its related teaching and research efforts. His work focuses on how the nervous system's synapses form in the embryo and function in the adult in various animal species. It relies on high-resolution imaging, chemical characterization and experimental manipulation of specific macromolecules and organelles, which altogether provide insights unobtainable via any other approach. The findings bear directly on the problems of understanding the molecular basis of human brain diseases and restoring brain function after trauma.",Professor,Biology,https://scholars.library.tamu.edu/vivo/display/nfc3672e7