Sentences with phrase «understand eukaryotic»

The Gordon and Betty Moore Foundation accepted sequencing nominations from Dr. Worden and provided sequencing funds in support of understanding eukaryotic algae.

The EBP would focus on the natural world, providing a better understanding of biodiversity by first sequencing in great detail the DNA of a member of each eukaryotic family (about 9000 in all) and eventually generating coarser genomes for the other eukaryotes.

«It's now understood to be absolutely essential for mitosis in virtually all eukaryotic cells,» Scholey said.

Bethesda, USA (2016 - present) Research areas: Super-resolution microscopy, single - molecule imaging, gene expression, computational modeling and data analysis This section includes all projects during my postdoctoral research stay at the National Institutes of Health in Bethesda, MD (Unites States): (9) Understanding gene expression in eukaryotic cells»

To enable such a system in plants, the re-designed receptors need to be targeted extracellularly and we need to address eukaryotic processes that are not fully understood, such as transmembrane signaling, signal - dependent nuclear translocation, and other signaling complexities.

To gain a better understanding of the evolutionary path by which these archaeal proteins gave rise to the eukaryotic cytoskeleton we have assembled a team of global experts in cytoskeletal biology and evolutionary cell biology.

Spectroscopy & Application of Lasers, Zare / Moerner / +, 6 - 1 Nuclear Hormone Signaling, Chambon / Evans / Jensen, 6 - 1 Bioinorganic Chemistry, Gray / Lippard / Holm / — , 8 - 1 The Field (everything not listed), 10 - 1 Techniques in DNA Synthesis, Caruthers / Hood / +, 10 - 1 Electrochemistry / Electron Transfer, Bard / Hush / Gray / — , 19 - 1 Instrumentation / Techniques in Genomics, Venter / +, 19 - 1 Biological Membrane Vesicles, Rothman / Schekman / +, 19 - 1 Molecular Studies of Gene Recognition, Ptashne, 19 - 1 Organic Electronics, Tang / +, 39 - 1 Polymer Science, Matyjaszewski / Langer / + / — 69 - 1 Solar Cells, Grätzel / +, 74 - 1 Mechanistic Enzymology, Walsh / Stubbe / Koshland / + / — , 74 - 1 Combinatorial Chemistry / DOS, Schreiber / +, 99 - 1 Pigments of Life, Battersby / +, 99 - 1 Development of the Birth Control Pill, Djerassi, 99 - 1 Molecular Modeling and Assorted Applications, Karplus / Houk / Schleyer / Miller / + / — , 99 - 1 Applications of NMR Spectroscopy, Pines / Roberts / McConnell / + / — , 99 - 1 Development of Chemical Biology, Schultz / Schreiber / +, 99 - 1 Self - Assembly, Whitesides / Nuzzo / Stang / — , 149 - 1 Small Regulatory RNA, Ambros / Baulcombe / Ruvkun, 149 - 1 Nanotechnology, Lieber / Whitesides / Alivisatos / Mirkin / Seeman / + / — , 149 - 1 Eukaryotic RNA Polymerases, Roeder, 149 - 1 Contributions to Theoretical Physical Chemistry, Rice / +, 149 - 1 Mechanical Bonds and Applications, Sauvage / Stoddart / +, 149 - 1 Bio - & Organo - catalysis, List / Lerner / Barbas / + / — , 149 - 1 Organic Synthesis, Evans / Danishefsky / Nicolaou / Ley / Trost / Stork / Wender / Kishi / + / — , 199 - 1 Leptin, Coleman / Friedman / Leong, 199 - 1 Fluorocarbons, DuPont / Curran / — , 199 - 1 Understanding of Organic Stereochemistry, Mislow, 199 - 1 Tissue Engineering, Langer / +, 199 - 1 Contributions to Bioorganic Chemistry, Breslow / Eschenmoser / +, 199 - 1 Dendrimers, Frechet / Tomalia / +, 399 - 1 Zeolites, Flanigan, 399 - 1 Molecular Recognition, Dervan / +, 399 - 1 Molecular Machines, Stoddart / Tour / + / — , 399 - 1 Astrochemistry, Oka, 999 - 1

Recognition and utilization of clear and, for the most part mechanistically well understood, criteria will allow the delineation of bona fide miRNAs from the myriad small RNAs generated in eukaryotic cells, allowing for deeper and robust insights into their function, possible mis - regulation, and evolution.

These newly identified organisms might have a big impact on our understanding of the deeper branches of the tree of life giving us new hints about the emergence of the eukaryotic cell.

By doing so, I help increase our understanding of the diversity within the Asgard archaea and their evolutionary relation to the eukaryotic domain.

His basic research is focused on understanding how eukaryotic mRNAs recruit ribosomes, how ribosomes subsequently locate initiation codons, and how ribosomes regulate the translation of specific subsets of mRNAs.

By 1) enhancing a new technology, 2) providing new, useful genomic data from diverse eukaryotic lineages, and 3) by training future researchers that may eventually become scientists and look for their own questions to better understand our world.

Evolutionary questions (WP6) include the addition of uncultured lineages to retrieve a more complete eukaryotic Tree of Life, understanding the evolution of genes and pathways across different lineages, and population genomics in a given lineage or species group.