The researchers used Prototype Foamy Virus integrase as a model and two
molecular microscopy techniques to record viral integration complexes traveling along stretches of target DNA in search of insertion points.
Not exact matches
Forthcoming workshops cover
techniques as varied as «
molecular and genetic tools for the analysis of medaka and zebrafish development» and «cryo - electron
microscopy and 3 - D image reconstruction.»
By using a combination of advanced genetics,
molecular approaches, and
microscopy techniques, they found that this signaling pathway is used in the adult brain in a completely novel way.
Jacques Dubochet of the University of Lausanne in Switzerland, Joachim Frank of Columbia University and Richard Henderson of the MRC Laboratory of
Molecular Biology in Cambridge, England, won for their contributions to the development of the
technique, called cryo - electron
microscopy, the Royal Swedish Academy of Sciences announced October 4.
In her 4 years at Furman University in Greenville, South Carolina, Laura Glish, a 2006 graduate, worked on collaborative projects in two different laboratories and explored a variety of experimental
techniques, from atomic force
microscopy to synthetic chemistry and
molecular modeling.
The breakthrough came with a new imaging
technique, dual - resonance - frequency - enhanced electrostatic force
microscopy (DREEM), which was developed by University of North Carolina at Chapel Hill chemist and co-author Dorothy Erie, former UNC and NC State postdoctoral researchers Dong Wu and Parminder Kaur, and was featured earlier this year in
Molecular Cell.
The researchers used
molecular and
microscopy techniques to observe interactions between the bacteria.
Researchers aim to answer these questions using cutting - edge electron
microscopy techniques in combination with
molecular and biochemical approaches.
The researchers were able to achieve a controllable self - assembly of peptoids on a flat surface by manipulating
molecular - level interactions through advanced chemistry and
microscopy techniques.
His group focuses on novel
techniques and instrumentation for high - resolution structural and
molecular microscopy based on integrated fluorescence and electron
microscopy.
The journal also focuses on the technological aspects of pathology, including
molecular biology
techniques, morphometry aspects (stereology, DNA analysis, syntactic structure analysis), communication aspects (telecommunication, virtual
microscopy, virtual pathology institutions, etc.), and electronic education and quality assurance (for example interactive publication, on - line references with automated updating, etc.).
Recent progress in phylogenomics, and the implementation of modern
molecular,
microscopy, and cell biology
techniques in a handful of spiralian model systems have made that possible.
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.
The projects are multidisciplinary, involving a variety of
techniques including
molecular biology (PCR, cloning), cell culture and advanced fluorescence
microscopy.
Berkeley Lab researchers, working at the
Molecular Foundry, have invented a
technique called «CLAIRE» that extends the incredible resolution of electron
microscopy to the non-invasive nanoscale imaging of soft matter, including biomolecules, liquids, polymers, gels and foams.