Your search keyword '"Ryan S, Renslow"' showing total 106 results

1. An initial investigation of accuracy required for the identification of small molecules in complex samples using quantum chemical calculated NMR chemical shifts

Author

Yasemin Yesiltepe, Niranjan Govind, Thomas O. Metz, and Ryan S. Renslow

Subjects

Metabolomics, Small molecules, NMR, DFT, Quantum chemistry, Information technology, T58.5-58.64, Chemistry, QD1-999

Abstract

Abstract The majority of primary and secondary metabolites in nature have yet to be identified, representing a major challenge for metabolomics studies that currently require reference libraries from analyses of authentic compounds. Using currently available analytical methods, complete chemical characterization of metabolomes is infeasible for both technical and economic reasons. For example, unambiguous identification of metabolites is limited by the availability of authentic chemical standards, which, for the majority of molecules, do not exist. Computationally predicted or calculated data are a viable solution to expand the currently limited metabolite reference libraries, if such methods are shown to be sufficiently accurate. For example, determining nuclear magnetic resonance (NMR) spectroscopy spectra in silico has shown promise in the identification and delineation of metabolite structures. Many researchers have been taking advantage of density functional theory (DFT), a computationally inexpensive yet reputable method for the prediction of carbon and proton NMR spectra of metabolites. However, such methods are expected to have some error in predicted 13C and 1H NMR spectra with respect to experimentally measured values. This leads us to the question–what accuracy is required in predicted 13C and 1H NMR chemical shifts for confident metabolite identification? Using the set of 11,716 small molecules found in the Human Metabolome Database (HMDB), we simulated both experimental and theoretical NMR chemical shift databases. We investigated the level of accuracy required for identification of metabolites in simulated pure and impure samples by matching predicted chemical shifts to experimental data. We found 90% or more of molecules in simulated pure samples can be successfully identified when errors of 1H and 13C chemical shifts in water are below 0.6 and 7.1 ppm, respectively, and below 0.5 and 4.6 ppm in chloroform solvation, respectively. In simulated complex mixtures, as the complexity of the mixture increased, greater accuracy of the calculated chemical shifts was required, as expected. However, if the number of molecules in the mixture is known, e.g., when NMR is combined with MS and sample complexity is low, the likelihood of confident molecular identification increased by 90%.

Published

2022

2. Daylight-driven carbon exchange through a vertically structured microbial community

Author

James J. Moran, Hans C. Bernstein, Jennifer M. Mobberley, Allison M. Thompson, Young-Mo Kim, Karl L. Dana, Alexandra B. Cory, Steph Courtney, Ryan S. Renslow, James K. Fredrickson, Helen W. Kreuzer, and Mary S. Lipton

Subjects

metaproteomics, stable isotope, cyanobacteria, microbial interactions, benthic microbial mat, Microbiology, QR1-502

Abstract

Interactions between autotrophs and heterotrophs are central to carbon (C) exchange across trophic levels in essentially all ecosystems and metabolite exchange is a frequent mechanism for distributing C within spatially structured ecosystems. Yet, despite the importance of C exchange, the timescales at which fixed C is transferred in microbial communities is poorly understood. We employed a stable isotope tracer combined with spatially resolved isotope analysis to quantify photoautotrophic uptake of bicarbonate and track subsequent exchanges across a vertical depth gradient in a stratified microbial mat over a light-driven diel cycle. We observed that C mobility, both across the vertical strata and between taxa, was highest during periods of active photoautotrophy. Parallel experiments with 13C-labeled organic substrates (acetate and glucose) showed comparably less exchange of C within the mat. Metabolite analysis showed rapid incorporation of 13C into molecules that can both comprise a portion of the extracellular polymeric substances in the system and serve to transport C between photoautotrophs and heterotrophs. Stable isotope proteomic analysis revealed rapid C exchange between cyanobacterial and associated heterotrophic community members during the day with decreased exchange at night. We observed strong diel control on the spatial exchange of freshly fixed C within tightly interacting mat communities suggesting a rapid redistribution, both spatially and taxonomically, primarily during daylight periods.

Published

2023

3. NP-MRD: the Natural Products Magnetic Resonance Database.

Author

David S. Wishart, Zinat Sayeeda, Zachary Budinski, Anchi Guo, Brian L. Lee, Mark V. Berjanskii, Manoj Rout, Harrison Peters, Raynard Dizon, Robert Mah, Claudia Torres-Calzada, Mickel Hiebert-Giesbrecht, Dorna Varshavi, Dorsa Varshavi, Eponine Oler, Dana Allen, Xuan Cao, Vasuk Gautam, Andrew Maras, Ella F. Poynton, Pegah Tavangar, Vera Yang, Jeffrey A. van Santen, Rajarshi Ghosh, Saurav Sarma, Eleanor Knutson, Victoria Sullivan, Amy M. Jystad, Ryan S. Renslow, Lloyd W. Sumner, Roger G. Linington, and John R. Cort

Published

2022

4. Correction: Nielson et al. Similarity Downselection: Finding the n Most Dissimilar Molecular Conformers for Reference-Free Metabolomics. Metabolites 2023, 13, 105

Author

Felicity F. Nielson, Bill Kay, Stephen J. Young, Sean M. Colby, Ryan S. Renslow, and Thomas O. Metz

Subjects

n/a, Microbiology, QR1-502

Abstract

There were missing figures and associated legends for Figure 3 and Figure 4 as published due to a publication error [...]

Published

2023

5. Mass Spectrometry Adduct Calculator.

Author

Madison R. Blumer, Christine H. Chang, Evangelina Brayfindley, Jamie R. Nuñez, Sean M. Colby, Ryan S. Renslow, and Thomas O. Metz

Published

2021

6. Ligand- and Structure-Based Analysis of Deep Learning-Generated Potential α2a Adrenoceptor Agonists.

Author

Katherine J. Schultz, Sean M. Colby, Vivian S. Lin, Aaron T. Wright, and Ryan S. Renslow

Published

2021

7. Chespa: Streamlining Expansive Chemical Space Evaluation of Molecular Sets.

Author

Jamie R. Nuñez, Monee Y. McGrady, Yasemin Yesiltepe, Ryan S. Renslow, and Thomas O. Metz

Published

2020

8. Similarity Downselection: Finding the n Most Dissimilar Molecular Conformers for Reference-Free Metabolomics

Author

Felicity F. Nielson, Bill Kay, Stephen J. Young, Sean M. Colby, Ryan S. Renslow, and Thomas O. Metz

Subjects

conformer, downselection, graph, metabolomics, molecule, Monte Carlo, Microbiology, QR1-502

Abstract

Computational methods for creating in silico libraries of molecular descriptors (e.g., collision cross sections) are becoming increasingly prevalent due to the limited number of authentic reference materials available for traditional library building. These so-called “reference-free metabolomics” methods require sampling sets of molecular conformers in order to produce high accuracy property predictions. Due to the computational cost of the subsequent calculations for each conformer, there is a need to sample the most relevant subset and avoid repeating calculations on conformers that are nearly identical. The goal of this study is to introduce a heuristic method of finding the most dissimilar conformers from a larger population in order to help speed up reference-free calculation methods and maintain a high property prediction accuracy. Finding the set of the n items most dissimilar from each other out of a larger population becomes increasingly difficult and computationally expensive as either n or the population size grows large. Because there exists a pairwise relationship between each item and all other items in the population, finding the set of the n most dissimilar items is different than simply sorting an array of numbers. For instance, if you have a set of the most dissimilar n = 4 items, one or more of the items from n = 4 might not be in the set n = 5. An exact solution would have to search all possible combinations of size n in the population exhaustively. We present an open-source software called similarity downselection (SDS), written in Python and freely available on GitHub. SDS implements a heuristic algorithm for quickly finding the approximate set(s) of the n most dissimilar items. We benchmark SDS against a Monte Carlo method, which attempts to find the exact solution through repeated random sampling. We show that for SDS to find the set of n most dissimilar conformers, our method is not only orders of magnitude faster, but it is also more accurate than running Monte Carlo for 1,000,000 iterations, each searching for set sizes n = 3–7 out of a population of 50,000. We also benchmark SDS against the exact solution for example small populations, showing that SDS produces a solution close to the exact solution in these instances. Using theoretical approaches, we also demonstrate the constraints of the greedy algorithm and its efficacy as a ratio to the exact solution.

Published

2023

9. Evaluation of In Silico Multifeature Libraries for Providing Evidence for the Presence of Small Molecules in Synthetic Blinded Samples.

Author

Jamie R. Nuñez, Sean M. Colby, Dennis G. Thomas, Malak M. Tfaily, Nikola Tolic, Elin M. Ulrich, Jon R. Sobus, Thomas O. Metz, Justin G. Teeguarden, and Ryan S. Renslow

Published

2019

10. SPECTRe: Substructure Processing, Enumeration, and Comparison Tool Resource: An efficient tool to encode all substructures of molecules represented in SMILES.

Author

Yasemin Yesiltepe, Ryan S. Renslow, and Thomas O. Metz

Published

2021

11. Similarity Downselection: A Python implementation of a heuristic search algorithm for finding the set of the n most dissimilar items with an application in conformer sampling.

Author

Felicity F. Nielson, Sean M. Colby, Ryan S. Renslow, and Thomas O. Metz

Published

2021

12. Application and Assessment of Deep Learning for the Generation of Potential NMDA Receptor Antagonists.

Author

Katherine J. Schultz, Sean M. Colby, Yasemin Yesiltepe, Jamie R. Nuñez, Monee Y. McGrady, and Ryan S. Renslow

Published

2020

13. An automated framework for NMR chemical shift calculations of small organic molecules.

Author

Yasemin Yesiltepe, Jamie R. Nuñez, Sean M. Colby, Dennis G. Thomas, Mark I. Borkum, Patrick Reardon, Nancy M. Washton, Thomas O. Metz, Justin G. Teeguarden, Niranjan Govind, and Ryan S. Renslow

Published

2018

14. New mass spectrometry technologies contributing towards comprehensive and high throughput omics analyses of single cells

Author

Sneha P. Couvillion, Ying Zhu, Gabe Nagy, Joshua N. Adkins, Charles Ansong, Ryan S. Renslow, Paul D. Piehowski, Yehia M. Ibrahim, Ryan T. Kelly, and Thomas O. Metz

Published

2019

15. Nitrogen Source Governs Community Carbon Metabolism in a Model Hypersaline Benthic Phototrophic Biofilm

Author

Christopher R. Anderton, Jennifer M. Mobberley, Jessica K. Cole, Jamie R. Nunez, Robert Starke, Amy A. Boaro, Yasemin Yesiltepe, Beau R. Morton, Alexandra B. Cory, Hayley C. Cardamone, Kirsten S. Hofmockel, Mary S. Lipton, James J. Moran, Ryan S. Renslow, James K. Fredrickson, and Stephen R. Lindemann

Subjects

carbon cycling, cyanobacteria, mass spectrometry, nitrogen cycling, stable isotopes, Microbiology, QR1-502

Abstract

ABSTRACT Increasing anthropogenic inputs of fixed nitrogen are leading to greater eutrophication of aquatic environments, but it is unclear how this impacts the flux and fate of carbon in lacustrine and riverine systems. Here, we present evidence that the form of nitrogen governs the partitioning of carbon among members in a genome-sequenced, model phototrophic biofilm of 20 members. Consumption of NO3− as the sole nitrogen source unexpectedly resulted in more rapid transfer of carbon to heterotrophs than when NH4+ was also provided, suggesting alterations in the form of carbon exchanged. The form of nitrogen dramatically impacted net community nitrogen, but not carbon, uptake rates. Furthermore, this alteration in nitrogen form caused very large but focused alterations to community structure, strongly impacting the abundance of only two species within the biofilm and modestly impacting a third member species. Our data suggest that nitrogen metabolism may coordinate coupled carbon-nitrogen biogeochemical cycling in benthic biofilms and, potentially, in phototroph-heterotroph consortia more broadly. It further indicates that the form of nitrogen inputs may significantly impact the contribution of these communities to carbon partitioning across the terrestrial-aquatic interface. IMPORTANCE Anthropogenic inputs of nitrogen into aquatic ecosystems, and especially those of agricultural origin, involve a mix of chemical species. Although it is well-known in general that nitrogen eutrophication markedly influences the metabolism of aquatic phototrophic communities, relatively little is known regarding whether the specific chemical form of nitrogen inputs matter. Our data suggest that the nitrogen form alters the rate of nitrogen uptake significantly, whereas corresponding alterations in carbon uptake were minor. However, differences imposed by uptake of divergent nitrogen forms may result in alterations among phototroph-heterotroph interactions that rewire community metabolism. Furthermore, our data hint that availability of other nutrients (i.e., iron) might mediate the linkage between carbon and nitrogen cycling in these communities. Taken together, our data suggest that different nitrogen forms should be examined for divergent impacts on phototrophic communities in fluvial systems and that these anthropogenic nitrogen inputs may significantly differ in their ultimate biogeochemical impacts.

Published

2020

16. Water‐dispersible nanocolloids and higher temperatures promote the release of carbon from riparian soil

Author

Kenton A. Rod, A. Peyton Smith, Weinan Leng, Sean Colby, Ravi K. Kukkadapu, Mark Bowden, Odeta Qafoku, Wooyong Um, Michael F. Hochella Jr., Vanessa L. Bailey, and Ryan S. Renslow

Subjects

Environmental sciences, GE1-350, Geology, QE1-996.5

Abstract

Abstract Increasing temperatures in alpine regions accompanied by glacial retreat is occurring rapidly due to climate change. This may affect riparian soils by increasing weathering rates, resulting in greater organic carbon (OC) release to rivers via movement of iron‐containing colloids and nanominerals. Increased concentrations of iron‐ or silcate‐nanominerals would result in higher surface area for OC adsorption. To test the influence of temperature on OC leaching, we examined mineral weathering and nanocolloid facilitated release of OC through a series of controlled laboratory batch and column experiments using sediment from the banks of the Nisqually River, Mount Rainier in Washington State (USA). Additional experiments were conducted using the same sediments, but with an illite amendment added to test the influence of additional surface area and nanominerals that many sediments along the Nisqually River contain. These higher‐ and lower‐surface‐area sediments (i.e., sediments with and without the illite amendment) were incubated for 90 d at 4 or 20 °C, followed by batch and column OC leaching tests. Results show that OC leaching rates for 20 °C were two to three times greater than for 4 °C. Further, our results suggest that nanocolloids are responsible for moving this increased OC load from these sediments. When hydrologically connected, OC is released from bank sediments to rivers faster than presently anticipated in fluvial environments experiencing climate change‐induced glacial retreat. Further, a one‐dimensional, finite‐element computational model developed for this study estimates that a 1 °C increase in temperature over a 90‐d summer runoff period increases the OC release rate from sediments by 79%.

Published

2020

17. Improving network inference algorithms using resampling methods

Author

Sean M Colby, Ryan S McClure, Christopher C Overall, Ryan S Renslow, and Jason E McDermott

Subjects

Gene regulatory network inference, Random subspace method, Resampling, Bootstrapping, Aggregation, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Background Relatively small changes to gene expression data dramatically affect co-expression networks inferred from that data which, in turn, can significantly alter the subsequent biological interpretation. This error propagation is an underappreciated problem that, while hinted at in the literature, has not yet been thoroughly explored. Resampling methods (e.g. bootstrap aggregation, random subspace method) are hypothesized to alleviate variability in network inference methods by minimizing outlier effects and distilling persistent associations in the data. But the efficacy of the approach assumes the generalization from statistical theory holds true in biological network inference applications. Results We evaluated the effect of bootstrap aggregation on inferred networks using commonly applied network inference methods in terms of stability, or resilience to perturbations in the underlying expression data, a metric for accuracy, and functional enrichment of edge interactions. Conclusion Bootstrap aggregation results in improved stability and, depending on the size of the input dataset, a marginal improvement to accuracy assessed by each method’s ability to link genes in the same functional pathway.

Published

2018

18. Correction to 'Chespa: Streamlining Expansive Chemical Space Evaluation of Molecular Sets'.

Author

Jamie R. Nuñez, Monee Y. McGrady, Yasemin Yesiltepe, Ryan S. Renslow, and Thomas O. Metz

Published

2021

19. PIXiE: an algorithm for automated ion mobility arrival time extraction and collision cross section calculation using global data association.

Author

Jian Ma, Cameron P. Casey, Xueyun Zheng, Yehia M. Ibrahim, Christopher S. Wilkins, Ryan S. Renslow, Dennis G. Thomas, Samuel H. Payne, Matthew E. Monroe, Richard D. Smith, Justin G. Teeguarden, Erin S. Baker, and Thomas O. Metz

Published

2017

20. Proton Affinity Values of Fentanyl and Fentanyl Analogues Pertinent to Ambient Ionization and Detection

Author

Elizabeth H. Denis, Jessica L. Bade, Ryan S. Renslow, Kelsey A. Morrison, Megan K. Nims, Niranjan Govind, and Robert G. Ewing

Subjects

Fentanyl, Substance Abuse Detection, Atmospheric Pressure, Limit of Detection, Structural Biology, Reproducibility of Results, Gases, Protons, Mass Spectrometry, Spectroscopy

Abstract

Proton affinity is a major factor in the atmospheric pressure chemical ionization of illicit drugs. The detection of illicit drugs by mass spectrometry and ion mobility spectrometry relies on the analytes having greater proton affinities than background species. Evaluating proton affinities for fentanyl and its analogues is informative for predicting the likelihood of ionization in different environments and for optimizing the compounds' ionization and detection, such as through the addition of dopant chemicals. Herein, density functional theory was used to computationally determine the proton affinity and gas-phase basicity of 15 fentanyl compounds and several relevant molecules as a reference point. The range of proton affinities for the fentanyl compounds was from 1018 to 1078 kJ/mol. Fentanyl compounds with the higher proton affinity values appeared to form a bridge between the oxygen on the amide and the protonated nitrogen on the piperidine ring based on models and calculated bond distances. Experiments with fragmentation of proton-bound clusters using atmospheric flow tube-mass spectrometry (AFT-MS) provided estimates of relative proton affinities and showed proton affinity values of fentanyl compounds1000 kJ/mol, which were consistent with the computational results. The high proton affinities of fentanyl compounds facilitate their detection by ambient ionization techniques in complex environments. The detection limits of the fentanyl compounds with AFT-MS are in the low femtogram range, which demonstrates the feasibility of trace vapor drug detection.

Published

2022

21. Optimizing colormaps with consideration for color vision deficiency to enable accurate interpretation of scientific data.

Author

Jamie R Nuñez, Christopher R Anderton, and Ryan S Renslow

Subjects

Medicine, Science

Abstract

Color vision deficiency (CVD) affects more than 4% of the population and leads to a different visual perception of colors. Though this has been known for decades, colormaps with many colors across the visual spectra are often used to represent data, leading to the potential for misinterpretation or difficulty with interpretation by someone with this deficiency. Until the creation of the module presented here, there were no colormaps mathematically optimized for CVD using modern color appearance models. While there have been some attempts to make aesthetically pleasing or subjectively tolerable colormaps for those with CVD, our goal was to make optimized colormaps for the most accurate perception of scientific data by as many viewers as possible. We developed a Python module, cmaputil, to create CVD-optimized colormaps, which imports colormaps and modifies them to be perceptually uniform in CVD-safe colorspace while linearizing and maximizing the brightness range. The module is made available to the science community to enable others to easily create their own CVD-optimized colormaps. Here, we present an example CVD-optimized colormap created with this module that is optimized for viewing by those without a CVD as well as those with red-green colorblindness. This colormap, cividis, enables nearly-identical visual-data interpretation to both groups, is perceptually uniform in hue and brightness, and increases in brightness linearly.

Published

2018

22. NP-MRD: the Natural Products Magnetic Resonance Database

Author

David S. Wishart, Raynard Dizon, Mickel Hiebert-Giesbrecht, Eponine Oler, An Chi Guo, Andrew Maras, Mark V. Berjanskii, Manoj Kumar Rout, John R. Cort, Victoria Sullivan, Saurav J. Sarma, Zachary Budinski, Dorna Varshavi, Brian L. Lee, Jeffrey A. van Santen, Zinat Sayeeda, Claudia Torres-Calzada, Pegah Tavangar, Lloyd W. Sumner, Roger G. Linington, Ryan S. Renslow, Xuan Cao, Rajarshi Ghosh, Robert Mah, Harrison Peters, Ella F. Poynton, Vera Yang, Eleanor Knutson, Amy M Jystad, Vasuk Gautam, Dana Allen, and Dorsa Varshavi

Subjects

Magnetic Resonance Spectroscopy, Databases, Factual, Biological substances, AcademicSubjects/SCI00010, Biology, 010402 general chemistry, computer.software_genre, 01 natural sciences, Natural (archaeology), Automated data, 03 medical and health sciences, Genetics, Extensive data, Database Issue, Relevance (information retrieval), 030304 developmental biology, Biological Products, Internet, 0303 health sciences, Database, Nuclear magnetic resonance spectroscopy, Nmr data, 0104 chemical sciences, NMR spectra database, computer, Software

Abstract

The Natural Products Magnetic Resonance Database (NP-MRD) is a comprehensive, freely available electronic resource for the deposition, distribution, searching and retrieval of nuclear magnetic resonance (NMR) data on natural products, metabolites and other biologically derived chemicals. NMR spectroscopy has long been viewed as the ‘gold standard’ for the structure determination of novel natural products and novel metabolites. NMR is also widely used in natural product dereplication and the characterization of biofluid mixtures (metabolomics). All of these NMR applications require large collections of high quality, well-annotated, referential NMR spectra of pure compounds. Unfortunately, referential NMR spectral collections for natural products are quite limited. It is because of the critical need for dedicated, open access natural product NMR resources that the NP-MRD was funded by the National Institute of Health (NIH). Since its launch in 2020, the NP-MRD has grown quickly to become the world's largest repository for NMR data on natural products and other biological substances. It currently contains both structural and NMR data for nearly 41,000 natural product compounds from >7400 different living species. All structural, spectroscopic and descriptive data in the NP-MRD is interactively viewable, searchable and fully downloadable in multiple formats. Extensive hyperlinks to other databases of relevance are also provided. The NP-MRD also supports community deposition of NMR assignments and NMR spectra (1D and 2D) of natural products and related meta-data. The deposition system performs extensive data enrichment, automated data format conversion and spectral/assignment evaluation. Details of these database features, how they are implemented and plans for future upgrades are also provided. The NP-MRD is available at https://np-mrd.org.

Published

2021

23. Optimizing colormaps with consideration for color vision deficiency to enable accurate interpretation of scientific data.

Author

Jamie R. Nuñez, Christopher R. Anderton, and Ryan S. Renslow

Published

2017

24. Modeling Substrate Utilization, Metabolite Production, and Uranium Immobilization in Shewanella oneidensis Biofilms

Author

Ryan S. Renslow, Bulbul Ahmed, Jamie R. Nuñez, Bin Cao, Paul D. Majors, Jim K. Fredrickson, and Haluk Beyenal

Subjects

biofilm, bioremediation, EPS, modeling, Shewanella oneidensis, substrate utilization, Environmental sciences, GE1-350

Abstract

In this study, we developed a two-dimensional mathematical model to predict substrate utilization and metabolite production rates in Shewanella oneidensis MR-1 biofilm in the presence and absence of uranium (U). In our model, lactate and fumarate are used as the electron donor and the electron acceptor, respectively. The model includes the production of extracellular polymeric substances (EPS). The EPS bound to the cell surface and distributed in the biofilm were considered bound EPS (bEPS) and loosely associated EPS (laEPS), respectively. COMSOL® Multiphysics finite element analysis software was used to solve the model numerically (model file provided in the Supplementary Material). The input variables of the model were the lactate, fumarate, cell, and EPS concentrations, half saturation constant for fumarate, and diffusion coefficients of the substrates and metabolites. To estimate unknown parameters and calibrate the model, we used a custom designed biofilm reactor placed inside a nuclear magnetic resonance (NMR) microimaging and spectroscopy system and measured substrate utilization and metabolite production rates. From these data we estimated the yield coefficients, maximum substrate utilization rate, half saturation constant for lactate, stoichiometric ratio of fumarate and acetate to lactate and stoichiometric ratio of succinate to fumarate. These parameters are critical to predicting the activity of biofilms and are not available in the literature. Lastly, the model was used to predict uranium immobilization in S. oneidensis MR-1 biofilms by considering reduction and adsorption processes in the cells and in the EPS. We found that the majority of immobilization was due to cells, and that EPS was less efficient at immobilizing U. Furthermore, most of the immobilization occurred within the top 10 μm of the biofilm. To the best of our knowledge, this research is one of the first biofilm immobilization mathematical models based on experimental observation. It has the ability to predict the relative contributions to U immobilization of laEPS, bEPS, and cells.

Published

2017

25. Quantum Chemistry Calculations for Metabolomics

Author

Amy T. Merrill, Lee-Ping Wang, Arthur S. Edison, Susanta Das, Shunyang Wang, Jesi Lee, Kenneth M. Merz, Ryan S. Renslow, Oliver Fiehn, Thomas O. Metz, Tobias Kind, Dean J. Tantillo, Ricardo Moreira Borges, Sean M. Colby, and Jamie R. Nuñez

Subjects

Identification methods, Primary (chemistry), 010405 organic chemistry, Ion-mobility spectrometry, Chemistry, General Chemistry, 010402 general chemistry, 01 natural sciences, Quantum chemistry, 0104 chemical sciences, Identification (information), Metabolomics, Chemical diversity, Biochemical engineering, Sources of error

Abstract

A primary goal of metabolomics studies is to fully characterize the small-molecule composition of complex biological and environmental samples. However, despite advances in analytical technologies over the past two decades, the majority of small molecules in complex samples are not readily identifiable due to the immense structural and chemical diversity present within the metabolome. Current gold-standard identification methods rely on reference libraries built using authentic chemical materials ("standards"), which are not available for most molecules. Computational quantum chemistry methods, which can be used to calculate chemical properties that are then measured by analytical platforms, offer an alternative route for building reference libraries, i.e., in silico libraries for "standards-free" identification. In this review, we cover the major roadblocks currently facing metabolomics and discuss applications where quantum chemistry calculations offer a solution. Several successful examples for nuclear magnetic resonance spectroscopy, ion mobility spectrometry, infrared spectroscopy, and mass spectrometry methods are reviewed. Finally, we consider current best practices, sources of error, and provide an outlook for quantum chemistry calculations in metabolomics studies. We expect this review will inspire researchers in the field of small-molecule identification to accelerate adoption of in silico methods for generation of reference libraries and to add quantum chemistry calculations as another tool at their disposal to characterize complex samples.

Published

2021

26. A Practical Guide to Metabolomics Software Development

Author

Jamey D. Young, Ryan S. Renslow, Gary J. Patti, Hui Yin Chang, Maximilian J. Helf, Shuzhao Li, Sean M. Colby, Javier D. Gomez, Jianguo Xia, Katerina Kechris, Christine Kirkpatrick, Mukesh Verma, Xiuxia Du, and Shankar Subramaniam

Subjects

Extramural, business.industry, Chemistry, Best practice, 010401 analytical chemistry, Software development, Cloud computing, Cloud Computing, 010402 general chemistry, 01 natural sciences, Data science, 0104 chemical sciences, Analytical Chemistry, Metabolomics data, Metabolomics, Software, Perspective, business, Coding (social sciences)

Abstract

A growing number of software tools have been developed for metabolomics data processing and analysis. Many new tools are contributed by metabolomics practitioners who have limited prior experience with software development, and the tools are subsequently implemented by users with expertise that ranges from basic point-and-click data analysis to advanced coding. This Perspective is intended to introduce metabolomics software users and developers to important considerations that determine the overall impact of a publicly available tool within the scientific community. The recommendations reflect the collective experience of an NIH-sponsored Metabolomics Consortium working group that was formed with the goal of researching guidelines and best practices for metabolomics tool development. The recommendations are aimed at metabolomics researchers with little formal background in programming and are organized into three stages: (i) preparation, (ii) tool development, and (iii) distribution and maintenance.

Published

2021

27. DEIMoS: An Open-Source Tool for Processing High-Dimensional Mass Spectrometry Data

Author

Sean M. Colby, Christine H. Chang, Jessica L. Bade, Jamie R. Nunez, Madison R. Blumer, Daniel J. Orton, Kent J. Bloodsworth, Ernesto S. Nakayasu, Richard D. Smith, Yehia M. Ibrahim, Ryan S. Renslow, and Thomas O. Metz

Subjects

Quantitative Biology - Biomolecules, Tandem Mass Spectrometry, FOS: Biological sciences, Metabolomics, Biomolecules (q-bio.BM), Quantitative Biology - Quantitative Methods, Quantitative Methods (q-bio.QM), Algorithms, Software, Analytical Chemistry, Chromatography, Liquid

Abstract

We present DEIMoS: Data Extraction for Integrated Multidimensional Spectrometry, a Python application programming interface (API) and command-line tool for high-dimensional mass spectrometry data analysis workflows that offers ease of development and access to efficient algorithmic implementations. Functionality includes feature detection, feature alignment, collision cross section (CCS) calibration, isotope detection, and MS/MS spectral deconvolution, with the output comprising detected features aligned across study samples and characterized by mass, CCS, tandem mass spectra, and isotopic signature. Notably, DEIMoS operates on N-dimensional data, largely agnostic to acquisition instrumentation; algorithm implementations simultaneously utilize all dimensions to (i) offer greater separation between features, thus improving detection sensitivity, (ii) increase alignment/feature matching confidence among datasets, and (iii) mitigate convolution artifacts in tandem mass spectra. We demonstrate DEIMoS with LC-IMS-MS/MS data to illustrate the advantages of a multidimensional approach in each data processing step.

Published

2022

28. A generalized spatial measure for resilience of microbial systems

Author

Ryan S. Renslow, Stephen R. Lindemann, and Hyun-Seob eSong

Subjects

Ecology, Recovery, microbial communities, resilience, emergent properties, Microbiology, QR1-502

Abstract

The emergent property of resilience is the ability of a system to recover an original function after a disturbance. Resilience may be used as an early warning system for significant or irreversible community transition, i.e., a community with diminishing or low resilience may be close to catastrophic shift in function or an irreversible collapse. Typically, resilience is quantified using recovery time, which may be difficult or impossible to directly measure in microbial systems. A recent study in the literature showed that under certain conditions, a set of spatial-based metrics termed recovery length, can be correlated to recovery time, and thus may be a reasonable alternative measure of resilience. As a limitation, however, this spatial metric of resilience is useful only for step-change perturbations. Building upon the concept of recovery length, we propose a more general form of the spatial metric of resilience that can be applied to any shape of perturbation profiles (i.e., a sharp or smooth gradient). We termed this new spatial measure perturbation-adjusted spatial metric of resilience (PASMORE). We demonstrate the applicability of the proposed metric using a mathematical model of a microbial mat.

Published

2016

29. Spatiotemporal Metabolic Network Models Reveal Complex Autotroph-Heterotroph Biofilm Interactions Governed by Photon Incidences

Author

Poonam Phalak, Hans C. Bernstein, Stephen R. Lindemann, Ryan S. Renslow, Dennis G. Thomas, Michael A. Henson, and Hyun-Seob Song

Subjects

Control and Systems Engineering

Abstract

Autotroph-heterotroph interactions are ubiquitous in natural environment and play a key role in controlling various essential ecosystem functions, such as production and utilization of organic matter, cycling of nitrogen, sulfur, and other chemical elements. Understanding how these biofilm metabolic interactions are constrained in space and time remains challenging because fully predictive models designed for this purpose are currently limited. Toward filling this gap, here we developed community metabolic network models for two autotroph-heterotroph biofilm consortia (termed UCC-A and UCC-O), which share a suite of common heterotrophic members but have a single distinct photoautotrophic cyanobacterium (Phormidesmis priestleyi str. ANA and Phormidium sp. OSCR) that provides organic carbon and nitrogen sources to support the growth of heterotrophic partners. After determining model parameters by data fitting using the spatiotemporal distributions of microbial abundances, we comparatively analyzed the resulting biofilm models to examine any fundamental differences in microbial interactions between the two consortia under the variation of key environmental variables: CO2 and photon levels. The UCC-A model predicted generally expected responses, i.e., the autotroph population increased in response to elevated levels of CO2 and photon, followed by increase in the heterotroph population. In contrast, the UCC-O model showed somewhat complicated dynamics, e.g., higher photon incidence rates resulted in the increase in autotroph population but decrease in heterotroph population due to the lowered provision of glucose from the autotroph. A further analysis showed that species coexistence was governed by the photon incidences rather than the carbon availability for UCC-O, which was the opposite for UCC-A.

Published

2022

30. Effects of warming on bacterial growth rates in a peat soil under ambient and elevated CO2

Author

Sheryl L. Bell, Amy E. Zimmerman, Bram W. Stone, Christine H. Chang, Madison Blumer, Ryan S. Renslow, Jeffrey R. Propster, Michaela Hayer, Egbert Schwartz, Bruce A. Hungate, and Kirsten S. Hofmockel

Subjects

Soil Science, Microbiology

Published

2023

31. An Introduction to the Benchmarking and Publications for Non-Targeted Analysis Working Group

Author

Jonathan K. Challis, Elin M. Ulrich, Alex Chao, Samanthi Wickramasekara, Alan M. Hood, Katherine T. Peter, Jon R. Sobus, Natalia Quinete, Allison L. Phillips, Andrew D. McEachran, Brian Ng, Bowen Du, Jamie R. Nuñez, Seth Newton, Kristin Favela, Sara L. Nason, Yong-Lai Feng, Antony J. Williams, Benjamin J. Place, Ryan S. Renslow, Benedikt Warth, Eric M. Sussman, Ann M. Knolhoff, Piero R. Gardinali, and Christine M. Fisher

Subjects

0303 health sciences, Test data generation, 010401 analytical chemistry, Analysis working, Harmonization, Benchmarking, 01 natural sciences, Data science, Article, 0104 chemical sciences, Analytical Chemistry, Variety (cybernetics), 03 medical and health sciences, Consistency (database systems), Environmental science, Humans, Instrumentation (computer programming), Dissemination, 030304 developmental biology

Abstract

Non-targeted analysis (NTA) encompasses a rapidly evolving set of mass spectrometry techniques aimed at characterizing the chemical composition of complex samples, identifying unknown compounds, and/or classifying samples, without prior knowledge regarding the chemical content of the samples. Recent advances in NTA are the result of improved and more accessible instrumentation for data generation and analysis tools for data evaluation and interpretation. As researchers continue to develop NTA approaches in various scientific fields, there is a growing need to identify, disseminate, and adopt community-wide method reporting guidelines. In 2018, NTA researchers formed the Benchmarking and Publications for Non-Targeted Analysis Working Group (BP4NTA) to address this need. Consisting of participants from around the world and representing fields ranging from environmental science and food chemistry to 'omics and toxicology, BP4NTA provides resources addressing a variety of challenges associated with NTA. Thus far, BP4NTA group members have aimed to establish a consensus on NTA-related terms and concepts and to create consistency in reporting practices by providing resources on a public Web site, including consensus definitions, reference content, and lists of available tools. Moving forward, BP4NTA will provide a setting for NTA researchers to continue discussing emerging challenges and contribute to additional harmonization efforts.

Published

2021

32. Mass Spectrometry Adduct Calculator

Author

Christine H. Chang, Evangelina Brayfindley, Jamie R. Nuñez, Sean M. Colby, Madison R. Blumer, Thomas O. Metz, and Ryan S. Renslow

Subjects

Chemistry, General Chemical Engineering, Analytical chemistry, Mass spectral library, General Chemistry, Library and Information Sciences, Mass spectrometry, Spectral line, Article, Mass Spectrometry, Computer Science Applications, Ion, Adduct, Molecular networking, Molecule, Chromatography, Liquid

Abstract

We describe the Mass Spectrometry Adduct Calculator (MSAC), an automated Python tool to calculate the adduct ion masses of a parent molecule. Here, adduct refers to a version of a parent molecule [M] that is charged due to addition or loss of atoms and electrons resulting in a charged ion, for example, [M + H](+). MSAC includes a database of 147 potential adducts and adduct/neutral loss combinations and their mass-to-charge ratios (m/z) as extracted from the NIST/EPA/NIH Mass Spectral Library (NIST17), Global Natural Products Social Molecular Networking Public Spectral Libraries (GNPS), and MassBank of North America (MoNA). The calculator relies on user-selected subsets of the combined database to calculate expected m/z for adducts of molecules supplied as formulas. This tool is intended to help researchers create identification libraries to collect evidence for the presence of molecules in mass spectrometry data. While the included adduct database focuses on adducts typically detected during liquid chromatography–mass spectrometry analyses, users may supply their own lists of adducts and charge states for calculating expected m/z. We also analyzed statistics on adducts from spectra contained in the three selected mass spectral libraries. MSAC is freely available at https://github.com/pnnl/MSAC.

Published

2021

33. Integrating ecological and engineering concepts of resilience in microbial communities

Author

Hyun-Seob eSong, Ryan S. Renslow, Jim K Fredrickson, and Steve R. Lindemann

Subjects

robustness, networks, stability, microbial ecology, Resistance, microbial communities, Microbiology, QR1-502

Abstract

Many definitions of resilience have been proffered for natural and engineered ecosystems, but a conceptual consensus on resilience in microbial communities is still lacking. We argue that the disconnect largely results from the wide variance in microbial community complexity, which range from compositionally simple synthetic consortia to complex natural communities, and divergence between the typical practical outcomes emphasized by ecologists and engineers. Viewing microbial communities as elasto-plastic systems that undergo both recoverable and unrecoverable transitions, we argue that this gap between the engineering and ecological definitions of resilience stems from their respective emphases on elastic and plastic deformation, respectively. We propose that the two concepts may be fundamentally united around the resilience of function rather than state in microbial communities and the regularity in the relationship between environmental variation and a community’s functional response. Furthermore, we posit that functional resilience is an intrinsic property of microbial communities and suggest that state changes in response to environmental variation may be a key mechanism driving functional resilience in microbial communities.

Published

2015

34. Evaluation of In Silico Multifeature Libraries for Providing Evidence for the Presence of Small Molecules in Synthetic Blinded Samples

Author

Ryan S. Renslow, Elin M. Ulrich, Jon R. Sobus, Jamie R. Nuñez, Sean M. Colby, Malak M. Tfaily, Justin G. Teeguarden, Dennis G. Thomas, Nikola Tolić, and Thomas O. Metz

Subjects

010304 chemical physics, Computer science, General Chemical Engineering, In silico, General Chemistry, Computational biology, Gold standard (test), Library and Information Sciences, 01 natural sciences, Small molecule, 0104 chemical sciences, Computer Science Applications, 010404 medicinal & biomolecular chemistry, Metabolomics, 0103 physical sciences, Molecular identification

Abstract

The current gold standard for unambiguous molecular identification in metabolomics analysis is comparing two or more orthogonal properties from the analysis of authentic reference materials (standa...

Published

2019

35. High-resolution elemental mapping of the root-rhizosphere-soil continuum using laser-induced breakdown spectroscopy (LIBS)

Author

P. Ilhardt, Joshua J. Rosnow, Elizabeth H. Denis, Jamie R. Nuñez, Ryan S. Renslow, Eirik J. Krogstad, and James J. Moran

Subjects

Rhizosphere, Spectral signature, Environmental remediation, Trace element, Soil Science, Soil science, 04 agricultural and veterinary sciences, Microbiology, Loam, Alfisol, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Environmental science, Sample preparation, Laser-induced breakdown spectroscopy

Abstract

Understanding the complex chemical nature of root-soil interactions is essential for building the next generation of sustainable agricultural systems and facilitating long-term environmental remediation strategies. Techniques currently suited to investigate spatial controls on nutrient exchange in plant rhizospheres, however, are hindered by limitations in throughput, cost, analytical scope, and sample preparation needs. We describe here a method for rapid, high-resolution (∼100 μm), multi-element imaging of both organic content and inorganic constituents in root-rhizosphere-soil systems using laser-induced breakdown spectroscopy (LIBS). A switchgrass assemblage (Panicum virgatum) was grown in compact rhizotrons containing a sandy loam Alfisol from the Kellogg Biological Station (KBS), Michigan, USA. Root-soil samples were extracted using custom plastic coring devices for live root sampling and a modified drill press for sectioning frozen stabilized soil. A 266 nm, Nd:YAG laser was rastered over ∼10 mm2 sample surfaces and broadband spectra from single-pulse ablations were collected and mapped to discrete XY spatial coordinates for simultaneous imaging of 17 macronutrients, micronutrients and matrix elements. In order to rapidly process LIBS raster data and investigate chemical trends in the rhizosphere, an open-source Python module was developed, in which we used a novel calibration-free masking algorithm (based on principal components analysis (PCA) of normalized spectral intensities) to discriminate soil mineral grains, root fragments, and associated rhizosphere regions. We observed fine-scale chemical gradients within only a millimeter of switchgrass roots, consistent with rhizodeposition of organic compounds and proximal uptake of inorganic nutrients. Detection of trace element and carbon accumulations with diagnostic spectral signatures in the rhizosphere suggested the presence of residues (detritusphere) that could serve as sites of preferential microbial accumulation. These results highlight potential applications of LIBS within the growing field of spatially-resolved plant-soil analysis and extend its versatile imaging capabilities to the complex root-rhizosphere-soil network.

Published

2019

36. ISiCLE: A Quantum Chemistry Pipeline for Establishing in Silico Collision Cross Section Libraries

Author

Justin G. Teeguarden, Dennis G. Thomas, Niranjan Govind, Ryan S. Renslow, Joseph Brown, Sean M. Colby, Kurt R. Glaesemann, Douglas J. Baxter, Jamie R. Nuñez, Meg Pirrung, and Thomas O. Metz

Subjects

Cheminformatics, 010401 analytical chemistry, Molecular Dynamics Simulation, 010402 general chemistry, computer.software_genre, 01 natural sciences, Article, 0104 chemical sciences, Analytical Chemistry, Characterization (materials science), Chemical library, Machine Learning, Small Molecule Libraries, Set (abstract data type), Identifier, Identification (information), chemistry.chemical_compound, Workflow, Models, Chemical, Code refactoring, chemistry, Data mining, computer, Density Functional Theory

Abstract

High-throughput, comprehensive, and confident identifications of metabolites and other chemicals in biological and environmental samples will revolutionize our understanding of the role these chemically diverse molecules play in biological systems. Despite recent technological advances, metabolomics studies still result in the detection of a disproportionate number of features that cannot be confidently assigned to a chemical structure. This inadequacy is driven by the single most significant limitation in metabolomics, the reliance on reference libraries constructed by analysis of authentic reference materials with limited commercial availability. To this end, we have developed the in silico chemical library engine (ISiCLE), a high-performance computing-friendly cheminformatics workflow for generating libraries of chemical properties. In the instantiation described here, we predict probable three-dimensional molecular conformers (i.e., conformational isomers) using chemical identifiers as input, from which collision cross sections (CCS) are derived. The approach employs first-principles simulation, distinguished by the use of molecular dynamics, quantum chemistry, and ion mobility calculations, to generate structures and chemical property libraries, all without training data. Importantly, optimization of ISiCLE included a refactoring of the popular MOBCAL code for trajectory-based mobility calculations, improving its computational efficiency by over 2 orders of magnitude. Calculated CCS values were validated against 1983 experimentally measured CCS values and compared to previously reported CCS calculation approaches. Average calculated CCS error for the validation set is 3.2% using standard parameters, outperforming other density functional theory (DFT)-based methods and machine learning methods (e.g., MetCCS). An online database is introduced for sharing both calculated and experimental CCS values ( metabolomics.pnnl.gov ), initially including a CCS library with over 1 million entries. Finally, three successful applications of molecule characterization using calculated CCS are described, including providing evidence for the presence of an environmental degradation product, the separation of molecular isomers, and an initial characterization of complex blinded mixtures of exposure chemicals. This work represents a method to address the limitations of small molecule identification and offers an alternative to generating chemical identification libraries experimentally by analyzing authentic reference materials. All code is available at github.com/pnnl .

Published

2019

37. New mass spectrometry technologies contributing towards comprehensive and high throughput omics analyses of single cells

Author

Ying Zhu, Gabe Nagy, Sneha P. Couvillion, Ryan T. Kelly, Yehia M. Ibrahim, Thomas O. Metz, Joshua N. Adkins, Ryan S. Renslow, Paul D. Piehowski, and Charles Ansong

Subjects

Proteomics, Computer science, Systems biology, 02 engineering and technology, Computational biology, 01 natural sciences, Biochemistry, Article, Mass Spectrometry, Analytical Chemistry, Metabolomics, Single-cell analysis, Electrochemistry, Humans, Environmental Chemistry, Precision Medicine, Throughput (business), Spectroscopy, Systems Biology, 010401 analytical chemistry, Genomics, 021001 nanoscience & nanotechnology, Omics, Precision medicine, 0104 chemical sciences, Identification (biology), Single-Cell Analysis, 0210 nano-technology

Abstract

Mass-spectrometry based omics technologies - namely proteomics, metabolomics and lipidomics - have enabled the molecular level systems biology investigation of organisms in unprecedented detail. There has been increasing interest for gaining a thorough, functional understanding of the biological consequences associated with cellular heterogeneity in a wide variety of research areas such as developmental biology, precision medicine, cancer research and microbiome science. Recent advances in mass spectrometry (MS) instrumentation and sample handling strategies are quickly making comprehensive omics analyses of single cells feasible, but key breakthroughs are still required to push through remaining bottlenecks. In this review, we discuss the challenges faced by single cell MS-based omics analyses and highlight recent technological advances that collectively can contribute to comprehensive and high throughput omics analyses in single cells. We provide a vision of the potential of integrating pioneering technologies such as Structures for Lossless Ion Manipulations (SLIM) for improved sensitivity and resolution, novel peptide identification tactics and standards free metabolomics approaches for future applications in single cell analysis.

Published

2019

38. Correction to 'Chespa: Streamlining Expansive Chemical Space Evaluation of Molecular Sets'

Author

Thomas O. Metz, Monee Y. McGrady, Jamie R. Nuñez, Ryan S. Renslow, and Yasemin Yesiltepe

Subjects

Information retrieval, Computer science, General Chemical Engineering, Published Erratum, MEDLINE, General Chemistry, Library and Information Sciences, Expansive, Chemical space, Article, Computer Science Applications

Published

2021

39. Exploring the impacts of conformer selection methods on ion mobility collision cross section predictions

Author

Felicity F. Nielson, Thomas O. Metz, Sean M. Colby, Ryan S. Renslow, and Dennis G. Thomas

Subjects

Chemical Physics (physics.chem-ph), genetic structures, Ion-mobility spectrometry, Chemistry, 010401 analytical chemistry, Molecular Conformation, FOS: Physical sciences, Biomolecules (q-bio.BM), Molecular Dynamics Simulation, 010402 general chemistry, Collision, 01 natural sciences, Molecular physics, Article, 0104 chemical sciences, Analytical Chemistry, Ion, Cross section (physics), Quantitative Biology - Biomolecules, Physics - Chemical Physics, FOS: Biological sciences, Ion Mobility Spectrometry, Selection method, Conformational isomerism, Selection (genetic algorithm)

Abstract

The prediction of structure dependent molecular properties, such as collision cross sections as measured using ion mobility spectrometry, are crucially dependent on the selection of the correct population of molecular conformers. Here, we report an in-depth evaluation of multiple conformation selection techniques, including simple averaging, Boltzmann weighting, lowest energy selection, low energy threshold reductions, and similarity reduction. Generating 50 000 conformers each for 18 molecules, we used the In Silico Chemical Library Engine (ISiCLE) to calculate the collision cross sections for the entire data set. First, we employed Monte Carlo simulations to understand the variability between conformer structures as generated using simulated annealing. Then we employed Monte Carlo simulations to the aforementioned conformer selection techniques applied on the simulated molecular property: the ion mobility collision cross section. Based on our analyses, we found Boltzmann weighting to be a good trade-off between precision and theoretical accuracy. Combining multiple techniques revealed that energy thresholds and root-mean-squared deviation-based similarity reductions can save considerable computational expense while maintaining property prediction accuracy. Molecular dynamic conformer generation tools like AMBER can continue to generate new lowest energy conformers even after tens of thousands of generations, decreasing precision between runs. This reduced precision can be ameliorated and theoretical accuracy increased by running density functional theory geometry optimization on carefully selected conformers.

Published

2021

40. The Epsomitic Phototrophic Microbial Mat of Hot Lake, Washington: Community Structural Responses to Seasonal Cycling

Author

Stephen R Lindemann, James J Moran, James C Stegen, Ryan S Renslow, Janine R Hutchison, Jessica K Cole, Alice C Dohnalkova, Julien eTremblay, Kanwar eSingh, Stephanie A Malfatti, Feng eChen, Susannah Green Tringe, Haluk eBeyenal, and James K Fredrickson

Subjects

Alphaproteobacteria, Cyanobacteria, Light, Magnesium Sulfate, 16S rRNA, Next-generation sequencing, Microbiology, QR1-502

Abstract

Phototrophic microbial mats are compact ecosystems composed of highly interactive organisms in which energy and element cycling take place over millimeter-to-centimeter-scale distances. Although microbial mats are common in hypersaline environments, they have not been extensively characterized in systems dominated by divalent ions. Hot Lake is a meromictic, epsomitic lake that occupies a small, endorheic basin in north-central Washington. The lake harbors a benthic, phototrophic mat that assembles each spring and disassembles each fall and is subject to greater than tenfold variation in salinity (primarily Mg2+ and SO42-) and irradiation over the annual cycle. We examined spatiotemporal variation in the mat community at five time points throughout the annual cycle with respect to prevailing physicochemical parameters by sequencing the V4 region of the 16S rRNA gene coupled to near-full-length 16S RNA clone sequences. The composition of these microbial communities was relatively stable over the seasonal cycle and included dominant populations of Cyanobacteria, primarily a group IV cyanobacterium (Leptolyngbya), and Alphaproteobacteria (specifically, members of Rhodobacteraceae and Geminicoccus). Members of Gammaproteobacteria (e.g., Thioalkalivibrio and Halochromatium) and Deltaproteobacteria (e.g., Desulfofustis) that are likely to be involved in sulfur cycling peaked in summer and declined significantly by mid-fall, mirroring larger trends in mat community richness and evenness. Phylogenetic turnover analysis of abundant phylotypes employing environmental metadata suggests that seasonal shifts in light variability exert a dominant influence on the composition of Hot Lake microbial mat communities. The seasonal development and organization of these structured microbial mats provide opportunities for analysis of the temporal and physical dynamics that feed back to community function.

Published

2013

41. An initial investigation of accuracy required for the identification of small molecules in complex samples using quantum chemical calculated NMR chemical shifts

Author

Niri Govind, Yasemin Yesiltepe, Ryan S. Renslow, and Thomas O. Metz

Subjects

Quantum chemical, Materials science, Chemical physics, Chemical shift, Identification (biology), Library and Information Sciences, Physical and Theoretical Chemistry, Computer Graphics and Computer-Aided Design, Small molecule, Computer Science Applications

Abstract

The majority of primary and secondary metabolites in nature have yet to be identified, representing a major challenge for metabolomics studies that currently require reference libraries from analyses of authentic compounds. Using currently available analytical methods, complete chemical characterization of metabolomes is infeasible for both technical and economic reasons. For example, unambiguous identification of metabolites is limited by the availability of authentic chemical standards, which, for the majority of molecules, do not exist. Computationally predicted or calculated data are a viable solution to expand the currently limited metabolite reference libraries, if such methods are shown to be sufficiently accurate. For example, determining nuclear magnetic resonance (NMR) spectroscopy spectra in silico has shown promise in the identification and delineation of metabolite structures. Many researchers have been taking advantage of density functional theory (DFT), a computationally inexpensive yet reputable method for the prediction of carbon and proton NMR spectra of metabolites. However, such methods are expected to have some error in predicted 13C and 1H NMR spectra with respect to experimentally measured values. This leads us to the question–what accuracy is required in predicted 13C and 1H NMR chemical shifts for confident metabolite identification? Using the set of 11,716 small molecules found in the Human Metabolome Database (HMDB), we simulated both experimental and theoretical NMR chemical shift databases. We investigated the level of accuracy required for identification of metabolites in simulated pure and impure samples by matching predicted chemical shifts to experimental data. We found 90% or more of molecules in simulated pure samples can be successfully identified when errors of 1H and 13C chemical shifts in water are below 0.6 ppm and 7.1 ppm, respectively, and below 0.5 ppm and 4.6 ppm in chloroform solvation, respectively. In simulated complex mixtures, as the complexity of the mixture increased, greater accuracy of the calculated chemical shifts was required, as expected. However, if the number of molecules in the mixture is known, e.g., when NMR is combined with MS and sample complexity is low, the likelihood of confident molecular identification increased by 90%.

Published

2020

42. Nitrogen Source Governs Community Carbon Metabolism in a Model Hypersaline Benthic Phototrophic Biofilm

Author

Mary S. Lipton, Robert Starke, James K. Fredrickson, James J. Moran, Stephen R. Lindemann, Amy A. Boaro, Christopher R. Anderton, Hayley C. Cardamone, Alexandra B. Cory, Ryan S. Renslow, Jamie R. Nuñez, Jessica K. Cole, Jennifer M. Mobberley, Beau R. Morton, Yasemin Yesiltepe, and Kirsten S. Hofmockel

Subjects

Biogeochemical cycle, Physiology, lcsh:QR1-502, chemistry.chemical_element, stable isotopes, carbon cycling, Biochemistry, Microbiology, cyanobacteria, lcsh:Microbiology, Carbon cycle, 03 medical and health sciences, Nutrient, nitrogen cycling, Genetics, Molecular Biology, Nitrogen cycle, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, mass spectrometry, 0303 health sciences, 030306 microbiology, Chemistry, Applied and Environmental Science, Aquatic ecosystem, Nitrogen, QR1-502, Computer Science Applications, Modeling and Simulation, Environmental chemistry, Nitrogen fixation, Eutrophication, Research Article

Abstract

Anthropogenic inputs of nitrogen into aquatic ecosystems, and especially those of agricultural origin, involve a mix of chemical species. Although it is well-known in general that nitrogen eutrophication markedly influences the metabolism of aquatic phototrophic communities, relatively little is known regarding whether the specific chemical form of nitrogen inputs matter. Our data suggest that the nitrogen form alters the rate of nitrogen uptake significantly, whereas corresponding alterations in carbon uptake were minor. However, differences imposed by uptake of divergent nitrogen forms may result in alterations among phototroph-heterotroph interactions that rewire community metabolism. Furthermore, our data hint that availability of other nutrients (i.e., iron) might mediate the linkage between carbon and nitrogen cycling in these communities. Taken together, our data suggest that different nitrogen forms should be examined for divergent impacts on phototrophic communities in fluvial systems and that these anthropogenic nitrogen inputs may significantly differ in their ultimate biogeochemical impacts., Increasing anthropogenic inputs of fixed nitrogen are leading to greater eutrophication of aquatic environments, but it is unclear how this impacts the flux and fate of carbon in lacustrine and riverine systems. Here, we present evidence that the form of nitrogen governs the partitioning of carbon among members in a genome-sequenced, model phototrophic biofilm of 20 members. Consumption of NO3− as the sole nitrogen source unexpectedly resulted in more rapid transfer of carbon to heterotrophs than when NH4+ was also provided, suggesting alterations in the form of carbon exchanged. The form of nitrogen dramatically impacted net community nitrogen, but not carbon, uptake rates. Furthermore, this alteration in nitrogen form caused very large but focused alterations to community structure, strongly impacting the abundance of only two species within the biofilm and modestly impacting a third member species. Our data suggest that nitrogen metabolism may coordinate coupled carbon-nitrogen biogeochemical cycling in benthic biofilms and, potentially, in phototroph-heterotroph consortia more broadly. It further indicates that the form of nitrogen inputs may significantly impact the contribution of these communities to carbon partitioning across the terrestrial-aquatic interface. IMPORTANCE Anthropogenic inputs of nitrogen into aquatic ecosystems, and especially those of agricultural origin, involve a mix of chemical species. Although it is well-known in general that nitrogen eutrophication markedly influences the metabolism of aquatic phototrophic communities, relatively little is known regarding whether the specific chemical form of nitrogen inputs matter. Our data suggest that the nitrogen form alters the rate of nitrogen uptake significantly, whereas corresponding alterations in carbon uptake were minor. However, differences imposed by uptake of divergent nitrogen forms may result in alterations among phototroph-heterotroph interactions that rewire community metabolism. Furthermore, our data hint that availability of other nutrients (i.e., iron) might mediate the linkage between carbon and nitrogen cycling in these communities. Taken together, our data suggest that different nitrogen forms should be examined for divergent impacts on phototrophic communities in fluvial systems and that these anthropogenic nitrogen inputs may significantly differ in their ultimate biogeochemical impacts.

Published

2020

43. Monitoring Electron Transfer Rates of Electrode-Respiring Cells

Author

Haluk Beyenal, Ozlem Istanbullu, Ryan S. Renslow, and Jerome T. Babauta

Subjects

Electron transfer, Materials science, Electrode, Inorganic chemistry

Published

2020

44. Water‐dispersible nanocolloids and higher temperatures promote the release of carbon from riparian soil

Author

Wooyong Um, Mark E. Bowden, Kenton A. Rod, Weinan Leng, Ryan S. Renslow, Odeta Qafoku, Michael F. Hochella, Ravi K. Kukkadapu, Sean M. Colby, A. Peyton Smith, and Vanessa L. Bailey

Subjects

Water dispersible, geography, QE1-996.5, geography.geographical_feature_category, Soil Science, chemistry.chemical_element, Geology, Environmental sciences, chemistry, Environmental chemistry, Environmental science, GE1-350, Carbon, Riparian zone

Abstract

Increasing temperatures in alpine regions accompanied by glacial retreat is occurring rapidly due to climate change. This may affect riparian soils by increasing weathering rates, resulting in greater organic carbon (OC) release to rivers via movement of iron‐containing colloids and nanominerals. Increased concentrations of iron‐ or silcate‐nanominerals would result in higher surface area for OC adsorption. To test the influence of temperature on OC leaching, we examined mineral weathering and nanocolloid facilitated release of OC through a series of controlled laboratory batch and column experiments using sediment from the banks of the Nisqually River, Mount Rainier in Washington State (USA). Additional experiments were conducted using the same sediments, but with an illite amendment added to test the influence of additional surface area and nanominerals that many sediments along the Nisqually River contain. These higher‐ and lower‐surface‐area sediments (i.e., sediments with and without the illite amendment) were incubated for 90 d at 4 or 20 °C, followed by batch and column OC leaching tests. Results show that OC leaching rates for 20 °C were two to three times greater than for 4 °C. Further, our results suggest that nanocolloids are responsible for moving this increased OC load from these sediments. When hydrologically connected, OC is released from bank sediments to rivers faster than presently anticipated in fluvial environments experiencing climate change‐induced glacial retreat. Further, a one‐dimensional, finite‐element computational model developed for this study estimates that a 1 °C increase in temperature over a 90‐d summer runoff period increases the OC release rate from sediments by 79%.

Published

2020

45. Isolation of Tryptanthrin and Reassessment of Evidence for Its Isobaric Isostere Wrightiadione in Plants of the Wrightia Genus

Author

Mark E. Bowden, Ryan S. Renslow, Mowei Zhou, Rhea C. Garcellano, Yehia M. Ibrahim, Dennis G. Thomas, Syed G. A. Moinuddin, Isaac K. Attah, Scott G. Franzblau, Sean M. Colby, Robert P. Young, Rui Ma, John R. Cort, Alicia M. Aguinaldo, Yasemin Yesiltepe, Norman G. Lewis, Christopher D. Chouinard, and Gabe Nagy

Subjects

Wrightiadione, Isostere, Stereochemistry, Proton Magnetic Resonance Spectroscopy, Antitubercular Agents, Pharmaceutical Science, Microbial Sensitivity Tests, 01 natural sciences, Mass Spectrometry, Analytical Chemistry, chemistry.chemical_compound, Isoflavonoid, Genus, Drug Discovery, Carbon-13 Magnetic Resonance Spectroscopy, Quinazolinone, Pharmacology, Molecular Structure, biology, 010405 organic chemistry, Chemistry, Alkaloid, Organic Chemistry, Mycobacterium tuberculosis, biology.organism_classification, Isoflavones, 0104 chemical sciences, Apocynaceae, Wrightia, 010404 medicinal & biomolecular chemistry, Complementary and alternative medicine, Quinazolines, Molecular Medicine, Isobaric process

Abstract

A series of Wrightia hanleyi extracts was screened for activity against Mycobacterium tuberculosis H37Rv. One active fraction contained a compound that initially appeared to be either the isoflavonoid wrightiadione or the alkaloid tryptanthrin, both of which have been previously reported in other Wrightia species. Characterization by NMR and MS, as well as evaluation of the literature describing these compounds, led to the conclusion that wrightiadione (1) was misidentified in the first report of its isolation from W. tomentosa in 1992 and again in 2015 when reported in W. pubescens and W. religiosa. Instead, the molecule described in these reports and in the present work is almost certainly the isobaric (same nominal mass) and isosteric (same number of atoms, valency, and shape) tryptanthrin (2), a well-known quinazolinone alkaloid found in a variety of plants including Wrightia species. Tryptanthrin (2) is also accessible synthetically via several routes and has been thoroughly characterized. Wrightiadione (1) has been synthesized and characterized and may have useful biological activity; however, this compound can no longer be said to be known to exist in Nature. To our knowledge, this misidentification of wrightiadione (1) has heretofore been unrecognized.

Published

2018

46. Improving network inference algorithms using resampling methods

Author

Christopher C. Overall, Ryan S. Renslow, Jason E. McDermott, Sean M. Colby, and Ryan McClure

Subjects

0301 basic medicine, Resampling, Computer science, Bootstrap aggregating, 0206 medical engineering, Inference, Gene Expression, 02 engineering and technology, computer.software_genre, lcsh:Computer applications to medicine. Medical informatics, Biochemistry, 03 medical and health sciences, Aggregation, Gene regulatory network inference, Structural Biology, Humans, Gene Regulatory Networks, Statistical theory, Molecular Biology, lcsh:QH301-705.5, Bootstrapping (statistics), Propagation of uncertainty, Applied Mathematics, Biological network inference, Random subspace method, Computer Science Applications, 030104 developmental biology, lcsh:Biology (General), Outlier, Bootstrapping, lcsh:R858-859.7, Data mining, computer, 020602 bioinformatics, Algorithms, Research Article

Abstract

Background Relatively small changes to gene expression data dramatically affect co-expression networks inferred from that data which, in turn, can significantly alter the subsequent biological interpretation. This error propagation is an underappreciated problem that, while hinted at in the literature, has not yet been thoroughly explored. Resampling methods (e.g. bootstrap aggregation, random subspace method) are hypothesized to alleviate variability in network inference methods by minimizing outlier effects and distilling persistent associations in the data. But the efficacy of the approach assumes the generalization from statistical theory holds true in biological network inference applications. Results We evaluated the effect of bootstrap aggregation on inferred networks using commonly applied network inference methods in terms of stability, or resilience to perturbations in the underlying expression data, a metric for accuracy, and functional enrichment of edge interactions. Conclusion Bootstrap aggregation results in improved stability and, depending on the size of the input dataset, a marginal improvement to accuracy assessed by each method’s ability to link genes in the same functional pathway. Electronic supplementary material The online version of this article (10.1186/s12859-018-2402-0) contains supplementary material, which is available to authorized users.

Published

2018

47. An automated framework for NMR chemical shift calculations of small organic molecules

Author

Justin G. Teeguarden, Dennis G. Thomas, Sean M. Colby, Thomas O. Metz, Ryan S. Renslow, Patrick N. Reardon, Niranjan Govind, Jamie R. Nuñez, Mark I. Borkum, Nancy M. Washton, and Yasemin Yesiltepe

Subjects

Materials science, Library and Information Sciences, 010402 general chemistry, 01 natural sciences, Quantum chemistry, DFT, Spectral line, Chemical library, lcsh:Chemistry, chemistry.chemical_compound, Molecule, Metabolomics, Physical and Theoretical Chemistry, lcsh:T58.5-58.64, 010405 organic chemistry, lcsh:Information technology, Chemical shift, Solvation, Computer Graphics and Computer-Aided Design, NMR, 0104 chemical sciences, Computer Science Applications, NMR spectra database, chemistry, lcsh:QD1-999, Chemical physics, NWchem, Density functional theory, Research Article, Python

Abstract

When using nuclear magnetic resonance (NMR) to assist in chemical identification in complex samples, researchers commonly rely on databases for chemical shift spectra. However, authentic standards are typically depended upon to build libraries experimentally. Considering complex biological samples, such as blood and soil, the entirety of NMR spectra required for all possible compounds would be infeasible to ascertain due to limitations of available standards and experimental processing time. As an alternative, we introduce the in silico Chemical Library Engine (ISiCLE) NMR chemical shift module to accurately and automatically calculate NMR chemical shifts of small organic molecules through use of quantum chemical calculations. ISiCLE performs density functional theory (DFT)-based calculations for predicting chemical properties—specifically NMR chemical shifts in this manuscript—via the open source, high-performance computational chemistry software, NWChem. ISiCLE calculates the NMR chemical shifts of sets of molecules using any available combination of DFT method, solvent, and NMR-active nuclei, using both user-selected reference compounds and/or linear regression methods. Calculated NMR chemical shifts are provided to the user for each molecule, along with comparisons with respect to a number of metrics commonly used in the literature. Here, we demonstrate ISiCLE using a set of 312 molecules, ranging in size up to 90 carbon atoms. For each, calculation of NMR chemical shifts have been performed with 8 different levels of DFT theory, and with solvation effects using the implicit solvent Conductor-like Screening Model. The DFT method dependence of the calculated chemical shifts have been systematically investigated through benchmarking and subsequently compared to experimental data available in the literature. Furthermore, ISiCLE has been applied to a set of 80 methylcyclohexane conformers, combined via Boltzmann weighting and compared to experimental values. We demonstrate that our protocol shows promise in the automation of chemical shift calculations and, ultimately, the expansion of chemical shift libraries. Electronic supplementary material The online version of this article (10.1186/s13321-018-0305-8) contains supplementary material, which is available to authorized users.

Published

2018

48. PIXiE: an algorithm for automated ion mobility arrival time extraction and collision cross section calculation using global data association

Author

Thomas O. Metz, Samuel H. Payne, Justin G. Teeguarden, Yehia M. Ibrahim, Ryan S. Renslow, Dennis G. Thomas, Jian Ma, Xueyun Zheng, Christopher S. Wilkins, Matthew E. Monroe, Erin S. Baker, Richard D. Smith, and Cameron P. Casey

Subjects

0301 basic medicine, Statistics and Probability, Ion-mobility spectrometry, Computer science, Real-time computing, Computational Biology, Omics, Mass spectrometry, Original Papers, Biochemistry, Mass Spectrometry, Computer Science Applications, Set (abstract data type), 03 medical and health sciences, Computational Mathematics, 030104 developmental biology, Computational Theory and Mathematics, Pixie, Data and Text Mining, Molecular Biology, Throughput (business), Algorithm, Algorithms, Software

Abstract

Motivation Drift tube ion mobility spectrometry coupled with mass spectrometry (DTIMS-MS) is increasingly implemented in high throughput omics workflows, and new informatics approaches are necessary for processing the associated data. To automatically extract arrival times for molecules measured by DTIMS at multiple electric fields and compute their associated collisional cross sections (CCS), we created the PNNL Ion Mobility Cross Section Extractor (PIXiE). The primary application presented for this algorithm is the extraction of data that can then be used to create a reference library of experimental CCS values for use in high throughput omics analyses. Results We demonstrate the utility of this approach by automatically extracting arrival times and calculating the associated CCSs for a set of endogenous metabolites and xenobiotics. The PIXiE-generated CCS values were within error of those calculated using commercially available instrument vendor software. Availability and implementation PIXiE is an open-source tool, freely available on Github. The documentation, source code of the software, and a GUI can be found at https://github.com/PNNL-Comp-Mass-Spec/PIXiE and the source code of the backend workflow library used by PIXiE can be found at https://github.com/PNNL-Comp-Mass-Spec/IMS-Informed-Library. Supplementary information Supplementary data are available at Bioinformatics online.

Published

2017

49. Structural Elucidation of cis/trans Dicaffeoylquinic Acid Photoisomerization Using Ion Mobility Spectrometry-Mass Spectrometry

Author

Yehia M. Ibrahim, Dennis G. Thomas, Mwadham M. Kabanda, Mpho M. Makola, Richard D. Smith, Xueyun Zheng, Heino M. Heyman, Niranjan Govind, Ntakadzeni E. Madala, Erin S. Baker, Ryan S. Renslow, Ian K. Webb, Liulin Deng, and Ian A. Dubery

Subjects

Photoisomerization, 010405 organic chemistry, Chemistry, Ion-mobility spectrometry, Stereochemistry, 010401 analytical chemistry, Dicaffeoylquinic acid, Health benefits, Mass spectrometry, 01 natural sciences, Article, 0104 chemical sciences, Ion-mobility spectrometry–mass spectrometry, General Materials Science, Physical and Theoretical Chemistry, Cis–trans isomerism

Abstract

Due to the recently uncovered health benefits and anti-HIV activities of dicaffeoylquinic acids (diCQAs), understanding their structures and functions is of great interest for drug discovery efforts. DiCQAs are analytically challenging to identify and quantify since they commonly exist as a diverse mixture of positional and geometric (cis/trans) isomers. In this work, we utilized ion mobility spectrometry coupled with mass spectrometry to separate the various isomers before and after UV irradiation. The experimental collision cross sections were then compared with theoretical structures to differentiate and identify the diCQA isomers. Our analyses found that naturally the diCQAs existed predominantly as trans/trans isomers, but after 3 h of UV irradiation, cis/cis, cis/trans, trans/cis, and trans/trans isomers were all present in the mixture. This is the first report of successful differentiation of cis/trans diCQA isomers individually, which shows the great promise of IMS coupled with theoretical calculations for determining the structure and activity relationships of different isomers in drug discovery studies.

Published

2017

50. High-resolution microstrip NMR detectors for subnanoliter samples

Author

Eric D. Walter, Ryan S. Renslow, Mark C. Butler, Hardeep S. Mehta, Karl T. Mueller, Ying Chen, Nancy M. Washton, and Patrick N. Reardon

Subjects

Materials science, Fluorinert, Detector, Analytical chemistry, General Physics and Astronomy, 02 engineering and technology, Surface finish, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Microstrip, 0104 chemical sciences, Radio frequency, Physical and Theoretical Chemistry, Spectral resolution, 0210 nano-technology, Spectroscopy, Ground plane

Abstract

We present the numerical optimization and experimental characterization of two microstrip-based nuclear magnetic resonance (NMR) detectors. The first detector, introduced in our previous work, was a flat wire detector with a strip resting on a substrate, and the second detector was created by adding a ground plane on top of the strip conductor, separated by a sample-carrying capillary and a thin layer of insulator. The dimensional parameters of the detectors were optimized using numerical simulations with regards to radio frequency (RF) sensitivity and homogeneity, with particular attention given to the effect of the ground plane. The influence of copper surface finish and substrate surface on the spectral resolution was investigated, and a resolution of 0.8-1.5 Hz was obtained on 1 nL deionized water depending on sample positioning. For 0.13 nmol sucrose (0.2 M in 0.63 nL H2O) encapsulated between two Fluorinert plugs, high RF homogeneity (A810°/A90° = 70-80%) and high sensitivity (expressed in the limit of detection nLODm = 0.73-1.21 nmol s1/2) were achieved, allowing for high-performance 2D NMR spectroscopy of subnanoliter samples.

Published

2017