First name,Last name,Preferred title,Overview,Position,Department,Individual
Hongmin,Qin,Associate Professor,"Live bioreactor for synthetic biology
The lab is developing live bioreactors to synthesize products of commercial value. The system we are developing is capable of resisting contamination, and withstanding harsh conditions. We are translating the technology developed for potential industrial usages.
The biogenesis of a cilium/flagellum
Our lab is interested in the conceptual frameworks that govern organelle biogenesis and the corresponding regulations. The current main research effort in our lab is to understand. Cilia and flagella are microtubule-based appendages extending from the basal body of almost all eukaryotic cells, and are classified as either motile or primary. Motile cilia or flagella such as Chlamydomonas flagella, sperm flagella and respiratory tract epithelial cell cilia are responsible for movement or generation of fluid flow. In contrast, primary cilia are non-motile organelles that are critically involved in visual, olfactory and auditory signal transduction and play key roles in regulation of gene expression, development and animal behavior. Ciliary defects are linked to ciliopathies such as polycystic kidney disease, nephronophthisis, retinal degeneration, situs inversus, hydrocephalus, polydactyly and obesity. Our lab uses a combination of biochemistry, cell biology, and genetics approaches to understand the principles of ciliogenesis and its regulation.
Flagellar axoneme structure and motility
The waveform of cilia is conserved, no matter whether the cilia are on green algae Chlamydomonas or mammalian epithelia found in the airways, the uterus and fallopian tubes, the efferent ducts of the testes, and the ventricular system of the brain. These motile cilia beat with a conserved planar asymmetrical waveform. We are beginning to learn how the asymmetry of the waveform is established and the mutant analyses are underway.",Associate Professor,Biology,https://scholars.library.tamu.edu/vivo/display/n11e70177
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
Karl,Aufderheide,Emeritus Associate Professor,"Cell/Developmental Biology. Developmental Genetics. Intracellular differentiation of eukaryotes, especially ciliates. General interests in: intracellular pattern formation and morphogenesis; molecular aspects of gene expression in ciliate protozoa; development of organelles, including intracellular motility and organelle localization. Specific interests in: signal transduction, regulation of cytoskeletal organization, and motility in the social amoeba Dictyostelium; organization, patterning and morphogenesis of surface-related cytoskeletal and membranous structures of ciliates, especially Paramecium; applications of laser optical force trap technology to developmental problems in Paramecium tetraurelia and Tetrahymena thermophila; 2 molecular aspects of serotype gene expression in P. tetraurelia; development of exocytotic organelles (the trichocysts) in P. tetraurelia. General approach involves use of classical and modern light and electron microscopic techniques, integrated with genetic, molecular, mechanical or physiological manipulations of the cells.",Associate Professor,Biology,https://scholars.library.tamu.edu/vivo/display/n3ed65e09
Lawrence,Griffing,Associate Professor,"I am testing the theory that the endoplasmic reticulum, ER is the circulatory network of the cell, connecting different organelles to each other, allowing them to share signals, lipids, and proteins.
I am particularly interested in how the cytoskeletal system of plants regulates the movement of the ER network. In interphase, the actinomyosin network drives movement of the ER, just as it drives the movement organelles through the cytoplasm in a process called cytoplasmic streaming, a phenomenon in plants, but not animal cells. Of the seventeen different myosin forms in plants, only six are involved in active cytoplasmic streaming. We are sorting out which of those six guide the different movements of the endoplasmic reticulum.
I am also interested in the nature of the nexus between the ER and other organelles, including the chloroplast, plasma membrane, and Golgi. I have recently shown that by photo-stimulating the nexus between the chloroplast and the ER, the directional flow within the ER can be reversibly altered. This ability to generate very localized ER stress may have application in a wide variety of fields - from finding cures for neurodegenerative diseases such as Alzheimer's syndrome to developing crops that can better-tolerate physiological heat stress and drought.
Finally, I recently founded the company, Griffing Biologics LLC, which is based on the discovery of a novel, non-toxic pre-emergent herbicide that interferes with plant sterol metabolism. Other work examining the uptake of sterols indicates that it may get into the plant cells via plasma membrane-ER contact sites. We are pursuing the function of this transport in controlling the early stages of plant growth.",Associate Professor,Biology,https://scholars.library.tamu.edu/vivo/display/nd558069a
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