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tag membrane cell molecular biology

DNA molecule.
Finding DNA Tags in AAV Stacks
Mariella Bodemeier Loayza Careaga, PhD | Mar 7, 2024 | 8 min read
Ten years ago, scientists put DNA barcodes in AAV vectors, creating an approach that simplified, expedited, and streamlined AAV screening. 
Microfluidics: Biology’s Liquid Revolution
Laura Tran, PhD | Feb 26, 2024 | 8 min read
Microfluidic systems redefined biology by providing platforms that handle small fluid volumes, catalyzing advancements in cellular and molecular studies.
Microscopic image of a live amoeba.
Illuminating Specimens Through Live Cell Imaging
Charlene Lancaster, PhD | Mar 14, 2024 | 8 min read
Live cell imaging is a powerful microscopy technique employed by scientists to monitor molecular processes and cellular behavior in real time.
Green and red fluorescent proteins in a zebrafish outline the animal’s vasculature in red and lymphatic system in green in a fluorescent image. Where the two overlap along the bottom of the animal is yellow.
Serendipity, Happenstance, and Luck: The Making of a Molecular Tool
Shelby Bradford, PhD | Dec 4, 2023 | 10+ min read
The common fluorescent marker GFP traveled a long road to take its popular place in molecular biology today.
Molecular Biology
The Scientist Staff | Feb 16, 1992 | 1 min read
D.E. Williams, J. Eisenman, A. Baird, C. Rauch, et al., "Identification of a ligand for the c-kit proto-oncogene," Cell, 63:167-74, 1990. N.G. Copeland, D.J. Gilbert, B.C. Cho, P.J. Donovan, et al., "Mast cell growth factor maps near the steel locus on mouse chromosome 10 and is deleted in a number of steel alleles," Cell, 63:175-83, 1990. D.M. Anderson, S.D. Lyman, A. Baird, J.M. Wignall, et al., "Molecular cloning of mast cell growth factor, a hematopoietin that is active in both membrane
Molecular Biology
The Scientist Staff | Mar 20, 1994 | 2 min read
Peter H. Seeburg (Center for Molecular Biology, University of Heidelberg): "In our brain, nerve cells communicate by chemical transmission at specialized structures termed synapses. Most excitatory synapses use the neurotransmitter L-glutamate, which activates specific receptor channels in the postsynaptic membrane. Molecularly and functionally different glutamate-activated channels are expressed by the brain, presumably tailored t
Molecular Biology
The Scientist Staff | Mar 20, 1994 | 2 min read
Peter H. Seeburg (Center for Molecular Biology, University of Heidelberg): "In our brain, nerve cells communicate by chemical transmission at specialized structures termed synapses. Most excitatory synapses use the neurotransmitter L-glutamate, which activates specific receptor channels in the postsynaptic membrane. Molecularly and functionally different glutamate-activated channels are expressed by the brain, presumably tailored t
Molecular Biology
The Scientist Staff | Apr 4, 1993 | 2 min read
S. Shimasaki, L. Gao, M. Shimonaka, N.Ling, "Isolation and molecular cloning of insulin-like growth factor-binding protein- 6," Molecular Endocrinology, 5:938, 1991. Shunichi Shimasaki (Whittier Institute for Diabetes and Endocrinology, La Jolla, Calif.): "There are two types of insulin-like growth factors: IGF-I and IGF-II, which act on a wide variety of target cells to regulate growth and cytodifferentiation. The IGF ligands interact with plasma membrane receptors, and the interactions are
Molecular Biology
The Scientist Staff | Jan 6, 1991 | 1 min read
B. Mosley, M.P. Beckmann, C.J. March, R.L. Idzerda, S.D. Gimpel, T. VandenBos, D. Friend, A. Alpert, D. Anderson, J. Jackson, J.M. Wignall, C. Smith, B. Gallis, J.E. Sims, D. Urdal, M.B. Widmer, D. Cosman, L.S. Park, "The murine interleukin-4 receptor: molecular cloning and characterization of secreted and membrane bound forms," Cell, 59, 335-48, 20 October 1989. David Cosman (Immunex Corp., Seattle): "I can think of several reasons why our paper has been cited. There is substantial interest i
The image shows six different panels containing cells. On each panel, the cells are labelled using a different fluorescent dye that highlights features of a specific organelle within the cells.
Cell Painting: Exploring the Richness of Biological Images
Mariella Bodemeier Loayza Careaga, PhD | Sep 8, 2023 | 4 min read
By coloring different organelles simultaneously, cell painting allows scientists to pick up subtle changes in cell function in response to drugs and other perturbations.

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