Your search keyword '"H. James Cleaves"' showing total 7 results

1. Adaptive Properties of the Genetically Encoded Amino Acid Alphabet Are Inherited from Its Subsets

Author

Melissa Ilardo, Natalie Grefenstette, Stephen J. Freeland, Christopher J. Butch, James Stephenson, H. James Cleaves, Richard J. Gillams, Rudrarup Bose, Bakhtiyor Rasulev, and Markus Meringer

Subjects

0301 basic medicine, Computational chemistry, Protein Folding, Computer science, In silico, lcsh:Medicine, Computational biology, ENCODE, Chemical origin of life, Article, Set (abstract data type), Evolution, Molecular, 03 medical and health sciences, 0302 clinical medicine, Origin of life, mental disorders, cardiovascular diseases, Amino Acids, lcsh:Science, chemistry.chemical_classification, Multidisciplinary, Cheminformatics, lcsh:R, Proteins, nutritional and metabolic diseases, Atmosphärenprozessoren, Astrobiology, Amino acid, 030104 developmental biology, chemistry, Models, Chemical, Proofreading, Protein folding, lcsh:Q, Alphabet, 030217 neurology & neurosurgery

Abstract

Life uses a common set of 20 coded amino acids (CAAs) to construct proteins. This set was likely canonicalized during early evolution; before this, smaller amino acid sets were gradually expanded as new synthetic, proofreading and coding mechanisms became biologically available. Many possible subsets of the modern CAAs or other presently uncoded amino acids could have comprised the earlier sets. We explore the hypothesis that the CAAs were selectively fixed due to their unique adaptive chemical properties, which facilitate folding, catalysis, and solubility of proteins, and gave adaptive value to organisms able to encode them. Specifically, we studied in silico hypothetical CAA sets of 3–19 amino acids comprised of 1913 structurally diverse α-amino acids, exploring the adaptive value of their combined physicochemical properties relative to those of the modern CAA set. We find that even hypothetical sets containing modern CAA members are especially adaptive; it is difficult to find sets even among a large choice of alternatives that cover the chemical property space more amply. These results suggest that each time a CAA was discovered and embedded during evolution, it provided an adaptive value unusual among many alternatives, and each selective step may have helped bootstrap the developing set to include still more CAAs.

Published

2019

2. Simple prebiotic synthesis of high diversity dynamic combinatorial polyester libraries

Author

Nicholas Guttenberg, Kuhan Chandru, Yayoi Hongo, H. James Cleaves, Irena Mamajanov, Christopher J. Butch, and Chaitanya Giri

Subjects

chemistry.chemical_classification, Reaction conditions, Prebiotic, medicine.medical_treatment, General Chemistry, Polymer, Biochemistry, Combinatorial chemistry, Polyester, lcsh:Chemistry, chemistry.chemical_compound, Monomer, chemistry, Polymerization, lcsh:QD1-999, Abiogenesis, Materials Chemistry, medicine, Environmental Chemistry, Simple (philosophy)

Abstract

It is widely believed that the origin of life depended on environmentally driven complexification of abiotically produced organic compounds. Polymerization is one type of such complexification, and it may be important that many diverse polymer sequences be produced for the sake of selection. Not all compound classes are easily polymerized under the environmental conditions present on primitive planets, and it is possible that life’s origin was aided by other monomers besides those used in contemporary biochemistry. Here we show that alpha-hydroxy acids, which are plausibly abundant prebiotic monomers, can be oligomerized to generate vast, likely sequence-complete libraries, which are also stable for significant amounts of time. This occurs over a variety of reaction conditions (temperature, concentration, salinity, and presence of congeners) compatible with geochemical settings on the primitive Earth and other solar system environments. The high-sequence heterogeneity achievable with these compounds may be useful for scaffolding the origin of life. The origins of life likely involved abiotic combinatorial polymer synthesis but the characterisation of such mixtures is challenging. Here the authors show that large libraries of linear and cyclic oligomers spontaneously form from α-hydroxy acids under mild conditions which may be relevant to prebiotic synthesis.

Published

2018

3. Estimating the capacity for production of formamide by radioactive minerals on the prebiotic Earth

Author

H. James Cleaves, Ruiqin Yi, Masashi Aono, Zachary R. Adam, Albert C. Fahrenbach, Isao Yoda, and Yayoi Hongo

Subjects

Formamide, Multidisciplinary, Mineral, Aqueous solution, Inorganic chemistry, lcsh:R, lcsh:Medicine, Oklo, 010402 general chemistry, Early Earth, 01 natural sciences, Article, 0104 chemical sciences, Solvent, chemistry.chemical_compound, Uraninite, chemistry, 0103 physical sciences, lcsh:Q, Acetonitrile, lcsh:Science, 010303 astronomy & astrophysics

Abstract

Water creates special problems for prebiotic chemistry, as it is thermodynamically favorable for amide and phosphodiester bonds to hydrolyze. The availability of alternative solvents with more favorable properties for the formation of prebiotic molecules on the early Earth may have helped bypass this so-called “water paradox”. Formamide (FA) is one such solvent, and can serve as a nucleobase precursor, but it is difficult to envision how FA could have been generated in large quantities or accumulated in terrestrial surface environments. We report here the conversion of aqueous acetonitrile (ACN) via hydrogen cyanide (HCN) as an intermediate into FA by γ-irradiation under conditions mimicking exposure to radioactive minerals. We estimate that a radioactive placer deposit could produce 0.1‒0.8 mol FA km−2 year−1. A uraninite fission zone comparable to the Oklo reactors in Gabon can produce 0.1‒1 mol m−2 year−1, orders of magnitude greater than other scenarios of FA production or delivery for which reaching sizeable concentrations of FA are problematic. Radioactive mineral deposits may be favorable settings for prebiotic compound formation through emergent geologic processes and FA-mediated organic chemistry.

Published

2018

4. Computational exploration of the chemical structure space of possible reverse tricarboxylic acid cycle constituents

Author

H. James Cleaves and Markus Meringer

Subjects

Models, Molecular, 0301 basic medicine, Interface (Java), Computer science, Chemical structure, media_common.quotation_subject, Citric Acid Cycle, astrobiology, lcsh:Medicine, Stereoisomerism, Space (commercial competition), 010402 general chemistry, 01 natural sciences, Article, Set (abstract data type), 03 medical and health sciences, Molecule, Computer Simulation, Simplicity, lcsh:Science, media_common, chemistry.chemical_classification, chemical origin of life, Multidisciplinary, Beilstein database, lcsh:R, Computational Biology, Tricarboxylic Acids, Metabolism, Tricarboxylic acid, Atmosphärenprozessoren, metabolomics, Chemical space, 0104 chemical sciences, Citric acid cycle, 030104 developmental biology, chemistry, Cheminformatics, lcsh:Q, Biochemical engineering

Abstract

The reverse tricarboxylic acid (rTCA) cycle has been explored from various standpoints as an idealized primordial metabolic cycle. Its simplicity and apparent ubiquity in diverse organisms across the tree of life have been used to argue for its antiquity and its optimality. In 2000 it was proposed that chemoinformatics approaches support some of these views. Specifically, defined queries of the Beilstein database showed that the molecules of the rTCA are heavily represented in such compound databases. We explore here the chemical structure “space,” e.g. the set of organic compounds which possesses some minimal set of defining characteristics, of the rTCA cycle’s intermediates using an exhaustive structure generation method. The rTCA’s chemical space as defined by the original criteria and explored by our method is some six to seven times larger than originally considered. Acknowledging that each assumption in what is a defining criterion making the rTCA cycle special limits possible generative outcomes, there are many unrealized compounds which fulfill these criteria. That these compounds are unrealized could be due to evolutionary frozen accidents or optimization, though this optimization may also be for systems-level reasons, e.g., the way the pathway and its elements interface with other aspects of metabolism.

Published

2017

5. The Abiotic Chemistry of Thiolated Acetate Derivatives and the Origin of Life

Author

H. James Cleaves, Masashi Aono, Kuhan Chandru, Alexis Gilbert, and Christopher J. Butch

Subjects

0301 basic medicine, Origin of Life, Sulfides, 01 natural sciences, Article, 03 medical and health sciences, Hydrolysis, chemistry.chemical_compound, Acetic acid, Acetyl Coenzyme A, Abiogenesis, 0103 physical sciences, Organic chemistry, Sulfhydryl Compounds, 010303 astronomy & astrophysics, Equilibrium constant, Acetic Acid, Abiotic component, Multidisciplinary, Chemistry, Carbon fixation, Geology, Carbon, Kinetics, 030104 developmental biology, Biochemistry, Reagent, Thioacetic acid

Abstract

Thioesters and thioacetic acid (TAA) have been invoked as key reagents for the origin of life as activated forms of acetate analogous to acetyl-CoA. These species could have served as high-energy group-transfer reagents and allowed carbon insertions to form higher molecular weight compounds such as pyruvate. The apparent antiquity of the Wood-Ljungdahl CO2 fixation pathway and its presence in organisms which inhabit hydrothermal (HT) environments has also led to suggestions that there may be a connection between the abiotic chemistry of compounds similar to TAA and the origins of metabolism. These compounds’ apparent chemical simplicity has made their prebiotic availability assumed, however, although the kinetic behavior and thermochemical properties of TAA and analogous esters have been preliminarily explored in other contexts, the geochemical relevance of these compounds merits further evaluation. Therefore, the chemical behavior of the simplest thiolated acetic acid derivatives, TAA and methylthioacetate (MTA) were explored here. Using laboratory measurements, literature data and thermochemical models, we examine the plausibility of the accumulation of these compounds in various geological settings. Due to the high free energy change of their hydrolysis and corresponding low equilibrium constants, it is unlikely that these species could have accumulated abiotically to any significant extant.

Published

2016

6. Extraordinarily Adaptive Properties of the Genetically Encoded Amino Acids

Author

Stephen J. Freeland, Baktiyour Rasulev, Melissa Ilardo, H. James Cleaves, and Markus Meringer

Subjects

Genetics, chemistry.chemical_classification, Multidisciplinary, Natural selection, Adaptation, Biological, Computational biology, Biology, Atmosphärenprozessoren, Genetic code, Article, Amino acid, Set (abstract data type), Synthetic biology, chemistry, Cover (topology), Origin of life, Metric (mathematics), Computational models, Amino Acids, Selection, Genetic, Codon, Gene

Abstract

Using novel advances in computational chemistry, we demonstrate that the set of 20 genetically encoded amino acids, used nearly universally to construct all coded terrestrial proteins, has been highly influenced by natural selection. We defined an adaptive set of amino acids as one whose members thoroughly cover relevant physico-chemical properties, or “chemistry space.” Using this metric, we compared the encoded amino acid alphabet to random sets of amino acids. These random sets were drawn from a computationally generated compound library containing 1913 alternative amino acids that lie within the molecular weight range of the encoded amino acids. Sets that cover chemistry space better than the genetically encoded alphabet are extremely rare and energetically costly. Further analysis of more adaptive sets reveals common features and anomalies and we explore their implications for synthetic biology. We present these computations as evidence that the set of 20 amino acids found within the standard genetic code is the result of considerable natural selection. The amino acids used for constructing coded proteins may represent a largely global optimum, such that any aqueous biochemistry would use a very similar set.

Published

2015

7. Supramolecular polymerization of a prebiotic nucleoside provides insights into the creation of sequence-controlled polymers.

Author

Wang J, Bonnesen PV, Rangel E, Vallejo E, Sanchez-Castillo A, James Cleaves Ii H, Baddorf AP, Sumpter BG, Pan M, Maksymovych P, and Fuentes-Cabrera M

Subjects

Adenine chemistry, Gold chemistry, Nanostructures chemistry, Nanostructures ultrastructure, Polymerization, Adenine analogs & derivatives, Polymers chemical synthesis, Prebiotics

Abstract

Self-assembly of a nucleoside on Au(111) was studied to ascertain whether polymerization on well-defined substrates constitutes a promising approach for making sequence-controlled polymers. Scanning tunneling microscopy and density functional theory were used to investigate the self-assembly on Au(111) of (RS)-N(9)-(2,3-dihydroxypropyl)adenine (DHPA), a plausibly prebiotic nucleoside analog of adenosine. It is found that DHPA molecules self-assemble into a hydrogen-bonded polymer that grows almost exclusively along the herringbone reconstruction pattern, has a two component sequence that is repeated over hundreds of nanometers, and is erasable with electron-induced excitation. Although the sequence is simple, more complicated ones are envisioned if two or more nucleoside types are combined. Because polymerization occurs on a substrate in a dry environment, the success of each combination can be gauged with high-resolution imaging and accurate modeling techniques. These characteristics make nucleoside self-assembly on a substrate an attractive approach for designing sequence-controlled polymers. Further, by choosing plausibly prebiotic nucleosides, insights may be provided into how nature created the first sequence-controlled polymers capable of storing information. Such insights, in turn, can inspire new ways of synthesizing sequence-controlled polymers.

Published

2016