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- Creators: Arizona State University
Description
Membrane proteins act as sensors, gatekeepers and information carriers in the cell membranes. Functional engineering of these proteins is important for the development of molecular tools for biosensing, therapeutics and as components of artificial cells. However, using protein engineering to modify existing protein structures is challenging due to the limitations of structural changes and difficulty in folding polypeptides into defined protein structures. Recent studies have shown that nanoscale architectures created by DNA nanotechnology can be used to mimic various protein functions, including some membrane proteins. However, mimicking the highly sophisticated structural dynamics of membrane proteins by DNA nanostructures is still in its infancy, mainly due to lack of transmembrane DNA nanostructures that can mimic the dynamic behavior, ubiquitous to membrane proteins. Here, I demonstrate design of dynamic DNA nanostructures to mimic two important class of membrane proteins. First, I describe a DNA nanostructure that inserts through lipid membrane and dynamically reconfigures upon sensing a membrane-enclosed DNA or RNA target, thereby transducing biomolecular information across the lipid membrane similar to G-protein coupled receptors (GPCR’s). I use the non-destructive sensing property of our GPCR-mimetic nanodevice to sense cancer associated micro-RNA biomarkers inside exosomes without the need of RNA extraction and amplification. Second, I demonstrate a fully reversibly gated DNA nanopore that mimics the ligand mediated gating of ion channel proteins. The 20.4 X 20.4 nm-wide channel of the DNA nanopore allows timed delivery of folded proteins across synthetic and biological membranes. These studies represent early examples of dynamic DNA nanostructures in mimicking membrane protein functions. I envision that they will be used in synthetic biology to create artificial cells containing GPCR-like and ion channel-like receptors, in site-specific drug or vaccine delivery and highly sensitive biosensing applications.
ContributorsDey, Swarup (Author) / Yan, Hao (Thesis advisor) / Hariadi, Rizal F (Thesis advisor) / Liu, Yan (Committee member) / Stephanopoulos, Nicholas (Committee member) / Arizona State University (Publisher)
Created2021
Description
The understanding of protein functions in vivo is very important since the protein is the building block of a cell. Cryogenic electron microscopy (cryo-EM) is capable of visualizing protein samples in their near-native states in high-resolution details. Cryo-EM enables the visualization of biomolecular structures at multiscale ranging from a cellular structure to an atomic structure of protein subunit.Neurodegenerative diseases, like Alzheimer’s disease and frontotemporal dementia, have multiple dysregulated signaling pathways. In my doctoral studies, I investigated two protein complexes relevant to these disorders: one is the proNGF- p75 neurotrophin receptor (p75NTR)- sortilin neurotrophin complex and the other is the p97R155H mutant complex. The neurotrophins are a family of soluble basic growth factors involved in the development, maintenance, and proliferation of neurons in the central nervous system (CNS) and peripheral nervous system (PNS). The ligand for the neuronal receptors dictates the fate of the neuronal cells. My studies focused on understanding the binding interfaces between the proteins in the proNGF-p75NTR-sortilin neuronal apoptotic complex. I have performed the biochemical characterization of the complex to understand how the complex formation occurs.
Single amino-acid mutation of R155H on the N-domain of p97 is known to be the prevalent mutation in 40% patients suffering from neurodegenerative disease. The p97R155H mutant exhibits abnormal ATPase activity and cofactor dysregulation. I pursued biochemical characterization in combination with single-particle cryo-EM to explore the interaction of p97R155H mutant with its cofactor p47 and determined the full-length structures of the p97R155H-p47 assemblies for the first time. About 40% p97R155H organizes into higher order dodecamers, which lacks nucleotide binding, does not bind to p47, and closely resembles the structure of p97 bound with an adenosine triphosphate (ATP)-competitive inhibitor, CB-5083, suggesting an inactive state of the p97R155H mutant. The structures also revealed conformational changes of the arginine fingers which might contribute to the elevated p97R155H ATPase activity. Because the D1-D2 domain communication is important in regulating the ATPase function, I further studied the functions of the conserved L464 residue on the D1-D2 linker using mutagenesis and single-particle cryo-EM. The biochemical and structural results suggested the torsional constraint of the D1-D2 linker likely modulates the D2 ATPase activity. Our studies thus contributed to develop deeper knowledge of the intricate cellular mechanisms and the proteins affected in disease pathways.
ContributorsNandi, Purbasha (Author) / Chiu, Po-Lin (Thesis advisor) / Mazor, Yuval (Committee member) / Hansen, Debra T (Committee member) / Arizona State University (Publisher)
Created2022
Description
Molecular structures and dynamics in amorphous materials present unique experimental challenges compared with the characterization of crystalline solids. Liquids and glassy solids have many applications in industry such as ionic liquids for fuel cells or biomolecule stabilizing agents, enhancing pharmaceuticals dissolution rates, and modified high performance biopolymers like silk for textile, biomedical, drug delivery, among many others. Amorphous materials are metastable, with kinetic profiles of phase transitions depending on relaxation dynamics, thermal history, plus factors such as temperature, pressure, and humidity. Understanding molecular structure and phase transitions of amorphous states of small molecules and biopolymers is broadly important for realizing their applications. The structure of liquid and glassy states of the drugs carbamazepine (CBZ) and indomethacin (IMC) were studied with solid-state nuclear magnetic resonance (ssNMR) spectroscopy, high energy X-ray diffraction, Fourier Infrared Transform Spectroscopy (FTIR), differential scanning calorimetry (DSC), and Empirical Potential Structure Refinement (EPSR). Both drugs have multiple crystalline polymorphs with slow dissolution kinetics, necessitating stable glassy or polymer dispersed formulations. More hydrogen bonds per CBZ molecule and a larger distribution of oligomeric states in the glass versus the liquid than expected. The chlorobenzyl ring of crystalline and glassy IMC measured with ssNMR were surprisingly found to have similar mobility. Crucially, humidity strongly affects glass structure, highlighting the importance of combining modeling techniques like EPSR with careful sample preparation for proper interpretation. Highly basic protic ionic liquids with low ∆pKa were synthesized with metathesis rather than proton transfer and characterized using NMR and dielectric spectroscopy. Finally, the protein secondary structure of spider egg sac silk was studied using ssNMR, FTIR, and scanning electron microscopy. Tubuliform silk found in spider egg sacs has extensive β-sheet domains which form nanocrystallites within an amorphous matrix. Structural predictions and spectroscopic measurements of tubuliform silk solution are mostly α-helical, with the mechanism of structural rearrangement to the β-sheet rich fiber unknown. The movement of spiders during egg silk spinning make in situ experiments difficult practically. This work is the first observation that tubuliform silk of Argiope aurantia after liquid crystalline spinning exits the spinneret as a predominantly (~70%) β-sheet fiber.
ContributorsEdwards, Angela Diane (Author) / Yarger, Jeffery L (Thesis advisor) / Liu, Yan (Committee member) / Mujica, Vladimiro (Committee member) / Arizona State University (Publisher)
Created2022
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
Transportation of material across a cell membrane is a vital process for maintaininghomeostasis. Na+/H+ antiporters, for instance, help maintain cell volume and regulate
intracellular sodium and proton concentrations. They are prime drug targets, since
dysfunction of these crucial proteins in humans is linked to heart and neurodegenerative
diseases. Due to their placement in a cell membrane, their study is particularly difficult
compared to globular proteins, which is likely the reason the transport mechanisms
for these proteins are not entirely known. This work focuses on the electrogenic
bacterial homologs Thermus thermophilus NapA (TtNapA) and Echerichia coli NhaA
(EcNhaA), each transporting one sodium from the interior of the cell for two protons
on outside of the cell. Even though X-ray crystal structures for both of these systems
have been resolved, their study through molecular dynamics (MD) simulations is
limited. The dynamic protonation and deprotonation of the binding site residues is
a fundamental process in the transport cycle, which currently cannot be explored
intuitively with standard MD methodologies. Apart from this limitation, simulation
performance is only a fraction of what is needed to understand the full transport
process, particularly when it comes to global conformational changes. This work
seeks to overcome these limitations through the development and application of a
multiscale thermodynamic and kinetic framework for constructing models capable of
predicting experimental observables, such as the dependence of transporter turnover
on membrane voltage. These models allow interpretation of the effects of individual
processes on the function as a whole. This procedure is demonstrated for TtNapA and
the connection between structure and function is shown by computing cycle turnover
across a range of non-equilibrium conditions.
ContributorsKenney, Ian Michael (Author) / Beckstein, Oliver (Thesis advisor) / Ozkan, Sefika Banu (Committee member) / Heyden, Matthias (Committee member) / Vaiana, Sara (Committee member) / Arizona State University (Publisher)
Created2022
Description
Protein interactions with the environment are crucial for proper function, butinteraction mechanisms are not always understood. In G protein-coupled receptors
(GPCRs), cholesterol modulates the function in some, but not all, GPCRs. Coarse
grained molecular dynamics was used to determine a set of contact events for each
residue and fit to a biexponential to determine the time scale of the long contacts
observed in simulation. Several residues of interest were indicated in CCK1 R near
Y140, which is known to render CCK1 R insensitive to cholesterol when mutated to
alanine. A difference in the overall residence time between CCK1 R and its cholesterol
insensitive homologue CCK2 R was also observed, indicating the ability to predict
relative cholesterol binding for homologous proteins.
Occasionally large errors and poor fits to the data were observed, so several
improvements were made, including generalizing the model to include K exponential
components. The sets of residence times in the improved method were analyzed using
Bayesian nonparametrics, which allowed for error estimations and the classification of
contact events to the individual components. Ten residues in three GPCRs bound to
cholesterol in experimental structures had large tau. Slightly longer overall interaction
time for the cholesterol sensitive CB1 R over its insensitive homologue CB2 R was also
observed.
The interactions between the cystic fibrosis transmembrane conductance regulator
(CFTR) and GlyH-101, an open-channel blocker, were analyzed using molecular
dynamics. The results showed the bromine in GlyH-101 was in constant contact with
F337, which is just inside the extracellular gate. The simulations also showed an
insertion of GlyH-101 between TM1 and TM6 deeper than the starting binding pose.
Once inserted deeper between TMs 1 and 6, the number of persistent contacts also
increased. This proposed binding pose may help in future investigations of CFTR
and help determine an open-channel structure for the protein, which in turn may help
in the development of treatments for various medical conditions. Overall, the use
of molecular dynamics and state of the art analysis tools can be useful in the study
of membrane proteins and eventuallyin the development of treatments for ailments
stemming from their atypical function.
ContributorsSexton, Ricky (Author) / Beckstein, Oliver (Thesis advisor) / Presse, Steve (Committee member) / Ozkan, Sefika B. (Committee member) / Hariadi, Rizal (Committee member) / Arizona State University (Publisher)
Created2022
Description
Enzymes keep life nicely humming along by catalyzing important reactions at relevant timescales. Despite their immediate importance, how enzymes recognize and bind their substrate in a sea of cytosolic small molecules, carry out the reaction, and release their product in microseconds is still relatively opaque. Methods to elucidate enzyme substrate specificity indicate that the shape of the active site and the amino acid residues therein play a major role. However, lessons from Directed Evolution experiments reveal the importance of residues far from the active site in modulating substrate specificity. Enzymes are dynamic macromolecules composed of networks of interactions integrating the active site, where the chemistry occurs, to the rest of the protein. The objective of this work is to develop computational methods to modify enzyme ligand specificity, either through molding the active site to accommodate a novel ligand, or by identifying distal mutations that can allosterically alter specificity. To this end, two homologues in the β-lactamase family of enzymes, TEM-1, and an ancestrally reconstructed variant, GNCA, were studied to identify whether the modulation of position-specific distal-residue flexibility could modify ligand specificity. RosettaDesign was used to create TEM-1 variants with altered dynamic patterns. Experimental characterization of ten designed proteins indicated that mutations to residues surrounding rigid, highly coupled residues substantially affected both enzymatic activity and stability. In contrast, native-like activities and stabilities were maintained when flexible, uncoupled residues, were targeted. Five of the TEM-1 variants were crystallized to see if the changes in function observed were due to architectural changes to the active site. In a second project, a computational platform using RosettaDesign was developed to remodel the firefly luciferase active site to accommodate novel luciferins. This platform resulted in the development of five luciferin-luciferase pairs with red-shifted emission maxima, ready for multicomponent bioluminescent imaging applications in tissues. Although the projects from this work focus on two classes of proteins, they provide insight into the structure-function relationship of ligand specificity in enzymes and are broadly applicable to other systems.
ContributorsKolbaba Kartchner, Bethany (Author) / Mills, Jeremy H (Thesis advisor) / Ghirlanda, Giovanna (Committee member) / Van Horn, Wade D (Committee member) / Arizona State University (Publisher)
Created2023
Description
Receiving signals and responding to the environment is crucial for survival for every living organism. One of those signals is being able to detect environmental and visceral temperatures. Transient receptor potential vanilloid 1 (TRPV1) and transient receptor potential melastatin 8 (TRPM8) are ion channels within cells that allow higher organisms to detect hot and cold temperatures, respectively. These TRP channels are also implicated in diverse physiological roles including pain, obesity, and cancer. As a result, these channels have garnered interest as potential targets for therapeutic interventions. However, the entanglement of TRPV1 and TRPM8 polymodal activation where it responds to a variety of different stimuli has caused adverse side effects of body thermal dysregulation and misregulation when antagonizing these channels as drug targets. This dissertation will dissect the molecular mechanism and regulation of TRPV1 and TRPM8. An in-depth look into the complex and conflicting results in trying to find the key area for thermosensation as well as looking into disentangling the polymodal activation modes in TRPV1. The regulatory mechanism between TRPM8 with phosphoinositide interacting regulator of TRPs (PIRT) and calmodulin will be examined using nuclear magnetic resonance (NMR). A computational, experimental, and methodical approach into ancestral TRPM8 orthologs using whole-cell patch-clamp electrophysiology, calcium mobilization assay, and cellular thermal shift assay (CETSA) to determine whether these modes of activation can be decoupled. Lastly, smaller studies are covered like developing a way to delivery full-length and truncated protein using amphipols to artificial and live cells without the biological regulatory processes and the purification of the TRPM8 transmembrane domain (TMD). In the end, two successful methods were developed to study the polymodal activation of proteins.
ContributorsLuu, Dustin Dean (Author) / Van Horn, Wade D (Thesis advisor) / Redding, Kevin E (Committee member) / Chiu, Po-Lin (Committee member) / Arizona State University (Publisher)
Created2023
Description
Transition metal ions such as Zn2+, Mn2+, Co2+, and Fe2+ play crucial roles in organisms from all kingdoms of life. The homeostasis of these ions is mainly regulated by a group of secondary transporters from the cation diffusion facilitator (CDF) family. The mammalian zinc transporters (ZnTs), a subfamily of CDF, have been an important target for study as they are associated with several diseases, such as diabetes, delayed growth and osteopenia, Alzheimer’s disease, and Parkinsonism. The bacterial homolog of ZnTs, YiiP, is the first CDF transporter with a determined structure and is used as a model for studying the structural and mechanistic properties of CDF transporters. On the other hand, Molecular dynamics simulation has emerged as a valuable computational tool for exploring the physical basis of biological macromolecules' structure and function with atomic precision at femtosecond resolution. This work aims to elucidate the roles of the three Zn$2+ binding sites found on each YiiP protomer and the role of protons in the transport process of CDFs, which remain under debate despite previous thermodynamic and structural studies on YiiP. Cryo-EM, microscale thermophoresis (MST) and molecular dynamics (MD) simulations were used to address these questions. With a Zn2+ model that accurately reproduces experimental structures of the binding clusters, the dynamical influence of zinc binding on the transporter was accessed through MD simulations, which was consistent with the new cryo-EM structures. Zinc binding affinities obtained through MST were used to infer the stoichiometry of Zn2+/H+ antiport in combination with a microscopic thermodynamic model and constant pH simulations. The most likely microstates of H$^+$ and Zn2+ binding indicated a transport stoichiometry of 1 Zn2+ to 2-3 H+ depending on the external pH. A model describing the entire transport cycle of YiiP was finally built on these findings, providing insight into the structural and mechanistic properties of CDF transporters.
ContributorsFan, Shujie (Author) / Beckstein, Oliver (Thesis advisor) / Ozkan, Banu (Committee member) / Heyden, Matthias (Committee member) / Van Horn, Wade (Committee member) / Arizona State University (Publisher)
Created2023
Description
To understand the mechanism behind real-life phenomena, e.g., bacterial infection, metabolic disorders and cancer, it is becoming more and more necessary to get to the level of individual cells and single molecules. This dissertation focuses on the application of atomic force microscopy and nanopore translocation related techniques to study microbial surface characteristics and single molecule properties at the nanoscale. At the cellular level, surface characteristics of single wild type and phoP mutant Salmonella typhimurium cells were analyzed to get a better understanding about the resistance of Salmonella typhimurium to antibiotics. These bacteria were grown under different 〖Mg〗^(2+) concentrations. 〖Mg〗^(2+) is known to modulate the activities of phoP gene which regulates surface structure modifications of Salmonella typhimurium. Wild type Salmonella typhimurium surfaces were found to have an average roughness of 6.6 ± 0.9 nm for high 〖Mg〗^(2+) and 6.0 ± 1.3 nm for low 〖Mg〗^(2+) concentrations, rougher than the 5.3 ± 1.1 nm (high 〖Mg〗^(2+)) and 5.6 ± 1.5 nm (low 〖Mg〗^(2+)) for phoP mutant. In addition, mutant Salmonella typhimurium have average surface potentials of -40 ± 19 mV (high 〖Mg〗^(2+)) and 20 ± 33 mV (low 〖Mg〗^(2+)), comparing to the -65 ± 23 mV (high 〖Mg〗^(2+)) and -71 ± 27 mV (low 〖Mg〗^(2+)) of wild-type bacteria. These significant surface characteristics differences will provide insights in the important role of the phoP gene in regulating Salmonella typhimurium surface structures. On the single-molecule level, the forming components of chromatin from two esophagus cell lines, one normal (EPC2) and one cancerous (CPD), were studied using atomic force microscopy (AFM) recognition imaging. Both EPC2 and CPD chromatin samples were found to contain histone H3 and SMC2, a subunit of the condensin complex. Western blotting results supported this conclusion. Further, DNA translocation speeds through a nanopore were controlled by utilizing rolling circle replication (RCR) with Φ29 polymerases. This is a major part for future sequencing single glycosaminoglycan (GAG) molecules to resolve their structures. Translocation time on the scale of seconds, which is much longer compared to the translocation of free DNA molecules, had been detected, indicating that the polymerase successfully controlled the translocation process.
ContributorsLiu, Jiawei (Author) / Ros, Robert RR (Thesis advisor) / Lindsay, Stuart SL (Committee member) / Wang, Xu XW (Committee member) / Hariadi, Rizal RH (Committee member) / Arizona State University (Publisher)
Created2022