Our laboratory focuses on
understanding gene regulation in the cardiovascular system, skeletal muscle, and other metabolic tissues, with the ultimate goal of finding novel therapeutic strategies to prevent and treat cardio - metabolic and - myopathic diseases.
«Quantum machine shows promise for biological research: In first quantum machine learning study with biological data, researchers leverage D - Wave to
understand gene regulation.»
The research that led to these findings is part of a larger effort to better
understand gene regulation and expression, carried out by the GTEx Consortium, a National Institutes of Health - funded group that includes researchers from around 80 institutions founded in 2010.
To
understand gene regulation, Panne works on a cell - free model of the human interferon beta response to viral infection.
The single - cell perspective has helped to better
understand gene regulation and regulatory networks during exit from pluripotency, cell - fate determination as well as molecular mechanisms driving cellular reprogramming of somatic cells to induced pluripotent stage.
Not exact matches
This finding by Whitehead Institute scientists challenges current
understandings of
gene regulation via DNA methylation, from development through adulthood.
This research tool can be used to better
understand the function of histone proteins, which play critical roles in the
regulation of
gene expression in animals and plants.
The quantum machine was also able to generate conclusions that were consistent with a biologist's current
understanding of
gene regulation.
However, to make use of that information required an
understanding of
gene expression and
regulation, areas in which institute members made a conscious decision to invest and that became its strengths.
Thus, the discovery of DNA methylation in early diverging fungi helps the research community better
understand regulation of
genes that encode the parts for bio-based economy and bioenergy applications.»
Plants perform these
regulations mainly by regulating nuclear
gene expression and multiple intracellular signaling pathways have been shown to play a role in the genomic response of plants to stress, but the processes are not well
understood.
At the nucleic acid level,
understanding the precise
regulation of
genes through analysis of
gene expression data will be of utmost importance.
While the study represents a strong start for
understanding how eQTLs affect
gene regulation and expression, Engelhardt pointed out that she and her colleagues still do not have enough samples to
understand trans - eQTLs as deeply as they would like.
Building on years of mouse and
gene regulation studies, they have developed a resource that can help scientists better
understand how similarities and differences between mice and humans are written in their genomes.
She leads a multidisciplinary team integrating computational and experimental approaches to develop an
understanding of
gene regulation in immune cells.
The publication of the latest Canine genome build and annotation, CanFam3.1 provides an opportunity to enhance our
understanding of
gene regulation across tissues in the dog model system.
«Using this approach, we will eventually be able to do the same thing you would do in English class — pick up a book of haiku or Shakespeare and
understand that «this is a love poem,» or «this is an elegy,» because we'll
understand how the words — the DNA elements — are used in different contexts to convey different meanings on the
regulation of
genes,» Arnosti said.
Targeted
gene therapies, however, had to wait for (1) the identification of the
genes to target, (2) the cloning and / or sequencing of the relevant
genes and in some cases, the specific disease - causing variant, (3) a full
understanding of the normal
gene function and
regulation, and (4) the development of efficient ways to deliver
genes to the relevant tissues at therapeutic levels.
Many miRNA
genes, therefore, lack annotated features such as a promoter or splice sites, hindering progress in
understanding their transcriptional and post-transcriptional
regulation.
Along this line, our primary research goals are directed towards
understanding how noncoding RNAs and their RNA - binding proteins are integrated in to the
regulation of
gene expression and modulation of the host immune response during ¿ - herpesviral infection.
These results are a huge step towards
understanding the basic molecular mechanism behind
gene regulation.»
He has made fundamental contributions to our
understanding of vertebrate developmental biology and microRNA - based
gene regulation using the model organism zebrafish.
«The knowledge gained will help us
understand many human disorders caused by malfunctions of
gene regulation, a major goal of the NIH and of our new Institute for Genomics and Systems Biology in Chicago» White said.
To
understand and analyze the
regulation of
gene expression patterns, quantitative RNA sequencing is used.
Along this line, our primary research goals are directed towards
understanding how noncoding RNAs and their RNA - binding proteins are integrated in to the
regulation of
gene expression and modulation of the host immune response during gammaherpesvirus infection.
Professor Segal's research has two major directions 1)
Gene regulation — using quantitative and computational models to
understand how DNA sequence variation among human individuals generates phenotypic diversity 2) Microbiome and Nutrition —
understanding how the microbial composition of individuals affect their physiology and health.
Now that scientists
understand how these
genes control the heart, they can begin to piece together how heart disease disrupts this
regulation.
RNA - based
gene regulation is revealing itself as key to
understanding cellular function, organismal development and homeostasis.
Several functions vary among the members of this group of bacteria, such as metabolism of nitrogen, respiration, cell wall and capsule, stress response, secondary metabolite biosynthesis,
regulation and cell signaling; this variation in
gene functions could help us
understand the ability of colonization and adaptability of these rhizosphere - colonizing bacteria.
Throughout his postdoctoral years, at Memorial Sloane - Kettering Cancer Center, and into his tenure at the University of Michigan, Dr. Al - Hashimi remained steadfast in his determination to solve the problem of how to visualize atomic motion, «to obtain a deeper
understanding of
gene regulation and to build new technologies for drug discovery and biotechnology.»
A physicist turned computational scientist, Graber comes to the MDI Biological Laboratory from The Jackson Laboratory, also located in Bar Harbor, where he focused on computational approaches to
understanding post-transcriptional
gene regulation and interactions, while also working intensively to process, analyze and interpret the genome - scale data sets generated within the Patient Derived Xenograft (PDX) cancer study program.
We study learning and memory at the genetic level to
understand the structure,
regulation, evolution and biological function of
genes that are required for normal learning and memory.
Research Focus: I dedicate my time and effort to develop high - throughput sequencing technologies such as single cell transcriptomic, ChIP - Seq, ChIA - PET, and many more... The scientific rational is to
understand better and with a different angle, the mechanisms of epigenetic
regulation of
gene expression in (rare) immune cells, pathologically relevant in many diseases such as asthma, SLE, tuberculosis...
We have a longstanding interest in
understanding gene expression
regulation, and in our wetlab at the Sanger Institute use mouse T helper cells as a model of cell differentiation.
Methylation of mammalian DNA and histone residues are known to regulate transcription, and the discovery of demethylases that remove methylation in DNA and histones provide a basis for the
understanding of dynamic
regulation of mammalian
gene expression.
- The work, published in Nature Genetics, represents an important advance in our
understanding of
gene regulation and reveals a new layer of complexity that needs to be studied to properly interpret genomics and
gene expression in the future.
Major areas of activity in our lab include 1) identification and characterization of Sgenes, 2) genomic analyses to identify the diversity of TAL effectors in pathogen populations and
understand their evolution, and 3) structural and biochemical studies to better harness the unique properties of these proteins for applications such as targeted
gene regulation and genome editing.
The current findings could provide important clues to determine the culture conditions for promoting the differentiation of primate ES cells into mature gametes, and to
understand molecular mechanisms of primate gametogenesis including the timing of germ cell induction, the
regulation of germ cell
gene expression, and the response to growth factors for germ cell differentiation.
Her scientific expertise lies in
understanding the epigenetic basis of
gene regulation during embryonic development and disease ontology.
His group work on
understanding the
regulation of
gene expression, especially at the single - cell level where he has pioneered analytical approaches.
To uncover molecular processes in individual cells and to
understand the full complexity of biological systems, our lab applies and develops novel microscopy and genomics based techniques to study the
regulation of
gene - expression in single cells.
A basic
understanding on the set of
genes and
gene networks responsible from directly regulating lifespan and the mechanisms used in this
regulation is also missing.
The focus of the Mar lab is to
understand how variability in
gene expression contributes to the
regulation of cellular phenotypes.
High fibre diets also contain various fatty acids such as the short chain fatty acids (SCFA) and the
understanding of synergistic effects of SCFA and phytosterols in glucose
regulation and cholesterol homeostasisis important to our
understanding of diet, lifestyle and drugs in relation to peripheral amyloidosis and
gene expression
High fibre diets also contain various fatty acids such as the short chain fatty acids (SCFA) and the
understanding of synergistic effects of SCFA and phytosterols in glucose
regulation and cholesterol homeostasisis important to our
understanding of diet, lifestyle and drugs in relation to peripheral amyloidosis and
gene expression that play an early role in the development of AD.
We want to
understand this observation through the investigation of
gene regulation in the context of the epigenetic landscape.
Respiratory sinus arrhythmia in the fourth decade of life depends on birth weight and the DRD4
gene: Implications for
understanding the development of emotion
regulation.