Your search keyword '"Rachel W. Martin"' showing total 7 results

1. Spatially resolved detection of small molecules from press‐dried plant tissue using MALDI imaging

Author

Zane G. Long, Jonathan V. Le, Benjamin B. Katz, Belen G. Lopez, Emily D. Tenenbaum, Bonnie Semmling, Ryan J. Schmidt, Felix Grün, Carter T. Butts, and Rachel W. Martin

Subjects

chemically specific imaging, in situ chemical analysis, intact plant tissue imaging, MALDI‐MSI, mass spectrometry, metabolites, Biology (General), QH301-705.5, Botany, QK1-989

Abstract

Abstract Premise Matrix‐assisted laser desorption/ionization mass spectrometry imaging (MALDI‐MSI) is a chemical imaging method that can visualize spatial distributions of particular molecules. Plant tissue imaging has so far mostly used cryosectioning, which can be impractical for the preparation of large‐area imaging samples, such as full flower petals. Imaging unsectioned plant tissue presents its own difficulties in extracting metabolites to the surface due to the waxy cuticle. Methods We address this by using established delipidation techniques combined with a solvent vapor extraction prior to applying the matrix with many low‐concentration sprays. Results Using this procedure, we imaged tissue from three different plant species (two flowers and one carnivorous plant leaf). Material factorization analysis of the resulting data reveals a wide range of plant‐specific small molecules with varying degrees of localization to specific portions of the tissue samples, while facilitating detection and removal of signal from background sources. Conclusions This work demonstrates applicability of MALDI‐MSI to press‐dried plant samples without freezing or cryosectioning, setting the stage for spatially resolved molecule identification. Increased mass resolution and inclusion of tandem mass spectrometry are necessary next steps to allow more specific and reliable compound identification.

Published

2023

2. Chemical Properties Determine Solubility and Stability in βγ‐Crystallins of the Eye Lens

Author

Kyle W. Roskamp, Rachel W. Martin, Ashley O. Kwok, Megan A. Megan A. Rocha, and Marc A. Sprague-Piercy

Subjects

Models, Molecular, Circular dichroism, Context (language use), Protein aggregation, 010402 general chemistry, 01 natural sciences, Biochemistry, Article, Crystallin, Lens, Crystalline, medicine, Humans, Solubility, Deamidation, Molecular Biology, 010405 organic chemistry, Chemistry, fungi, Organic Chemistry, food and beverages, Crystallins, eye diseases, 0104 chemical sciences, medicine.anatomical_structure, Förster resonance energy transfer, Lens (anatomy), Biophysics, Molecular Medicine, sense organs

Abstract

βγ-Crystallins are the primary structural and refractive proteins found in the vertebrate eye lens. Because crystallins are not replaced after early eye development, their solubility and stability must be maintained for a lifetime, which is even more remarkable given the high protein concentration in the lens. Aggregation of crystallins caused by mutations or post-translational modifications can reduce crystallin protein stability and alter intermolecular interactions. Common post-translational modifications that can cause age-related cataracts include deamidation, oxidation, and tryptophan derivatization. Metal ion binding can also trigger reduced crystallin solubility through a variety of mechanisms. Interprotein interactions are critical to maintaining lens transparency: crystallins can undergo domain swapping, disulfide bonding, and liquid-liquid phase separation, all of which can cause opacity depending on the context. Important experimental techniques for assessing crystallin conformation in the absence of a high-resolution structure include dye-binding assays, circular dichroism, fluorescence, light scattering, and transition metal FRET.

Published

2021

3. Crystallin Proteins from Aquatic Organisms: Stability and Function in the Lens and Beyond

Author

Megha H. Unhelkar, Megan A. Megan A. Rocha, Marc A. Sprague-Piercy, Rachel W. Martin, Jessica I. Kelz, Chelsea Anorma, and Brenna Norton-Baker

Subjects

medicine.anatomical_structure, Crystallin, Chemistry, Lens (anatomy), Genetics, medicine, Biophysics, Molecular Biology, Biochemistry, Function (biology), Biotechnology, Aquatic organisms

Published

2021

4. Novel proteases from the genome of the carnivorous plantDrosera capensis: Structural prediction and comparative analysis

Author

Jan C. Bierma, Carter T. Butts, and Rachel W. Martin

Subjects

0301 basic medicine, Protein Folding, Drosera, Sequence alignment, Biochemistry, Genome, Article, Protein Structure, Secondary, Substrate Specificity, Contig Mapping, 03 medical and health sciences, Protein Domains, Structural Biology, Catalytic Domain, Botany, Venus flytrap, Amino Acid Sequence, Homology modeling, Droseraceae, Molecular Biology, Phylogeny, Plant Proteins, Carnivorous plant, biology, High-Throughput Nucleotide Sequencing, Molecular Sequence Annotation, biology.organism_classification, Carnivory, Molecular Docking Simulation, Drosera capensis, 030104 developmental biology, Structural Homology, Protein, Evolutionary biology, Sequence Alignment, Genome, Plant, Peptide Hydrolases

Abstract

In his 1875 monograph on insectivorous plants, Darwin described the feeding reactions of Drosera flypaper traps and predicted that their secretions contained a “ferment” similar to mammalian pepsin, an aspartic protease. Here we report a high-quality draft genome sequence for the cape sundew, Drosera capensis}, the first genome of a carnivorous plant from order Caryophyllales, which also includes the Venus flytrap (Dionaea) and the tropical pitcher plants (Nepenthes). This species was selected in part for its hardiness and ease of cultivation, making it an excellent model organism for further investigations of plant carnivory. Analysis of predicted protein sequences yields genes encoding proteases homologous to those found in other plants, some of which display sequence and structural features that suggest novel functionalities. Because the sequence similarity to proteins of known structure is in most cases too low for traditional homology modeling, 3D structures of representative proteases are predicted using comparative modeling with all-atom refinement. Although the overall folds and active residues for these proteins are conserved, we find structural and sequence differences consistent with a diversity of substrate recognition patterns. Finally, we predict differences in substrate specificities using in silico experiments, providing targets for structure/function studies of novel enzymes with biological and technological significance. This article is protected by copyright. All rights reserved.

Published

2016

5. ChemInform Abstract: Spatial Reorientation Experiments for NMR of Solids and Partially Oriented Liquids

Author

Kelsey A. Collier, John E. Kelly, and Rachel W. Martin

Subjects

symbols.namesake, Magic angle, Liquid crystal, Chemistry, Instrumentation, symbols, Magic angle spinning, General Medicine, Hamiltonian (quantum mechanics), Magnetostatics, Anisotropy, Spinning, Computational physics

Abstract

Motional reorientation experiments are extensions of Magic Angle Spinning (MAS) where the rotor axis is changed in order to average out, reintroduce, or scale anisotropic interactions (e.g. dipolar couplings, quadrupolar interactions or chemical shift anisotropies). This review focuses on Variable Angle Spinning (VAS), Switched Angle Spinning (SAS), and Dynamic Angle Spinning (DAS), all of which involve spinning at two or more different angles sequentially, either in successive experiments or during a multidimensional experiment. In all of these experiments, anisotropic terms in the Hamiltonian are scaled by changing the orientation of the spinning sample relative to the static magnetic field. These experiments vary in experimental complexity and instrumentation requirements. In VAS, many one-dimensional spectra are collected as a function of spinning angle. In SAS, dipolar couplings and/or chemical shift anisotropies are reintroduced by switching the sample between two different angles, often 0° or 90° and the magic angle, yielding a two-dimensional isotropic-anisotropic correlation spectrum. Dynamic Angle Spinning (DAS) is a related experiment that is used to simultaneously average out the first- and second-order quadrupolar interactions, which cannot be accomplished by spinning at any unique rotor angle in physical space. Although motional reorientation experiments generally require specialized instrumentation and data analysis schemes, some are accessible with only minor modification of standard MAS probes. In this review, the mechanics of each type of experiment are described, with representative examples. Current and historical probe and coil designs are discussed from the standpoint of how each one accomplishes the particular objectives of the experiment(s) it was designed to perform. Finally, applications to inorganic materials and liquid crystals, which present very different experimental challenges, are discussed. The review concludes with perspectives on how motional reorientation experiments can be applied to current problems in chemistry, molecular biology, and materials science, given the many advances in high-field NMR magnets, fast spinning, and sample preparation realized in recent years.

Published

2016

6. High-resolution nuclear magnetic resonance spectroscopy of biological tissues using projected magic angle spinning

Author

Rachel W. Martin, Rebecca C. Jachmann, Dimitris Sakellariou, Ulla Gro Nielsen, and Alexander Pines

Subjects

Magnetic Resonance Spectroscopy, Magic angle, Rotation, business.industry, Chemistry, Isotropy, Magnetic resonance force microscopy, Signal Processing, Computer-Assisted, Magnetostatics, Optics, Nuclear magnetic resonance, Liver, Solid-state nuclear magnetic resonance, Spin echo, Magic angle spinning, Animals, Anisotropy, Cattle, Radiology, Nuclear Medicine and imaging, Muscle, Skeletal, business, Spinning

Abstract

High-resolution NMR spectra of materials subject to anisotropic broadening are usually obtained by rotating the sample about the magic angle, which is 54.7 degrees to the static magnetic field. In projected magic angle spinning (p-MAS), the sample is spun about two angles, neither of which is the magic angle. This provides a method of obtaining isotropic spectra while spinning at shallow angles. The p-MAS experiment may be used in situations where spinning the sample at the magic angle is not possible due to geometric or other constraints, allowing the choice of spinning angle to be determined by factors such as the shape of the sample, rather than by the spin physics. The application of this technique to bovine tissue samples is demonstrated as a proof of principle for future biological or medical applications.

Published

2005

7. Cover Image, Volume 84, Issue 10

Author

Carter T. Butts, Jan C. Bierma, and Rachel W. Martin

Subjects

Structural Biology, Molecular Biology, Biochemistry

Published

2016