Your search keyword '"Laura E. Bartley"' showing total 57 results

51. The Study of Single Biomolecules with Fluorescence Methods

Author

X. Zhuang, Hazen P. Babcock, S. Chu, Laura E. Bartley, J. W. Orr, D. Herschlag, Hee Kyung Kim, Taekjip Ha, J. R. Williamson, and Rick Russell

Subjects

chemistry.chemical_classification, Physics, Förster resonance energy transfer, chemistry, Chemical physics, Biomolecule, Molecule, Polymer physics, Protein folding, Polymer, Kinetic energy, Fluorescence

Abstract

The study of individual molecules allows one to look beyond the ensemble average and observe the distribution and time trajectory of the structure and motion of molecules. This approach has led to new paradigms in polymer physics. The study of polymer dynamics at the single-molecule level has led to the discovery that identical DNA molecules exposed to the same conditions will follow a multitude of paths to equilibrium as they extend in elongational [1] and shear [2] flows. This “molecular individualism” was not discovered in half a century of experimental work on bulk samples. Nor was it anticipated theoretically. It is possible that biological processes such as protein folding and enzyme activity will also show a rich set of kinetic paths and transient states that can only be fully characterized at the single-molecule level. Thus, it is important to develop techniques that will allow the study of molecular processes at the level of single molecules.

Published

2001

52. Use of duplex rigidity for stability and specificity in RNA tertiary structure

Author

Geeta J. Narlikar, Daniel Herschlag, and Laura E. Bartley

Subjects

Binding Sites, biology, Nucleic acid tertiary structure, Base pair, Oligonucleotide, Stereochemistry, Ribozyme, Nucleic Acid Heteroduplexes, Oligonucleotides, Active site, Biochemistry, Substrate Specificity, Kinetics, Docking (molecular), Duplex (building), Tetrahymena, biology.protein, Animals, Nucleic Acid Conformation, RNA, Catalytic, Binding site

Abstract

The Tetrahymena group I ribozyme's oligonucleotide substrate, CCCUCUA(5), forms six base pairs with the ribozyme's internal guide sequence (IGS, 5'GGAGGG) to give the P1 duplex, and this duplex then docks into the active site via tertiary interactions. Shortening the substrate by three residues to give UCUA(5) reduces the equilibrium constant for P1 docking by approximately 200-fold even though UCUA(5) retains all the functional groups known to be involved in tertiary interactions [Narlikar, G. J., Bartley, L. E., Khosla, M., and Herschlag, D. (1999) Biochemistry 38, 14192-14204]. Here we show that the P1 duplex formed with UCUA(5) engages in all of the major tertiary interactions made by the standard P1 duplex. This suggests that the destabilization is not due to disruption of specific tertiary interactions. It therefore appears that the weaker docking of UCUA(5) arises from the increased conformational freedom of the undocked P1 duplex, which has three unpaired IGS residues and thus a larger entropic cost for docking. Further, a 2'-methoxy substitution at an IGS residue that is base-paired in the standard P1 duplex with CCCUCUA(5) but unpaired in the P1 duplex with UCUA(5) destabilizes docking of the standard P1 duplex approximately 300-fold more than it destabilizes docking of the P1 duplex formed with UCUA(5). These results suggest that fixation of groups in the context of a rigid duplex may be a general strategy used by RNA to substantially increase interaction specificity, both by aiding binding of the desired functional groups and by increasing the energetic cost of forming alternative interactions.

Published

2000

53. Observing folding and catalysis of a single RNA enzyme molecule

Author

Steven Chu, Xiaowei Zhuang, Daniel Herschlag, Rick Russell, Hazen P. Babcock, Taekjip Ha, and Laura E. Bartley

Subjects

Riboswitch, Folding (chemistry), chemistry.chemical_classification, Enzyme, Chemistry, Fluorescence microscope, Biophysics, Molecule, RNA, Fluorescence, Macromolecule

Abstract

Summary form only given.RNA enzyme molecules form complex and specific structures that are able to perform a variety of structure-related functions. Yet the mechanism by which an RNA molecule folds into a unique structure is largely unknown. In this paper, we demonstrate that single molecules fluorescence microscopy is a power tool to study RNA folding.

54. Comparative genomic analysis of the R2R3 MYB secondary cell wall regulators of Arabidopsis, poplar, rice, maize, and switchgrass

Author

Laura E. Bartley and Kangmei Zhao

Subjects

0106 biological sciences, Homolog, Protein family, Amino Acid Motifs, Arabidopsis, Plant Science, Biology, Panicum, Zea mays, 01 natural sciences, 7. Clean energy, Secondary cell wall, 03 medical and health sciences, Species Specificity, Biofuel, Cell Wall, Gene Expression Regulation, Plant, R2R3 MYB, Botany, Arabidopsis thaliana, Gene Regulatory Networks, MYB, Gene, Phylogeny, Plant Proteins, 030304 developmental biology, 2. Zero hunger, Comparative genomics, Genetics, Likelihood Functions, Ortholog, 0303 health sciences, Sequence Homology, Amino Acid, fungi, food and beverages, Oryza, 15. Life on land, biology.organism_classification, Populus, Subfunctionalization, Transcription factor, Genome, Plant, Research Article, 010606 plant biology & botany

Abstract

Background R2R3 MYB proteins constitute one of the largest plant transcription factor clades and regulate diverse plant-specific processes. Several R2R3 MYB proteins act as regulators of secondary cell wall (SCW) biosynthesis in Arabidopsis thaliana (At), a dicotyledenous plant. Relatively few studies have examined SCW R2R3 MYB function in grasses, which may have diverged from dicots in terms of SCW regulatory mechanisms, as they have in cell wall composition and patterning. Understanding cell wall regulation is especially important for improving lignocellulosic bioenergy crops, such as switchgrass. Results Here, we describe the results of applying phylogenic, OrthoMCL, and sequence identity analyses to classify the R2R3 MYB family proteins from the annotated proteomes of Arabidposis, poplar, rice, maize and the initial genome (v0.0) and translated transcriptome of switchgrass (Panicum virgatum). We find that the R2R3 MYB proteins of the five species fall into 48 subgroups, including three dicot-specific, six grass-specific, and two panicoid grass-expanded subgroups. We observe four classes of phylogenetic relationships within the subgroups of known SCW-regulating MYB proteins between Arabidopsis and rice, ranging from likely one-to-one orthology (for AtMYB26, AtMYB103, AtMYB69) to no homologs identifiable (for AtMYB75). Microarray data for putative switchgrass SCW MYBs indicate that many maintain similar expression patterns with the Arabidopsis SCW regulators. However, some of the switchgrass-expanded candidate SCW MYBs exhibit differences in gene expression patterns among paralogs, consistent with subfunctionalization. Furthermore, some switchgrass representatives of grass-expanded clades have gene expression patterns consistent with regulating SCW development. Conclusions Our analysis suggests that no single comparative genomics tool is able to provide a complete picture of the R2R3 MYB protein family without leaving ambiguities, and establishing likely false-negative and -positive relationships, but that used together a relatively clear view emerges. Generally, we find that most R2R3 MYBs that regulate SCW in Arabidopsis are likely conserved in the grasses. This comparative analysis of the R2R3 MYB family will facilitate transfer of understanding of regulatory mechanisms among species and enable control of SCW biosynthesis in switchgrass toward improving its biomass quality.

55. A genome-wide survey of switchgrass genome structure and organization.

Author

Manoj K Sharma, Rita Sharma, Peijian Cao, Jerry Jenkins, Laura E Bartley, Morgan Qualls, Jane Grimwood, Jeremy Schmutz, Daniel Rokhsar, and Pamela C Ronald

Subjects

Medicine, Science

Abstract

The perennial grass, switchgrass (Panicum virgatum L.), is a promising bioenergy crop and the target of whole genome sequencing. We constructed two bacterial artificial chromosome (BAC) libraries from the AP13 clone of switchgrass to gain insight into the genome structure and organization, initiate functional and comparative genomic studies, and assist with genome assembly. Together representing 16 haploid genome equivalents of switchgrass, each library comprises 101,376 clones with average insert sizes of 144 (HindIII-generated) and 110 kb (BstYI-generated). A total of 330,297 high quality BAC-end sequences (BES) were generated, accounting for 263.2 Mbp (16.4%) of the switchgrass genome. Analysis of the BES identified 279,099 known repetitive elements, >50,000 SSRs, and 2,528 novel repeat elements, named switchgrass repetitive elements (SREs). Comparative mapping of 47 full-length BAC sequences and 330K BES revealed high levels of synteny with the grass genomes sorghum, rice, maize, and Brachypodium. Our data indicate that the sorghum genome has retained larger microsyntenous regions with switchgrass besides high gene order conservation with rice. The resources generated in this effort will be useful for a broad range of applications.

Published

2012

56. Towards establishment of a rice stress response interactome.

Author

Young-Su Seo, Mawsheng Chern, Laura E Bartley, Muho Han, Ki-Hong Jung, Insuk Lee, Harkamal Walia, Todd Richter, Xia Xu, Peijian Cao, Wei Bai, Rajeshwari Ramanan, Fawn Amonpant, Loganathan Arul, Patrick E Canlas, Randy Ruan, Chang-Jin Park, Xuewei Chen, Sohyun Hwang, Jong-Seong Jeon, and Pamela C Ronald

Subjects

Genetics, QH426-470

Abstract

Rice (Oryza sativa) is a staple food for more than half the world and a model for studies of monocotyledonous species, which include cereal crops and candidate bioenergy grasses. A major limitation of crop production is imposed by a suite of abiotic and biotic stresses resulting in 30%-60% yield losses globally each year. To elucidate stress response signaling networks, we constructed an interactome of 100 proteins by yeast two-hybrid (Y2H) assays around key regulators of the rice biotic and abiotic stress responses. We validated the interactome using protein-protein interaction (PPI) assays, co-expression of transcripts, and phenotypic analyses. Using this interactome-guided prediction and phenotype validation, we identified ten novel regulators of stress tolerance, including two from protein classes not previously known to function in stress responses. Several lines of evidence support cross-talk between biotic and abiotic stress responses. The combination of focused interactome and systems analyses described here represents significant progress toward elucidating the molecular basis of traits of agronomic importance.

Published

2011

57. Refinement of light-responsive transcript lists using rice oligonucleotide arrays: evaluation of gene-redundancy.

Author

Ki-Hong Jung, Christopher Dardick, Laura E Bartley, Peijian Cao, Jirapa Phetsom, Patrick Canlas, Young-Su Seo, Michael Shultz, Shu Ouyang, Qiaoping Yuan, Bryan C Frank, Eugene Ly, Li Zheng, Yi Jia, An-Ping Hsia, Kyungsook An, Hui-Hsien Chou, David Rocke, Geun Cheol Lee, Patrick S Schnable, Gynheung An, C Robin Buell, and Pamela C Ronald

Subjects

Medicine, Science

Abstract

Studies of gene function are often hampered by gene-redundancy, especially in organisms with large genomes such as rice (Oryza sativa). We present an approach for using transcriptomics data to focus functional studies and address redundancy. To this end, we have constructed and validated an inexpensive and publicly available rice oligonucleotide near-whole genome array, called the rice NSF45K array. We generated expression profiles for light- vs. dark-grown rice leaf tissue and validated the biological significance of the data by analyzing sources of variation and confirming expression trends with reverse transcription polymerase chain reaction. We examined trends in the data by evaluating enrichment of gene ontology terms at multiple false discovery rate thresholds. To compare data generated with the NSF45K array with published results, we developed publicly available, web-based tools (www.ricearray.org). The Oligo and EST Anatomy Viewer enables visualization of EST-based expression profiling data for all genes on the array. The Rice Multi-platform Microarray Search Tool facilitates comparison of gene expression profiles across multiple rice microarray platforms. Finally, we incorporated gene expression and biochemical pathway data to reduce the number of candidate gene products putatively participating in the eight steps of the photorespiration pathway from 52 to 10, based on expression levels of putatively functionally redundant genes. We confirmed the efficacy of this method to cope with redundancy by correctly predicting participation in photorespiration of a gene with five paralogs. Applying these methods will accelerate rice functional genomics.

Published

2008