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- Creators: School of Molecular Sciences
Description
Transient Receptor Potential (TRP) ion channels are a diverse family of nonselective, polymodal sensors in uni- and multicellular eukaryotes that are implicated in an assortment of biological contexts and human disease. The cold-activated TRP Melastatin-8 (TRPM8) channel, also recognized as the human body's primary cold sensor, is among the few TRP channels responsible for thermosensing. Despite sustained interest in the channel, the mechanisms underlying TRPM8 activation, modulation, and gating have proved challenging to study and remain poorly understood. In this thesis, I offer data collected on various expression, extraction, and purification conditions tested in E. Coli expression systems with the aim to optimize the generation of a structurally stable and functional human TRPM8 pore domain (S5 and S6) construct for application in structural biology studies. These studies, including the biophysical technique nuclear magnetic spectroscopy (NMR), among others, will be essential for elucidating the role of the TRPM8 pore domain in in regulating ligand binding, channel gating, ion selectively, and thermal sensitivity. Moreover, in the second half of this thesis, I discuss the ligation-independent megaprimer PCR of whole-plasmids (MEGAWHOP PCR) cloning technique, and how it was used to generate chimeras between TRPM8 and its nearest analog TRPM2. I review steps taken to optimize the efficiency of MEGAWHOP PCR and the implications and unique applications of this novel methodology for advancing recombinant DNA technology. I lastly present preliminary electrophysiological data on the chimeras, employed to isolate and study the functional contributions of each individual transmembrane helix (S1-S6) to TRPM8 menthol activation. These studies show the utility of the TRPM8\u2014TRPM2 chimeras for dissecting function of TRP channels. The average current traces analyzed thus far indicate that the S2 and S3 helices appear to play an important role in TRPM8 menthol modulation because the TRPM8[M2S2] and TRPM8[M2S3] chimeras significantly reduce channel conductance in the presence of menthol. The TRPM8[M2S4] chimera, oppositely, increases channel conductance, implying that the S4 helix in native TRPM8 may suppress menthol modulation. Overall, these findings show that there is promise in the techniques chosen to identify specific regions of TRPM8 crucial to menthol activation, though the methods chosen to study the TRPM8 pore independent from the whole channel may need to be reevaluated. Further experiments will be necessary to refine TRPM8 pore solubilization and purification before structural studies can proceed, and the electrophysiology traces observed for the chimeras will need to be further verified and evaluated for consistency and physiological significance.
ContributorsWaris, Maryam Siddika (Author) / Van Horn, Wade (Thesis director) / Redding, Kevin (Committee member) / School of Molecular Sciences (Contributor) / Department of English (Contributor) / Barrett, The Honors College (Contributor)
Created2016-05
Description
Higher plant Rubisco activase (Rca) is a stromal ATPase responsible for reactivating Rubisco. It is a member of the AAA+ protein superfamily and is thought to assemble into closed-ring hexamers like other AAA+ proteins belonging to the classic clade. Progress towards modeling the interaction between Rca and Rubisco has been slow due to limited structural information on Rca. Previous efforts in the lab were directed towards solving the structure of spinach short-form Rca using X-ray crystallography, given that it had notably high thermostability in the presence of ATP-γS, an ATP analog. However, due to disorder within the crystal lattice, an atomic resolution structure could not be obtained, prompting us to move to negative stain electron microscopy (EM), with our long-term goal being the use of cryo-electron microscopy (cryo-EM) for atomic resolution structure determination. Thus far, we have screened different Rca constructs in the presence of ATP-γS, both the full-length β-isoform and truncations containing only the AAA+ domain. Images collected on preparations of the full-length protein were amorphous, whereas images of the AAA+ domain showed well-defined ring-like assemblies under some conditions. Procedural adjustments, such as the use of previously frozen protein samples, rapid dilution, and minimizing thawing time were shown to improve complex assembly. The presence of Mn2+ was also found to improve hexamer formation over Mg2+. Calculated class averages of the AAA+ Rca construct in the presence of ATP-γS indicated a lack of homogeneity in the assemblies, showing both symmetric and asymmetric hexameric rings. To improve structural homogeneity, we tested buffer conditions containing either ADP alone or different ratios of ATP-γS to ADP, though results did not show a significant improvement in homogeneity. Multiple AAA+ domain preparations were evaluated. Because uniform protein assembly is a major requirement for structure solution by cryo-EM, more work needs to be done on screening biochemical conditions to optimize homogeneity.
ContributorsHernandez, Victoria Joan (Author) / Wachter, Rebekka (Thesis director) / Chiu, Po-Lin (Committee member) / Redding, Kevin (Committee member) / School of Molecular Sciences (Contributor) / Barrett, The Honors College (Contributor)
Created2018-05
Description
Polyketides are a wide ranging class of natural microbial products highly relevant to the pharmacological industry. As chemical synthesis of polyketides is quite challenging, significant effort has been made to understand the polyketide synthases (PKSs) responsible for their natural production. Native to Streptomyces, the aln biosynthetic gene cluster was recently characterized and encodes for an iterative type I polyketide synthase (iT1PKS). This iT1PKS produces both , and ,-double bond polyketides named allenomycins; however, the basis in which one bond is chosen over the other is not yet clear. The dehydratase domain, AlnB_DH, is thought to be solely responsible for catalyzing double bond formation. Elucidation of enzyme programming is the first step towards reprogramming AlnB_DH to produce novel industrially relevant products. The Nannenga lab has worked as collaborators to the Zhao lab at the University of Illinois at Urbana-Champaign to unravel AlnB_DH’s structure and mechanism. Here, mutant constructs of AlnB_DH are developed to elucidate enzyme structure and provide insight into active site machinery. The primary focus of this work is on the development of the mutant constructs themselves rather than the methods used for structural or mechanistic determination. Truncated constructs were successfully developed for crystallization and upon x-ray diffraction, a 2.45 Å resolution structure was determined. Point-mutated constructs were then developed based on structural insights, which identified H49, P58, and H62 as critical residues in active site machinery.
ContributorsBlackson, Wyatt (Author) / Nannenga, Brent (Thesis director) / Nielsen, David (Committee member) / Barrett, The Honors College (Contributor) / Chemical Engineering Program (Contributor) / School of Molecular Sciences (Contributor)
Created2023-05
Description
Viral proteases have been implicated in harmful viral diseases, and as such are becoming increasingly relevant drug targets. Essential for drug design is a detailed knowledge of the structure of the drug target, particularly its active site and binding regions. Research in this area, however, is lacking and many protease structures remain unknown. This project aims to advance towards solving the structure of a viral cysteine protease through means of crystallization and X-ray crystallography. The wild-type protease was crystallized using sitting drop vapor diffusion. Due to the dynamic nature of proteins, crystallization is no easy feat. Initial high throughput screens using commercial kits streamlined the identification of conditions with potential to form crystals. This was followed by several rounds of optimization of crystallization parameters including pH, buffer concentration, salt concentration, additive type, and crystallization volume in an effort to find a condition suited for crystal growth. This process eventually resulted in large, well-ordered crystals suitable for further experimentation. X-ray crystallography performed on these crystals demonstrated significant diffraction patterns up to a resolution of 3.7 Angstroms, indicative of moderate success in crystallization. Initial data processing was able to identify space groups, but analysis beyond that requires a higher resolution diffraction pattern. Future research will focus on continuing to optimize crystallization conditions to obtain a higher quality crystal and thus higher resolution diffraction patterns. From that point, diffraction data can be processed to build a structural profile of the wild-type viral protease. This information will serve invaluable for future research on the structures of similar proteins and for structure-based drug design targeted towards this viral protease.
ContributorsNichols, Alexis Christine (Author) / Liu, Dr. Wei (Thesis director) / Khdour, Dr. Omar (Committee member) / Mills, Dr. Jeremy (Committee member) / School of Molecular Sciences (Contributor) / Barrett, The Honors College (Contributor)
Created2020-05
Description
Developments in structural biology has led to advancements in drug design and vaccine development. By better understanding the macromolecular structure, rational choices can be made to improve factors in such as binding affinity, while reducing promiscuity and off-target interactions, improving the medicines of tomorrow. The majority of diseases have a macromolecular basis where rational drug development can make a large impact. Two challenging protein targets of different medical relevance have been investigated at different stages of determining their structures with the ultimate goal of advancing in drug development. The first protein target is the CapBCA membrane protein complex, a virulence factor from the bacterium Francisella tularensis and the causative agent of tularemia and classified as a potential bioterrorism weapon by the United States. Purification of the individual protein targets from the CapBCA complex is a key and challenging step that has been, so far, a limiting factor towards the structure determination of the whole complex. Here, the purification protocols for the CapB and CapC subunits have been establish, which will allow us to progress towards biophysical and structural studies. The second protein target investigated in this thesis is the catalytically active Taspase1. Taspase1 functions as a non-oncogene addiction protease that coordinates cancer cell proliferation and apoptosis and has been found to be overexpressed in many primary human cancers. Here the structure is presented to 3.04A with the goal of rational drug design of Taspase1 inhibitors. Development of Taspase1 inhibitors has no completion in the drug discovery arena and would function as a new anti-cancer therapeutic. Solving the structures of medically relevant proteins such as these is critical towards rapidly developing treatments and prevention of old and new diseases.
ContributorsJernigan, Rebecca J. (Author) / Fromme, Petra (Thesis director) / Hansen, Debra T. (Committee member) / Martin-Garcia, Jose M. (Committee member) / School of Molecular Sciences (Contributor) / School of Life Sciences (Contributor) / Barrett, The Honors College (Contributor)
Created2020-05