Your search keyword '"Alison M. Maxwell"' showing total 4 results

1. Robust Sequence Determinants of α-Synuclein Toxicity in Yeast Implicate Membrane Binding

Author

Zun Zar Chi Naing, Maru Jaime-Garza, Taia S. Wu, Laurel S Estes, Martin Kampmann, Eric D. Chow, Taylor B. Cavazos, Miriam A. Goldman, Yessica K. Gomez, William F. DeGrado, Stephanie A. Wankowicz, Matthew C. Johnson, Christa Caggiano, Christina A. Stephens, Bryan Faust, Daniel Barrero, Lakshmi E. Miller-Vedam, Elizabeth E. McCarthy, Kyle E. Lopez, Sy Redding, Jenna Pellegrino, Elissa A Fink, Wren Saylor, Alison M Maxwell, Hayarpi Torosyan, Jared Lumpe, Robert W. Newberry, George C. Hartoularos, Daniel M. C. Schwarz, Calla Martyn, Laura M. Gunsalus, Jack Strickland, Maureen Pittman, Taylor Arhar, Andrew F. Kung, Daniel R. Wong, Garrett Wong, Nishith R. Reddy, Matthew G. Jones, Aji Palar, Erik J. Navarro, Nick Hoppe, M. Grace Gordon, Douglas R. Wassarman, Jean Costello, and Adam Catching

Subjects

0301 basic medicine, Protein Conformation, Mutant, Context (language use), Saccharomyces cerevisiae, Neurodegenerative, medicine.disease_cause, 01 natural sciences, Biochemistry, Article, 03 medical and health sciences, 0302 clinical medicine, Protein structure, Genetics, medicine, 2.1 Biological and endogenous factors, Humans, Amino Acid Sequence, Aetiology, Peptide sequence, 030304 developmental biology, Mutation, 0303 health sciences, Parkinson's Disease, 010405 organic chemistry, Chemistry, C-terminus, Organic Chemistry, Neurosciences, Parkinson Disease, General Medicine, Biological Sciences, Small molecule, Yeast, Brain Disorders, 0104 chemical sciences, 030104 developmental biology, Proteostasis, Chemical Sciences, alpha-Synuclein, Biophysics, Molecular Medicine, Generic health relevance, Chemical genetics, 030217 neurology & neurosurgery

Abstract

Protein conformations are shaped by cellular environments, but how environmental changes alter the conformational landscapes of specific proteins in vivo remains largely uncharacterized, in part due to the challenge of probing protein structures in living cells. Here, we use deep mutational scanning to investigate how a toxic conformation of α-synuclein, a dynamic protein linked to Parkinson’s disease, responds to perturbations of cellular proteostasis. In the context of a course for graduate students in the UCSF Integrative Program in Quantitative Biology, we screened a comprehensive library of α-synuclein missense mutants in yeast cells treated with a variety of small molecules that perturb cellular processes linked to α-synuclein biology and pathobiology. We found that the conformation of α-synuclein previously shown to drive yeast toxicity—an extended, membrane-bound helix—is largely unaffected by these chemical perturbations, underscoring the importance of this conformational state as a driver of cellular toxicity. On the other hand, the chemical perturbations have a significant effect on the ability of mutations to suppress α-synuclein toxicity. Moreover, we find that sequence determinants of α-synuclein toxicity are well described by a simple structural model of the membrane-bound helix. This model predicts that α-synuclein penetrates the membrane to constant depth across its length but that membrane affinity decreases toward the C terminus, which is consistent with orthogonal biophysical measurements. Finally, we discuss how parallelized chemical genetics experiments can provide a robust framework for inquiry-based graduate coursework.

Published

2020

2. De novo design of a hyperstable non-natural protein–ligand complex with sub-Å accuracy

Author

David N. Beratan, Alison M Maxwell, Yibing Wu, Michael J. Therien, William F. DeGrado, Jeff Rawson, Thomas Lemmin, Shao-Qing Zhang, and Nicholas F. Polizzi

Subjects

Models, Molecular, 0301 basic medicine, Porphyrins, Chemistry, Novel protein, Stereochemistry, Extramural, General Chemical Engineering, Protein design, Temperature, Proteins, General Chemistry, Ligands, 010402 general chemistry, 01 natural sciences, Porphyrin, Article, 0104 chemical sciences, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Protein–ligand complex, Side chain

Abstract

If we truly understand proteins, we should be able to design functional proteins purposefully from scratch. While the de novo design of proteins has seen many successes1–11, no small molecule ligand- or organic cofactor-binding protein has been designed entirely from first principles to achieve i) a unique structure and ii) a predetermined binding-site geometry with sub-Å accuracy. Such achievements are prerequisites for the design of proteins that control and enable complex reaction trajectories, where the relative placements of cofactors, substrates, and protein side chains must be established within the length scale of a chemical bond. Here, we develop and test a strategy for design of small molecule-binding proteins, based on the concept that the entire protein contributes to establishing the binding geometry of a ligand12–15. Hence, what are traditionally considered as separate sectors – the hydrophobic core and ligand-binding site – we treat as an inseparable unit. We utilize flexible backbone sequence design of a parametrically defined protein template to simultaneously pack the protein interior both proximal to and remote from the ligand-binding site. Thus, tight interdigitation of core side chains quite removed from the binding site structurally restrains the first- and second-shell packing around the ligand. We apply this principle to the decades-old problem of structural non-uniqueness in de novo-designed heme-binding proteins16. We designed a novel protein, PS1, which binds a highly electron-deficient, non-natural porphyrin at temperatures up to 100 °C. The high-resolution structure of holo-PS1 is in sub-Å agreement with the design. The structure of apo-PS1 retains the remote core packing of the holo, predisposing a flexible binding region for the desired ligand-binding geometry. Our results reveal the unification of core packing and binding site definition as an essential principle of ligand-binding protein design.

Published

2017

3. Extending chemical perturbations of the ubiquitin fitness landscape in a classroom setting reveals new constraints on sequence tolerance

Author

Danielle L. Swaney, Alexander M. Wolff, Tamas L. Nagy, Douglas Myers-Turnbull, Douglas R. Wassarman, Kyle A. Barlow, Paul V. Thomas, Rachel M. Brunetti, Derek Britain, Kevin Lou, Sy Redding, Wesley M. Marin, Mary K. Tsai, Kurt S. Thorn, Ryan W. Tibble, Lillian R. Kenner, Daniel M. C. Schwarz, Charlotte A. Nelson, Bruk Mensa, Fatima S. Ugur, Derek Bogdanoff, Taia S. Wu, E. Kang, Nicholas J. Rettko, Leanna S. Morinishi, Peter F. McTigue, Martin Kampmann, Gabriel K. Reder, Eric D. Chow, Alison M Maxwell, Jason Town, James S. Fraser, Andrew M. Natale, David P. Bauer, Cole Helsell, Joseph L. DeRisi, Yuliya Birman, Pooja Suresh, Evan M. Green, Ruilin Tian, Jennifer Y. Li, Sergei Pourmal, Weilin Chen, Hiten D. Madhani, Daniel N. Bolon, Miles Sasha Dickinson, Shane O’Conchúir, Keely Oltion, Daniel Asarnow, Peter J. Rohweder, Susanna K. Elledge, David Mavor, Erin M. Poss, Matvei S. Khoroshkin, Beatrice Ary, Ian D. Bergman, Nadja Kern, Taylor Arhar, Lisa L. Kirkemo, Tanja Kortemme, Sophia K. Tan, Shizhong Dai, Greyson R. Lewis, Nathan L. Hendel, and Cynthia M. Chio

Subjects

0301 basic medicine, QH301-705.5, Fitness landscape, Evolution, Science, Computational biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Cobalt acetate, Protein sequencing, Ubiquitin, Biology (General), Selection (genetic algorithm), Sequence (medicine), biology, Tunicamycin, 030104 developmental biology, chemistry, Mutation (genetic algorithm), biology.protein, Other Biological Sciences, General Agricultural and Biological Sciences, Deep mutational scanning, 030217 neurology & neurosurgery, Research Article

Abstract

Although the primary protein sequence of ubiquitin (Ub) is extremely stable over evolutionary time, it is highly tolerant to mutation during selection experiments performed in the laboratory. We have proposed that this discrepancy results from the difference between fitness under laboratory culture conditions and the selective pressures in changing environments over evolutionary timescales. Building on our previous work (Mavor et al., 2016), we used deep mutational scanning to determine how twelve new chemicals (3-Amino-1,2,4-triazole, 5-fluorocytosine, Amphotericin B, CaCl2, Cerulenin, Cobalt Acetate, Menadione, Nickel Chloride, p-Fluorophenylalanine, Rapamycin, Tamoxifen, and Tunicamycin) reveal novel mutational sensitivities of ubiquitin residues. Collectively, our experiments have identified eight new sensitizing conditions for Lys63 and uncovered a sensitizing condition for every position in Ub except Ser57 and Gln62. By determining the ubiquitin fitness landscape under different chemical constraints, our work helps to resolve the inconsistencies between deep mutational scanning experiments and sequence conservation over evolutionary timescales., Summary: We organized a project-based course that used deep mutational scanning of ubiquitin to resolve the inconsistencies between tolerance to mutations in laboratory conditions and sequence conservation over evolutionary timescales.

Published

2018

4. Structural heterogeneity and intersubject variability of Aβ in familial and sporadic Alzheimer’s disease

Author

William F. DeGrado, Stanley B. Prusiner, Yibing Wu, Mimi Nick, Alison M Maxwell, Lars Lannfelt, Joel C. Watts, Thomas Lemmin, Martin Ingelsson, Sjoerd G. van Duinen, Caroline Graff, Thomas D. Bird, Kurt Giles, Jan Stöhr, Abby Oehler, C. Dirk Keene, Carlo Condello, and Christoffer D Caro

Subjects

0301 basic medicine, Protein Folding, Aging, Medicin och hälsovetenskap, Protein Conformation, conformational strains, Mutant, spectral imaging, Neurodegenerative, Medical and Health Sciences, Transgenic, Mice, 0302 clinical medicine, 2.1 Biological and endogenous factors, Alzheimer's Disease including Alzheimer's Disease Related Dementias, Aetiology, protein misfolding, education.field_of_study, Multidisciplinary, Chemistry, Biological Sciences, Alzheimer's disease, Phenotype, amyloid-beta, 3. Good health, PNAS Plus, Neurological, Cerebral amyloid angiopathy, Alzheimer’s disease, Genetically modified mouse, Amyloid, Population, Mice, Transgenic, amyloid-β, 03 medical and health sciences, Alzheimer Disease, Acquired Cognitive Impairment, medicine, Animals, Point Mutation, education, Amyloid beta-Peptides, Point mutation, Neurosciences, Alzheimer's Disease including Alzheimer's Disease Related Dementias (AD/ADRD), medicine.disease, Molecular biology, Brain Disorders, 030104 developmental biology, Dementia, 030217 neurology & neurosurgery, Neuroscience

Abstract

Significance An expanding body of evidence argues that the Aβ and tau proteins share important characteristics of prion propagation to cause pathogenesis in Alzheimer’s disease (AD). Aβ and tau form a number of amyloids (β-sheet–rich structures) with distinct conformations (“strains”), some of which give rise to different diseases and associated pathologies. We develop new probes of amyloid structure and use these to identify conformational strains of Aβ in heritable and sporadic forms of AD patient samples. We demonstrate that distinct strains of Aβ can be discerned in different disease types, or in different brain compartments within a given patient. Our findings may potentially explain the spectrum of clinical and pathologic features observed in AD., Point mutations in the amyloid-β (Aβ) coding region produce a combination of mutant and WT Aβ isoforms that yield unique clinicopathologies in familial Alzheimer’s disease (fAD) and cerebral amyloid angiopathy (fCAA) patients. Here, we report a method to investigate the structural variability of amyloid deposits found in fAD, fCAA, and sporadic AD (sAD). Using this approach, we demonstrate that mutant Aβ determines WT Aβ conformation through prion template-directed misfolding. Using principal component analysis of multiple structure-sensitive fluorescent amyloid-binding dyes, we assessed the conformational variability of Aβ deposits in fAD, fCAA, and sAD patients. Comparing many deposits from a given patient with the overall population, we found that intrapatient variability is much lower than interpatient variability for both disease types. In a given brain, we observed one or two structurally distinct forms. When two forms coexist, they segregate between the parenchyma and cerebrovasculature, particularly in fAD patients. Compared with sAD samples, deposits from fAD patients show less intersubject variability, and little overlap exists between fAD and sAD deposits. Finally, we examined whether E22G (Arctic) or E22Q (Dutch) mutants direct the misfolding of WT Aβ, leading to fAD-like plaques in vivo. Intracerebrally injecting mutant Aβ40 fibrils into transgenic mice expressing only WT Aβ induced the deposition of plaques with many biochemical hallmarks of fAD. Thus, mutant Aβ40 prions induce a conformation of WT Aβ similar to that found in fAD deposits. These findings indicate that diverse AD phenotypes likely arise from one or more initial Aβ prion conformations, which kinetically dominate the spread of prions in the brain.

Published

2018