Your search keyword '"Nicholas F. Polizzi"' showing total 22 results

1. Inhibitor binding mode and allosteric regulation of Na + -glucose symporters

Author

Paola Bisignano, Chiara Ghezzi, Hyunil Jo, Nicholas F. Polizzi, Thorsten Althoff, Chakrapani Kalyanaraman, Rosmarie Friemann, Matthew P. Jacobson, Ernest M. Wright, and Michael Grabe

Subjects

Science

Abstract

Sodium-dependent glucose transporters (SGLTs) transport sugars across the plasma membrane and play important roles in renal sugar reabsorption. Here authors develop structural models of human SGLT1/2 (hSGLT1/2) in complex with inhibitors which helps to understand inhibitor subtype selectivity.

Published

2018

2. Allosteric mechanism of signal transduction in the two-component system histidine kinase PhoQ

Author

Bruk Mensa, Nicholas F Polizzi, Kathleen S Molnar, Andrew M Natale, Thomas Lemmin, and William F DeGrado

Subjects

histidine kinase, signal transduction, HAMP, PhoQ, allostery, Medicine, Science, Biology (General), QH301-705.5

Abstract

Transmembrane signaling proteins couple extracytosolic sensors to cytosolic effectors. Here, we examine how binding of Mg2+ to the sensor domain of an E. coli two component histidine kinase (HK), PhoQ, modulates its cytoplasmic kinase domain. We use cysteine-crosslinking and reporter-gene assays to simultaneously and independently probe the signaling state of PhoQ’s sensor and autokinase domains in a set of over 30 mutants. Strikingly, conservative single-site mutations distant from the sensor or catalytic site strongly influence PhoQ’s ligand-sensitivity as well as the magnitude and direction of the signal. Data from 35 mutants are explained by a semi-empirical three-domain model in which the sensor, intervening HAMP, and catalytic domains can adopt kinase-promoting or inhibiting conformations that are in allosteric communication. The catalytic and sensor domains intrinsically favor a constitutively ‘kinase-on’ conformation, while the HAMP domain favors the ‘off’ state; when coupled, they create a bistable system responsive to physiological concentrations of Mg2+. Mutations alter signaling by locally modulating domain intrinsic equilibrium constants and interdomain couplings. Our model suggests signals transmit via interdomain allostery rather than propagation of a single concerted conformational change, explaining the diversity of signaling structural transitions observed in individual HK domains.

Published

2021

3. Allosteric cooperation in a de novo-designed two-domain protein

Author

Nicholas F. Polizzi, Fabio Pirro, Nathan W. Schmidt, Michael J. Therien, Lijun Liu, Marco Chino, Michael Grabe, William F. DeGrado, Angela Lombardi, James Lincoff, Zachary X Widel, Pirro, Fabio, Schmidt, Nathan, Lincoff, Jame, Widel, Zachary X, Polizzi, Nicholas F, Liu, Lijun, Therien, Michael J, Grabe, Michael, Chino, Marco, Lombardi, Angela, and Degrado, William F

Subjects

Models, Molecular, Protein Structure, Secondary, Stereochemistry, Allosteric regulation, Protein domain, Coenzymes, Sequence (biology), macromolecular substances, Crystal structure, Ligands, Protein Engineering, Protein Structure, Secondary, Cofactor, chemistry.chemical_compound, porphyrin-binding protein, Allosteric Regulation, Protein Domains, Models, de novo design, diiron protein, Enzyme kinetics, protein evolution, Oxidase test, allostery, Multidisciplinary, biology, Molecular, Biological Sciences, Porphyrin, Recombinant Proteins, Biophysics and Computational Biology, Chemistry, chemistry, Metals, Physical Sciences, Biocatalysis, biology.protein, Oxidation-Reduction

Abstract

Significance A major mechanism of evolution involves fusing genes that encode single-domain proteins to create multidomain structures that achieve new functions. Here, we develop methods to design multidomain proteins entirely from scratch and achieve the premier de novo design of an allosterically regulated phenol oxidase that responds to the binding of a synthetic porphyrin., We describe the de novo design of an allosterically regulated protein, which comprises two tightly coupled domains. One domain is based on the DF (Due Ferri in Italian or two-iron in English) family of de novo proteins, which have a diiron cofactor that catalyzes a phenol oxidase reaction, while the second domain is based on PS1 (Porphyrin-binding Sequence), which binds a synthetic Zn-porphyrin (ZnP). The binding of ZnP to the original PS1 protein induces changes in structure and dynamics, which we expected to influence the catalytic rate of a fused DF domain when appropriately coupled. Both DF and PS1 are four-helix bundles, but they have distinct bundle architectures. To achieve tight coupling between the domains, they were connected by four helical linkers using a computational method to discover the most designable connections capable of spanning the two architectures. The resulting protein, DFP1 (Due Ferri Porphyrin), bound the two cofactors in the expected manner. The crystal structure of fully reconstituted DFP1 was also in excellent agreement with the design, and it showed the ZnP cofactor bound over 12 Å from the dimetal center. Next, a substrate-binding cleft leading to the diiron center was introduced into DFP1. The resulting protein acts as an allosterically modulated phenol oxidase. Its Michaelis–Menten parameters were strongly affected by the binding of ZnP, resulting in a fourfold tighter Km and a 7-fold decrease in kcat. These studies establish the feasibility of designing allosterically regulated catalytic proteins, entirely from scratch.

Published

2020

4. Author response: Allosteric mechanism of signal transduction in the two-component system histidine kinase PhoQ

Author

Bruk Mensa, Nicholas F Polizzi, Kathleen S Molnar, Andrew M Natale, Thomas Lemmin, and William F DeGrado

Published

2021

5. A defined structural unit enables de novo design of small-molecule–binding proteins

Author

William F. DeGrado and Nicholas F. Polizzi

Subjects

Stereochemistry, Pyridones, Drug Evaluation, Preclinical, Mutagenesis (molecular biology technique), Plasma protein binding, 010402 general chemistry, Protein Engineering, 01 natural sciences, Protein Structure, Secondary, Article, Small Molecule Libraries, 03 medical and health sciences, Protein structure, Fibrinolytic Agents, Structural unit, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Multidisciplinary, Proteins, Protein engineering, Small molecule, 0104 chemical sciences, Amino acid, chemistry, Pyrazoles, Small molecule binding, Carrier Proteins, Protein Binding

Abstract

A new tool in the protein design toolbox Protein design can compute protein folds from first principles. However, designing new proteins that are functional remains challenging, in part because designing binding interactions requires simultaneous optimization of protein sequence and protein-ligand conformation. Polizzi and DeGrado designed proteins from scratch that bind a small-molecule drug (see the Perspective by Peacock). They introduced a new structural element called a van der Mer (vdM), which tracks the orientation of a chemical group relative to the backbone of a contacting residue. Assuming proteins bind ligands using interactions similar to intraprotein packing, they determined statistically preferred vdMs from a large set of structures in the Protein Data Bank. By including weighted vdMs in their computations, they designed two of six de novo proteins that bind the drug apixaban. A drug-protein x-ray crystal structure confirmed the designed model. Science , this issue p. 1227 ; see also p. 1166

Published

2020

6. 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

7. Engineering High-Potential Photo-oxidants with Panchromatic Absorption

Author

Ting Jiang, Michael J. Therien, Jeff Rawson, and Nicholas F. Polizzi

Subjects

Oscillator strength, 02 engineering and technology, General Chemistry, Molar absorptivity, 010402 general chemistry, 021001 nanoscience & nanotechnology, Supermolecule, Photochemistry, 01 natural sciences, Biochemistry, Catalysis, 0104 chemical sciences, Panchromatic film, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Functional group, Orders of magnitude (speed), Absorption (chemistry), 0210 nano-technology, Derivative (chemistry)

Abstract

Challenging photochemistry demands high-potential visible-light-absorbing photo-oxidants. We report (i) a highly electron-deficient Ru(II) complex (eDef-Rutpy) bearing an E1/20/+ potential more than 300 mV more positive than that of any established Ru(II) bis(terpyridyl) derivative, and (ii) an ethyne-bridged eDef-Rutpy−(porphinato)Zn(II) (eDef-RuPZn) supermolecule that affords both panchromatic UV–vis spectral domain absorptivity and a high E1/20/+ potential, comparable to that of Ce(NH4)2(NO3)6 [E1/2(Ce3+/4+) = 1.61 V vs NHE], a strong and versatile ground-state oxidant commonly used in organic functional group transformations. eDef-RuPZn exhibits ∼8-fold greater absorptive oscillator strength over the 380–700 nm range relative to conventional Ru(II) polypyridyl complexes, and impressive excited-state reduction potentials (1E–/* = 1.59 V; 3E–/* = 1.26 V). eDef-RuPZn manifests electronically excited singlet and triplet charge-transfer state lifetimes more than 2 orders of magnitude longer than those typi...

Published

2017

8. Excitation energy-dependent photocurrent switching in a single-molecule photodiode

Author

Yosuke Kanai, Thomas J. Meyer, Nicholas F. Polizzi, Ninghao Zhou, Andrew M. Moran, Yanming Liu, Michael J. Therien, Animesh Nayak, Olivia F. Williams, Bing Shan, and Dillon C. Yost

Subjects

Photocurrent, Multidisciplinary, Materials science, business.industry, Doping, Chromophore, Photodiode, law.invention, Semiconductor, law, Excited state, Physical Sciences, Optoelectronics, Flash photolysis, business, Excitation

Abstract

The direction of electron flow in molecular optoelectronic devices is dictated by charge transfer between a molecular excited state and an underlying conductor or semiconductor. For those devices, controlling the direction and reversibility of electron flow is a major challenge. We describe here a single-molecule photodiode. It is based on an internally conjugated, bichromophoric dyad with chemically linked (porphyrinato)zinc(II) and bis(terpyridyl)ruthenium(II) groups. On nanocrystalline, degenerately doped indium tin oxide electrodes, the dyad exhibits distinct frequency-dependent, charge-transfer characters. Variations in the light source between red-light (∼1.9 eV) and blue-light (∼2.7 eV) excitation for the integrated photodiode result in switching of photocurrents between cathodic and anodic. The origin of the excitation frequency-dependent photocurrents lies in the electronic structure of the chromophore excited states, as shown by the results of theoretical calculations, laser flash photolysis, and steady-state spectrophotometric measurements.

Published

2019

9. Modulating Integrin αIIbβ3 Activity through Mutagenesis of Allosterically Regulated Intersubunit Contacts

Author

William F. DeGrado, Alex Sternisha, Karen P. Fong, Nicholas F. Polizzi, Sophia K. Tan, Kyungchul Yoon, Joel S. Bennett, and Joanna S.G. Slusky

Subjects

Protein Structure, Secondary, Biochemistry & Molecular Biology, Mutant, Integrin, CHO Cells, Platelet Glycoprotein GPIIb-IIIa Complex, Medical Biochemistry and Metabolomics, Biochemistry, Protein Structure, Secondary, Article, 03 medical and health sciences, Medicinal and Biomolecular Chemistry, Protein structure, Cricetulus, Allosteric Regulation, Cricetinae, Extracellular, Animals, Humans, Alanine, 0303 health sciences, biology, Chemistry, 030302 biochemistry & molecular biology, Mutagenesis, biology.organism_classification, Transmembrane protein, Protein Structure, Tertiary, Protein Subunits, Biophysics, biology.protein, Biochemistry and Cell Biology, Tertiary, Protein Binding

Abstract

Integrin αIIbβ3, a transmembrane heterodimer, mediates platelet aggregation when it switches from an inactive to an active ligand-binding conformation following platelet stimulation. Central to regulating αIIbβ3 activity is the interaction between the αIIb and β3 extracellular stalks, which form a tight heterodimer in the inactive state and dissociate in the active state. Here, we demonstrate that alanine replacements of sensitive positions in the heterodimer stalk interface destabilize the inactive conformation sufficiently to cause constitutive αIIbβ3 activation. To determine the structural basis for this effect, we performed a structural bioinformatics analysis and found that perturbing intersubunit contacts with favorable interaction geometry through substitutions to alanine quantitatively accounted for the degree of constitutive αIIbβ3 activation. This mutational study directly assesses the relationship between favorable interaction geometry at mutation-sensitive positions and the functional activity of those mutants, giving rise to a simple model that highlights the importance of interaction geometry in contributing to the stability between protein-protein interactions.

Published

2019

10. X-ray Crystal Structure of the Influenza A M2 Proton Channel S31N Mutant in Two Conformational States: An Open and Shut Case

Author

Lijun Liu, Nicholas F. Polizzi, Yibing Wu, William F. DeGrado, Jessica L. Thomaston, and Jun Wang

Subjects

Steric effects, Models, Molecular, Protein Conformation, Nuclear Magnetic Resonance, Adamantane, Drug Resistance, Crystal structure, 010402 general chemistry, Crystallography, X-Ray, 01 natural sciences, Biochemistry, Catalysis, Article, Viral Matrix Proteins, chemistry.chemical_compound, Colloid and Surface Chemistry, Protein structure, Models, Drug Resistance, Viral, Side chain, Amantadine, Viral, Nuclear Magnetic Resonance, Biomolecular, Crystallography, Binding Sites, biology, Chemistry, Hydrogen bond, Prevention, Molecular, Hydrogen Bonding, General Chemistry, Nuclear magnetic resonance spectroscopy, Hydrogen-Ion Concentration, Influenza, 3. Good health, 0104 chemical sciences, Infectious Diseases, Emerging Infectious Diseases, M2 proton channel, Influenza A virus, Chemical Sciences, X-Ray, Pneumonia & Influenza, biology.protein, Asparagine, Biomolecular

Abstract

The amantadine-resistant S31N mutant of the influenza A M2 proton channel has become prevalent in currently circulating viruses. Here, we have solved an X-ray crystal structure of M2(22–46) S31N that contains two distinct conformational states within its asymmetric unit. This structure reveals the mechanism of adamantane resistance in both conformational states of the M2 channel. In the Inward(open) conformation, the mutant Asn31 side chain faces the channel pore and sterically blocks the adamantane binding site. In the Inward(closed) conformation, Asn31 forms hydrogen bonds with carbonyls at the monomer–monomer interface, which twists the monomer helices and constricts the channel pore at the drug binding site. We also examine M2(19–49) WT and S31Nusing solution NMR spectroscopy and show that distribution of the two conformational states is dependent on both detergent choice and experimental pH.

Published

2019

11. Engineering opposite electronic polarization of singlet and triplet states increases the yield of high-energy photoproducts

Author

Nicholas F. Polizzi, Ting Jiang, Michael J. Therien, and David N. Beratan

Subjects

Physics, Models, Molecular, Electron density, Multidisciplinary, Spectrum Analysis, Bioengineering, Rhodobacter sphaeroides, Chromophore, Acceptor, Molecular physics, Electron Transport, Electron transfer, Intersystem crossing, Energy Transfer, Excited state, Commentaries, Physical Sciences, Density of states, Solar Energy, Singlet state, Photosynthesis

Abstract

Efficient photosynthetic energy conversion requires quantitative, light-driven formation of high-energy, charge-separated states. However, energies of high-lying excited states are rarely extracted, in part because the congested density of states in the excited-state manifold leads to rapid deactivation. Conventional photosystem designs promote electron transfer (ET) by polarizing excited donor electron density toward the acceptor (“one-way” ET), a form of positive design. Curiously, negative design strategies that explicitly avoid unwanted side reactions have been underexplored. We report here that electronic polarization of a molecular chromophore can be used as both a positive and negative design element in a light-driven reaction. Intriguingly, prudent engineering of polarized excited states can steer a “U-turn” ET—where the excited electron density of the donor is initially pushed away from the acceptor—to outcompete a conventional one-way ET scheme. We directly compare one-way vs. U-turn ET strategies via a linked donor–acceptor (DA) assembly in which selective optical excitation produces donor excited states polarized either toward or away from the acceptor. Ultrafast spectroscopy of DA pinpoints the importance of realizing donor singlet and triplet excited states that have opposite electronic polarizations to shut down intersystem crossing. These results demonstrate that oppositely polarized electronically excited states can be employed to steer photoexcited states toward useful, high-energy products by routing these excited states away from states that are photosynthetic dead ends.

Published

2019

12. Genetically Introducing Biochemically Reactive Amino Acids Dehydroalanine and Dehydrobutyrine in Proteins

Author

Paul D. Schnier, Feng Zheng, Peng George Wang, Bing Yang, Qian Wang, Nanxi Wang, William F. DeGrado, Varma Saikam, Lei Wang, Nicholas F. Polizzi, Avinash Ittuveetil, and He Zhu

Subjects

Models, Molecular, Protein Structure, Secondary, 010402 general chemistry, Protein Engineering, 01 natural sciences, Biochemistry, Catalysis, Protein Structure, Secondary, Article, Serine, chemistry.chemical_compound, Colloid and Surface Chemistry, Protein structure, Dehydroalanine, Models, Threonine, chemistry.chemical_classification, Alanine, Aminobutyrates, Molecular, Protein engineering, General Chemistry, Genetic code, 0104 chemical sciences, Amino acid, chemistry, Chemical Sciences, Generic health relevance, Bioorthogonal chemistry, Biotechnology

Abstract

Expansion of the genetic code with unnatural amino acids (Uaas) has significantly increased the chemical space available to proteins for exploitation. Due to the inherent limitation of translational machinery and the required compatibility with biological settings, function groups introduced via Uaas to date are restricted to chemically inert, bioorthogonal, or latent bioreactive groups. To break this barrier, here we report a new strategy enabling the specific incorporation of biochemically reactive amino acids into proteins. A latent bioreactive amino acid is genetically encoded at a position proximal to the target natural amino acid; they react via proximity-enabled reactivity, selectively converting the latter into a reactive residue in situ. Using this Genetically Encoded Chemical COnversion (GECCO) strategy and harnessing the sulfur-fluoride exchange (SuFEx) reaction between fluorosulfate-L-tyrosine and serine or threonine, we site-specifically generated the reactive dehydroalanine and dehydrobutyrine into proteins. GECCO works both inter- and intra-molecularly, and is compatible with various proteins. We further labeled the resultant dehydroalanine-containing protein with thiol-saccharide to generate glycoprotein mimetics. GECCO represents a new solution for selectively introducing biochemically reactive amino acids into proteins and is expected to open new avenues for exploiting chemistry in live systems for biological research and engineering.

Published

2019

13. Mean First-Passage Times in Biology

Author

Michael J. Therien, Nicholas F. Polizzi, and David N. Beratan

Subjects

0301 basic medicine, Markov chain, Chemistry, General Chemistry, Biology, 010402 general chemistry, 01 natural sciences, Article, 0104 chemical sciences, 03 medical and health sciences, Formalism (philosophy of mathematics), 030104 developmental biology, Computational chemistry, Statistical physics

Abstract

Many biochemical processes, such as charge hopping or protein folding, can be described by an average timescale to reach a final state, starting from an initial state. Here, we provide a pedagogical treatment of the mean first-passage time (MFPT) of a physical process, which depends on the number of intervening states between the initial state and the target state. Our aim in this tutorial review is to provide a clear development of the mean first-passage time formalism and to show some of its practical utility. The MFPT treatment can provide a useful link between microscopic rates and the average timescales often probed by experiment.

Published

2016

14. Inhibitors of the M2 Proton Channel Engage and Disrupt Transmembrane Networks of Hydrogen-Bonded Waters

Author

Antonios Kolocouris, William F. DeGrado, Jun Wang, Nicholas F. Polizzi, Jessica L. Thomaston, and Athina Konstantinidi

Subjects

0301 basic medicine, Models, Molecular, Rimantadine, Hydronium, Crystal structure, 010402 general chemistry, Crystallography, X-Ray, 01 natural sciences, Biochemistry, Catalysis, Article, Viral Matrix Proteins, 03 medical and health sciences, chemistry.chemical_compound, Colloid and Surface Chemistry, medicine, Amantadine, biology, Chemistry, Hydrogen bond, Water, Hydrogen Bonding, General Chemistry, Small molecule, Combinatorial chemistry, Transmembrane protein, 0104 chemical sciences, 030104 developmental biology, M2 proton channel, biology.protein, medicine.drug

Abstract

Water-mediated interactions play key roles in drug binding. In protein sites with sparse polar functionality, a small-molecule approach is often viewed as insufficient to achieve high affinity and specificity. Here we show that small molecules can enable potent inhibition by targeting key waters. The M2 proton channel of influenza A is the target of the antiviral drugs amantadine and rimantadine. Structural studies of drug binding to the channel using X-ray crystallography have been limited because of the challenging nature of the target, with the one previously solved crystal structure limited to 3.5 Å resolution. Here we describe crystal structures of amantadine bound to M2 in the Inward(closed) conformation (2.00 Å), rimantadine bound to M2 in both the Inward(closed) (2.00 Å) and Inward(open) (2.25 Å) conformations, and a spiro-adamantyl amine inhibitor bound to M2 in the Inward(closed) conformation (2.63 Å). These X-ray crystal structures of the M2 proton channel with bound inhibitors reveal that ammonium groups bind to water-lined sites that are hypothesized to stabilize transient hydronium ions formed in the proton-conduction mechanism. Furthermore, the ammonium and adamantyl groups of the adamantyl–amine class of drugs are free to rotate in the channel, minimizing the entropic cost of binding. These drug-bound complexes provide the first high-resolution structures of drugs that interact with and disrupt networks of hydrogen-bonded waters that are widely utilized throughout nature to facilitate proton diffusion within proteins.

Published

2018

15. Photoinduced Electron Transfer Elicits a Change in the Static Dielectric Constant of a de Novo Designed Protein

Author

David N. Beratan, Jeffery G. Saven, Michael J. Therien, Matthew J. Eibling, Jose Manuel Perez-Aguilar, Nicholas F. Polizzi, Christopher J. Lanci, H. Christopher Fry, and Jeff Rawson

Subjects

Models, Molecular, Analytical chemistry, chemistry.chemical_element, Dielectric, Zinc, Naphthalenes, Imides, 010402 general chemistry, 01 natural sciences, Biochemistry, Article, Catalysis, Photoinduced electron transfer, Electron Transport, Colloid and Surface Chemistry, 0103 physical sciences, Organometallic Compounds, Molecule, Group 2 organometallic chemistry, Molecular Structure, 010304 chemical physics, Chemistry, Proteins, General Chemistry, Photochemical Processes, Electron transport chain, Acceptor, 0104 chemical sciences, Solvent, Crystallography

Abstract

We provide a direct measure of the change in effective dielectric constant (ε(S)) within a protein matrix after a photoinduced electron transfer (ET) reaction. A linked donor-bridge-acceptor molecule, PZn-Ph-NDI, consisting of a (porphinato)Zn donor (PZn), a phenyl bridge (Ph), and a naphthalene diimide acceptor (NDI), is shown to be a "meter" to indicate protein dielectric environment. We calibrated PZn-Ph-NDI ET dynamics as a function of solvent dielectric, and computationally de novo designed a protein SCPZnI3 to bind PZn-Ph-NDI in its interior. Mapping the protein ET dynamics onto the calibrated ET catalogue shows that SCPZnI3 undergoes a switch in the effective dielectric constant following photoinduced ET, from ε(S) ≈ 8 to ε(S) ≈ 3.

Published

2016

16. Open-Access, Interactive Explorations for Teaching and Learning Quantum Dynamics

Author

David N. Beratan and Nicholas F. Polizzi

Subjects

Physics, Computer based learning, Dynamics (music), Interface (Java), Human–computer interaction, Quantum dynamics, General Chemistry, Electronic notebook, Field (computer science), Education, Document format, Variety (cybernetics)

Abstract

While the research field of quantum dynamics (QD) benefits from advances in modern computational power, the educational field of QD paradoxically does not. We have developed an open-access, interactive, electronic notebook that leverages a user-friendly interface to engage a new generation of visual learners with QD. We begin each topic (e.g., adiabaticity, light–matter interactions, and relaxation processes) with essential questions, issues, and background that orient the learner; we then move directly to visual explorations of the phenomena, where the learner can immediately manipulate parameters that control and drive the physics. This notebook requires only a computer that can run Wolfram’s computable document format (CDF) files (both the notebook and CDF player are free) and enables learning in a variety of contexts and grade levels: flipped classrooms, small groups, and high school students through advanced researchers. Without sacrificing rigor, Quantum Dynamics...with the Dynamics! (QDWD) aims to ...

Published

2015

17. Molecular Road Map to Tuning Ground State Absorption and Excited State Dynamics of Long-Wavelength Absorbers

Author

Michael J. Therien, Hyejin Yoo, Jean Hubert Olivier, Yusong Bai, Jeff Rawson, Nicholas F. Polizzi, and Jaehong Park

Subjects

010405 organic chemistry, Chemistry, General Chemistry, Molar absorptivity, Chromophore, 010402 general chemistry, 01 natural sciences, Biochemistry, Catalysis, Photon upconversion, 0104 chemical sciences, Colloid and Surface Chemistry, Intersystem crossing, Atomic orbital, Excited state, Atomic physics, Ground state, Absorption (electromagnetic radiation)

Abstract

Realizing chromophores that simultaneously possess substantial near-infrared (NIR) absorptivity and long-lived, high-yield triplet excited states is vital for many optoelectronic applications, such as optical power limiting and triplet–triplet annihilation photon upconversion (TTA-UC). However, the energy gap law ensures such chromophores are rare, and molecular engineering of absorbers having such properties has proven challenging. Here, we present a versatile methodology to tackle this design issue by exploiting the ethyne-bridged (polypyridyl)metal(II) (M; M = Ru, Os)-(porphinato)metal(II) (PM′; M′ = Zn, Pt, Pd) molecular architecture (M-(PM′)n-M), wherein high-oscillator-strength NIR absorptivity up to 850 nm, near-unity intersystem crossing (ISC) quantum yields (ΦISC), and triplet excited-state (T1) lifetimes on the microseconds time scale are simultaneously realized. By varying the extent to which the atomic coefficients of heavy metal d orbitals contribute to the one-electron excitation configurati...

Published

2017

18. Zinc-binding structure of a catalytic amyloid from solid-state NMR

Author

William F. DeGrado, Haifan Wu, Tuo Wang, Olga V. Makhlynets, Jan Stöhr, Ivan V. Korendovych, Yibing Wu, Nicholas F. Polizzi, Pallavi M. Gosavi, Myungwoon Lee, and Mei Hong

Subjects

0301 basic medicine, Models, Molecular, Amyloid, Magnetic Resonance Spectroscopy, 1.1 Normal biological development and functioning, 010402 general chemistry, 01 natural sciences, metal–peptide framework, Turn (biochemistry), 03 medical and health sciences, Models, Underpinning research, Metalloproteins, magic angle spinning, Side chain, Histidine, Binding site, Multidisciplinary, Binding Sites, metal-peptide framework, Chemistry, Ligand, Water, Computational Biology, Molecular, metalloprotein, Nuclear magnetic resonance spectroscopy, histidine, 0104 chemical sciences, Crystallography, Zinc, 030104 developmental biology, Physical Sciences, Protein folding, Generic health relevance, Protein ligand

Abstract

Throughout biology, amyloids are key structures in both functional proteins and the end product of pathologic protein misfolding. Amyloids might also represent an early precursor in the evolution of life because of their small molecular size and their ability to self-purify and catalyze chemical reactions. They also provide attractive backbones for advanced materials. When β-strands of an amyloid are arranged parallel and in register, side chains from the same position of each chain align, facilitating metal chelation when the residues are good ligands such as histidine. High-resolution structures of metalloamyloids are needed to understand the molecular bases of metal-amyloid interactions. Here we combine solid-state NMR and structural bioinformatics to determine the structure of a zinc-bound metalloamyloid that catalyzes ester hydrolysis. The peptide forms amphiphilic parallel β-sheets that assemble into stacked bilayers with alternating hydrophobic and polar interfaces. The hydrophobic interface is stabilized by apolar side chains from adjacent sheets, whereas the hydrated polar interface houses the Zn2+-binding histidines with binding geometries unusual in proteins. Each Zn2+ has two bis-coordinated histidine ligands, which bridge adjacent strands to form an infinite metal-ligand chain along the fibril axis. A third histidine completes the protein ligand environment, leaving a free site on the Zn2+ for water activation. This structure defines a class of materials, which we call metal-peptide frameworks. The structure reveals a delicate interplay through which metal ions stabilize the amyloid structure, which in turn shapes the ligand geometry and catalytic reactivity of Zn2.

Published

2017

19. Towards the de novo Design of Functional Metalloproteins

Author

Ketaki D. Belsare, Nicholas F. Polizzi, Lior Shtayer, and William F. DeGrado

Subjects

chemistry.chemical_classification, chemistry, Biophysics, Metalloprotein, Computational biology

Published

2020

20. Where Is the Electronic Oscillator Strength? Mapping Oscillator Strength across Molecular Absorption Spectra

Author

David N. Beratan, Lianjun Zheng, Agostino Migliore, Adarsh Dave, and Nicholas F. Polizzi

Subjects

Electronic oscillator, Oscillator strength, Chemistry, 02 engineering and technology, Electron, Electronic structure, Chromophore, Models, Theoretical, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Spectral line, Article, 0104 chemical sciences, Solar Energy, Spectrophotometry, Ultraviolet, Sum rule in quantum mechanics, Physical and Theoretical Chemistry, Atomic physics, 0210 nano-technology, Excitation

Abstract

The effectiveness of solar energy capture and conversion materials derives from their ability to absorb light and to transform the excitation energy into energy stored in free carriers or chemical bonds. The Thomas-Reiche-Kuhn (TRK) sum rule mandates that the integrated (electronic) oscillator strength of an absorber equals the total number of electrons in the structure. Typical molecular chromophores place only about 1% of their oscillator strength in the UV-vis window, so individual chromophores operate at about 1% of their theoretical limit. We explore the distribution of oscillator strength as a function of excitation energy to understand this circumstance. To this aim, we use familiar independent-electron model Hamiltonians as well as first-principles electronic structure methods. While model Hamiltonians capture the qualitative electronic spectra associated with π electron chromophores, these Hamiltonians mistakenly focus the oscillator strength in the fewest low-energy transitions. Advanced electronic structure methods, in contrast, spread the oscillator strength over a very wide excitation energy range, including transitions to Rydberg and continuum states, consistent with experiment. Our analysis rationalizes the low oscillator strength in the UV-vis spectral region in molecules, a step toward the goal of oscillator strength manipulation and focusing.

Published

2016

21. Defusing redox bombs?

Author

Michael J. Therien, Nicholas F. Polizzi, Agostino Migliore, and David N. Beratan

Subjects

Models, Molecular, Multidisciplinary, biology, Chemistry, Stereochemistry, Tryptophan, Proteins, Biological Sciences, medicine.disease_cause, Redox, Combinatorial chemistry, Cofactor, Enzyme catalysis, Oxidative Stress, Commentaries, Oxidizing agent, biology.protein, medicine, Humans, Tyrosine, Surface protein, Oxidative stress

Abstract

Living organisms have adapted to atmospheric dioxygen by exploiting its oxidizing power while protecting themselves against toxic side effects. Reactive oxygen and nitrogen species formed during oxidative stress, as well as high-potential reactive intermediates formed during enzymatic catalysis, could rapidly and irreversibly damage polypeptides were protective mechanisms not available. Chains of redox-active tyrosine and tryptophan residues can transport potentially damaging oxidizing equivalents (holes) away from fragile active sites and toward protein surfaces where they can be scavenged by cellular reductants. Precise positioning of these chains is required to provide effective protection without inhibiting normal function. A search of the structural database reveals that about one third of all proteins contain Tyr/Trp chains composed of three or more residues. Although these chains are distributed among all enzyme classes, they appear with greatest frequency in the oxidoreductases and hydrolases. Consistent with a redox-protective role, approximately half of the dioxygen-using oxidoreductases have Tyr/Trp chain lengths ≥3 residues. Among the hydrolases, long Tyr/Trp chains appear almost exclusively in the glycoside hydrolases. These chains likely are important for substrate binding and positioning, but a secondary redox role also is a possibility.

Published

2015

22. Biochemistry and Theory of Proton-Coupled Electron Transfer

Author

David N. Beratan, Michael J. Therien, Agostino Migliore, and Nicholas F. Polizzi

Subjects

Models, Molecular, 010405 organic chemistry, Chemistry, Kinetics, Photosystem II Protein Complex, Electrons, General Chemistry, Electron, Review, 010402 general chemistry, Photochemistry, 01 natural sciences, Electron transport chain, 0104 chemical sciences, Electron Transport, Biochemistry, Ribonucleotide Reductases, Quantum Theory, Proton-coupled electron transfer, Amino Acids, Protons, Deoxyribodipyrimidine Photo-Lyase

Published

2014