Matching Items (18)
Filtering by
- All Subjects: Biochemistry
- Creators: Mills, Jeremy
- Member of: Theses and Dissertations
Description
DNA nanotechnology uses the reliability of Watson-Crick base pairing to program and generate two-dimensional and three-dimensional nanostructures using single-stranded DNA as the structural material. DNA nanostructures show great promise for the future of bioengineering, as there are a myriad of potential applications that utilize DNA’s chemical interactivity and ability to bind other macromolecules and metals. DNA origami is a method of constructing nanostructures, which consists of a long “scaffold” strand folded into a shape by shorter “staple” oligonucleotides. Due to the negative charge of DNA molecules, divalent cations, most commonly magnesium, are required for origami to form and maintain structural integrity. The experiments in this paper address the discrepancy between salt concentrations required for origami stability and the salt concentrations present in living systems. The stability of three structures, a two-dimensional triangle, a three-dimensional solid cuboid and a three-dimensional wireframe icosahedron were examined in buffer solutions containing various concentrations of salts. In these experiments, DNA origami structures remained intact in low-magnesium conditions that emulate living cells, supporting their potential for widespread biological application in the future.
ContributorsSeverson, Grant William (Author) / Stephanopoulos, Nicholas (Thesis director) / Mills, Jeremy (Committee member) / School of Molecular Sciences (Contributor) / School of Life Sciences (Contributor) / Barrett, The Honors College (Contributor)
Created2020-05
Description
G protein-coupled receptors, or GPCRs, are receptors located within the membrane of cells that elicit a wide array of cellular responses through their interactions with G proteins. Recent advances in the use of lipid cubic phase (LCP) for the crystallization of GPCRs, as well as increased knowledge of techniques to improve receptor stability, have led to a large increase in the number of available GPCR structures, despite historic difficulties. This project is focused on the histamine family of receptors, which are Class A GPCRs that are involved in the body’s allergic and inflammatory responses. In particular, the goal of this project was to design, express, and purify histamine receptors with the ultimate goal of crystallization. Successive rounds of optimization included the use of recombinant DNA techniques in E.coli to truncate sections of the proteins and the insertion of several fusion partner proteins to improve receptor expression and stability. All constructs were expressed in a Bac-to-Bac baculovirus expression system using Sf9 insect cells, solubilized using n-Dodecyl-β-D-Maltoside (DDM), and purified using immobilized metal affinity chromatography. Constructs were then analyzed by SDS-Page, Western blot, and size-exclusion chromatography to determine their presence, purity, and homogeneity. Along with their expression data from insect cells, the most stable and homogeneous construct from each round was used to design successive optimizations. After 3 rounds of construct design for each receptor, much work remains to produce a stable sample that has the potential to crystallize. Future work includes further optimization of the insertion site of the fusion proteins, ligand screening for co-crystallization, optimization of purification conditions, and screening of potential thermostabilizing point mutations. Success in solving a structure will allow for a more detailed understanding of the receptor function in addition to its vital use in rational drug discovery.
ContributorsCosgrove, Steven Andrew (Author) / Liu, Wei (Thesis director) / Mills, Jeremy (Committee member) / Mazor, Yuval (Committee member) / W. P. Carey School of Business (Contributor) / School of Molecular Sciences (Contributor) / Barrett, The Honors College (Contributor)
Created2016-12
Description
The world today needs novel solutions to address current challenges in areas spanning areas from sustainable manufacturing to healthcare, and biotechnology offers the potential to help address some of these issues. One tool that offers opportunities across multiple industries is the use of nonribosomal peptide synthases (NRPSs). These are modular biological factories with individualized subunits that function in concert to create novel peptides.One element at the heart of environmental health debates today is plastics. Biodegradable alternatives for petroleum-based plastics is a necessity. One NRPS, cyanophycin synthetase (CphA), can produce cyanophycin grana protein (CGP), a polymer composed of a poly-aspartic acid backbone with arginine side chains. The aspartic backbone has the potential to replace synthetic polyacrylate, although current production costs are prohibitive. In Chapter 2, a CphA variant from Tatumella morbirosei is characterized, that produces up to 3x more CGP than other known variants, and shows high iCGP specificity in both flask and bioreactor trials. Another CphA variant, this one from Acinetobacter baylyi, underwent rational protein design to create novel mutants. One, G217K, is 34% more productive than the wild type, while G163K produces a CGP with shorter chain lengths. The current structure refined from 4.4Å to 3.5Å.
Another exciting application of NRPSs is in healthcare. They can be used to generate novel peptides such as complex antibiotics. A recently discovered iterative polyketide synthase (IPTK), dubbed AlnB, produces an antibiotic called allenomycin. One of the modular subunits, a dehydratase named AlnB_DH, was crystallized to 2.45Å. Several mutations were created in multiple active site residues to help understand the functional mechanism of AlnB_DH. A preliminary holoenzyme AlnB structure at 3.8Å was generated although the large disorganized regions demonstrated an incomplete structure. It was found that chain length is the primary factor in driving dehydratase action within AlnB_DH, which helps lend understanding to this module.
ContributorsSwain, Kyle (Author) / Nannenga, Brent (Thesis advisor) / Nielsen, David (Committee member) / Mills, Jeremy (Committee member) / Seo, Eileen (Committee member) / Acharya, Abhinav (Committee member) / Arizona State University (Publisher)
Created2022
Description
In recent years, researchers have employed DNA and protein nanotechnology to develop nanomaterials for applications in the fields of regenerative medicine, gene therapeutic, and materials science. In the current state of research, developing a biomimetic approach to fabricate an extracellular matrix (ECM)-like material has faced key challenges. The difficulty arises due to achieving spatiotemporal complexity that rivals the native ECM. Attempts to replicate the ECM using hydrogels have been limited in their ability to recapitulate its structural and functional properties. Moreover, the biological activities of the ECM, such as cell adhesion, proliferation, and differentiation, are mediated by ECM proteins and their interactions with cells, making it difficult to reproduce these activities in vitro.Thus, the work presented in my dissertation represents efforts to develop DNA and protein-based materials that mimic the biological properties of the ECM. The research involves the design, synthesis, and characterization of nanomaterials that exhibit unique physical, chemical, and mechanical properties. Two specific aspects of the biomimetic system have been to include (1) a modular protein building block to change the bioactivity of the system and (2) to temporally control the self-assembly of the protein nanofiber using different coiled coil mechanisms. The protein nanofibers were characterized using atomic force microscopy, transmission electron microscopy, and super-resolution DNA Point Accumulation for Imaging in Nanoscale Topology. The domains chosen are the fibronectin domains, Fn-III10, Fn-III9-10, and Fn-III12-14, with bioactivity such as cell adhesion and growth factor binding.
To extend this approach, these cys-nanofibers have been embedded in a hyaluronic acid scaffold to enable bioactivity and fibrous morphologies. Nanofiber integration within the HA gel has been shown to promote tunable mechanical properties and architectures, in addition to promoting a temporal display of the protein nanofibers. The hydrogels were characterized using scanning electron microscopy, mechanical compression testing, and fluorescence microscopy. The findings in this dissertation highlight the promise of biomimetic DNA and protein nanomaterials as a versatile approach for developing next-generation materials with unprecedented properties and functions. These findings continue to push the boundaries of what is possible in nanotechnology, leading to new discoveries that will have a significant impact on society.
ContributorsBernal-Chanchavac, Julio (Author) / Stephanopoulos, Nicholas (Thesis advisor) / Jones, Anne (Committee member) / Mills, Jeremy (Committee member) / Arizona State University (Publisher)
Created2023
Description
Exoelectrogenic organisms transfer electrons from their quinone pool to extracellular acceptors over m-scale distances through appendages known as “biological nanowires”. These structures have been described as cytochrome-rich membrane extensions or pili. However, the components and mechanisms of this long-range electron transfer remain largely unknown. This dissertation describes supramolecular assembly of a tetraheme cytochrome into well-defined models of microbial nanowires and uses those structures to explore the mechanisms of ultra-long-range electron transfer. Chiral-induced-spin-selectivity through the cytochrome is also demonstrated. Nanowire extensions in Shewanella oneidensis have been hypothesized to transfer electrons via electron tunneling through proteinaceous structures that reinforce π-π stacking or through electron hopping via redox cofactors found along their lengths. To provide a model to evaluate the possibility of electron hopping along micron-scale distances, the first part of this dissertation describes the construction of a two-component, supramolecular nanostructure comprised of a small tetraheme cytochrome (STC) from Shewanella oneidensis fused to a peptide domain that self-assembles with a β-fibrillizing peptide. Structural and electrical characterization shows that the self-assembled protein fibers have dimensions relevant to understanding ultralong-range electron transfer and conduct electrons along their length via a cytochrome-mediated mechanism of electron transfer. The second part of this dissertations shows that a model three-component fiber construct based on charge complementary peptides and the redox protein can also be assembled. Structural and electrical characterization of the three-component structure also demonstrates desirable dimensions and electron conductivity along the length via a cytochrome-mediated mechanism.
In vivo, it has been hypothesized that cytochromes in the outer surface conduit are spin-selective. However, cytochromes in the periplasm of Shewanella oneidensis have not been shown to be spin selective, and the physiological impact of the chiral-induced-spin-selectivity (CISS) effect on microbial electron transport remains unclear. In the third part of this dissertation, investigations via spin polarization and a spin-dependent conduction study show that STC is spin selective, suggesting that spin selectivity may be an important factor in the electron transport efficiency of exoelectrogens.
In conclusion, this dissertation enables a better understanding of long-range electron transfer in bacterial nanowires and bioelectronic circuitry and offers suggestions for how to construct enhanced biosensors.
ContributorsNWACHUKWU, JUSTUS NMADUKA (Author) / Jones, Anne K. (Thesis advisor) / Mills, Jeremy (Committee member) / Stephanopoulos, Nicholas (Committee member) / Arizona State University (Publisher)
Created2023
Description
Marine algae are a rich source of bioactive halogenated natural products. Thepresence of these marine natural products has largely been attributed to their biosynthesis
by organisms in these environments through a variety of different halogenation
mechanisms. One of the key contributors in these halogenation processes are from the
vanadium haloperoxidases (VHPOs) class of enzymes. VHPOs perform an electrophilic
halogenation through the oxidation of halide ions with hydrogen peroxide as the terminal
oxidant. This technique produces an electrophilic halide equivalent that can directly
halogenate organic substrates. Despite the numerous known reaction capabilities of this
enzyme class, their construction of intramolecular ring formation between a carbon and
nitrogen atom has remained unreported.
Herein, this study presents a development of a ‘new to nature’ chemical reaction for lactam synthesis. In pursuit of this type of reaction, it was discovered that wild type VHPOs (e.g., Curvularia inaequalis, Corallina officinalis, Corallina pilulifera, Acaryochloria marina) produce halogenated iminolactone compounds from acyclic amides in excellent yields and selectivity greater than 99 percent yield. The extension to chlorocyclizations will also be discussed.
ContributorsMerker, Kayla Rose (Author) / Biegasiewicz, Kyle (Thesis advisor) / Ackerman-Biegasiewicz, Laura (Committee member) / Mills, Jeremy (Committee member) / Arizona State University (Publisher)
Created2022
Description
CRISPR-Cas based DNA precision genome editing tools such as DNA Adenine Base Editors (ABEs) could remedy the majority of human genetic diseases caused by point mutations (aka Single Nucleotide Polymorphisms, SNPs). ABEs were designed by fusing CRISPR-Cas9 and DNA deaminating enzymes. Since there is no natural enzyme able to deaminate adenosine in DNA, the deaminase domain of ABE was evolved from an Escherichia coli tRNA deaminase, EcTadA. Initial rounds of directed evolution resulted in ABE7.10 enzyme (which contains two deaminases EcTadA and TadA7.10 fused to Cas9) which was further evolved to ABE8e containing a single TadA8e and Cas9. The original EcTadA as well as the evolved TadA8e where shown to form homodimers in solution. Although it was shown that tRNA binding pocket in EcTadA is composed by both monomers, the significance of TadA dimerization in either tRNA or DNA deamination has not been demonstrated. Here we explore the role of TadA dimerization on the DNA adenosine deamination activity of ABE8e. We hypothesize that the dimerization of TadA8e is more important for the DNA deamination than for the tRNA deamination. To explore this, I conducted a urea titration on ABE8e to disrupt TadA8e dimerization and performed single turnover kinetics assays to assess DNA deamination rate of ABE8e’s. Results showed that DNA deamination rate and efficiency of ABE8e was already impaired at 4M urea and completely lost at 7M. Unfortunately, CD measurements at the equivalent urea concentrations indicate that the loss of activity is due to the unfolding of ABE8e rather than the disruption of TadA8e’s dimerization.
ContributorsBennett, Marisa (Author) / Lapinaite, Audrone (Thesis director) / Mills, Jeremy (Committee member) / Stephanopolous, Nicholas (Committee member) / Barrett, The Honors College (Contributor) / School of Life Sciences (Contributor) / School of Molecular Sciences (Contributor)
Created2023-05
Description
G protein coupled receptors (GPCRs) mediate various of physiologicalactivities which makes them significant drug targets. Determination of atomic level
structure of GPCRs facilitates the structure-based drug design. The most widely
used method currently for solving GPCR structure is still protein crystallography
especially lipidic cubic phase (LCP) crystallization. LCP could mimic the native
environment of membrane protein which stable the membrane proteins. Traditional
synchrotron source requires large size large size protein crystals (>30 micron) due to
the radiation damage during data collection. However, acquiring large sized protein
crystals is challenging and not guaranteed practically. In this study, a novel method
was developed which combined LCP technology and micro-electron diffraction
(MicroED) technology. LCP-MicroED technology was able to collect complete
diffraction data sets from serval submicron protein crystals and deliver high
resolution protein structures. This technology was first confirmed with soluble
protein crystals, proteinase K and small molecule crystals, cholesterol. Furthermore,
this novel method was applied to a human GPCR target, Î22- adrenergic receptor
(Î22AR). The structure model was successfully built which proved the feasibility of
applying LCP-MicroED method to GPCRs and other membrane proteins. Besides, in
this research, a novel human GPCR target, human histamine 4 receptor(H4R) was
studied. Different constructs were expressed, purified, and characterized. Some key
residuals that affect ligand binding were confirmed.
ContributorsJing, Liang (Author) / Mazor, Yuval (Thesis advisor) / Mills, Jeremy (Committee member) / Wang, Xu (Committee member) / Arizona State University (Publisher)
Created2022
Description
Natures hardworking machines, proteins, are dynamic beings. Comprehending the role of dynamics in mediating allosteric effects is paramount to unraveling the intricate mechanisms underlying protein function and devising effective protein design strategies. Thus, the essential objective of this thesis is to elucidate ways to use protein dynamics based tools integrated with evolution and docking techniques to investigate the effect of distal allosteric mutations on protein function and further rationally design proteins. To this end, I first employed molecular dynamics (MD) simulations, Dynamic Flexibility Index (DFI) and Dynamic Coupling Index (DCI) on PICK1 PDZ, Butyrylcholinesterase (BChE), and Dihydrofolate reductase (DHFR) to uncover how these proteins utilize allostery to tune activity. Moreover, a new classification technique (“Controller”/“Controlled”) based on asymmetry in dynamic coupling is developed and applied to DHFR to elucidate the effect of allosteric mutations on enzyme activity. Subsequently, an MD driven dynamics design approach is applied on TEM-1 β-lactamase to tailor its activity against β-lactam antibiotics. New variants were created, and using a novel analytical approach called "dynamic distance analysis" (DDA) the degree of dynamic similarity between these variants were quantified. The experimentally confirmed results of these studies showed that the implementation of MD driven dynamics design holds significant potential for generating variants that can effectively modulate activity and stability. Finally, I introduced an evolutionary guided molecular dynamics driven protein design approach, integrated co-evolution and dynamic coupling (ICDC), to identify distal residues that modulate binding site dynamics through allosteric mechanisms. After validating the accuracy of ICDC with a complete mutational data set of β-lactamase, I applied it to Cyanovirin-N (CV-N) to identify allosteric positions and mutations that can modulate binding affinity. To further investigate the impact of mutations on the identified allosteric sites, I subjected putative mutants to binding analysis using Adaptive BP-Dock. Experimental validation of the computational predictions demonstrated the efficacy of integrating MD, DFI, DCI, and evolution to guide protein design. Ultimately, the research presented in this thesis demonstrates the effectiveness of using evolutionary guided molecular dynamics driven design alongside protein dynamics based tools to examine the significance of allosteric interactions and their influence on protein function.
ContributorsKazan, Ismail Can (Author) / Ozkan, Sefika Banu (Thesis advisor) / Ghirlanda, Giovanna (Thesis advisor) / Mills, Jeremy (Committee member) / Beckstein, Oliver (Committee member) / Arizona State University (Publisher)
Created2023
Description
Since understanding the nature of proteins, it has been a long held belief that protein sequence dictated structure which then determined function. As such, all proteins contained structure and those that did not must not serve a purpose. For the last 25 years, scientists have begun to understand that disordered proteins, lacking structure, did not lack function. Their unique ability to undergo liquid-liquid phase separation served a cellular purpose, most involving nucleic acids. As more is uncovered, these unique proteins are being used to build new systems. Phase separated disordered proteins were used to design a functional organelle using the enzyme horseradish peroxidase and its chromatic substrate ABTS. Upon doing so, it was discovered that disordered proteins are highly susceptible to chemical modification through radical reactions with tyrosine. The increased frequency of tyrosine in disordered proteins provides multiple sites of conjugation by the ABTS radical and other substrates. These modifications then alter the physical properties of the proteins. The phase separated system was also incorporated with shell proteins from bacterial microcompartments in an attempt to limit access to the droplets. Through expression with truncations of the disordered sequence, shell proteins were able to interact with the droplets. Despite the appearance of complete coatings, they were found to be permeable to their surroundings, though much more stable than uncoated droplets. Just as disordered proteins are considered outside the traditional structures, so too are many students entering higher education. Non-traditional students are becoming more prevalent in the undergraduate population, though they are woefully underrepresented in the natural sciences. The benefits these students bring to their programs is highlighted and the circumstances that drive them away from STEM is explored. Non-traditional students contribute to the diversity of the scientific population, though many pursue education in non-STEM fields. To support these students, focus is put on andragogy (the teaching of adults), rather than pedagogy (the teaching of children). Non-traditional students face isolation and discrimination that is not being addressed by higher education institutions, hindering their ability to succeed. Through infrastructure designed for adult learners, STEM fields can be diversified in non-traditional ways.
ContributorsCostantino, Michele (Author) / Ghirlanda, Giovanna (Thesis advisor) / Mills, Jeremy (Committee member) / Matyushov, Dmitry (Committee member) / Arizona State University (Publisher)
Created2024