ADVERTISEMENT

404

Not Found

Is this what you were looking for?

tag regulation evolution cell molecular biology

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.
A close up of a tick held in a pair of forceps, with Kevin Esvelt’s face out of focus in the background.
CRISPR Gene Drives and the Future of Evolution
Hannah Thomasy, PhD | Mar 15, 2024 | 10+ min read
Genetic engineering pioneer Kevin Esvelt’s work highlights biotechnology’s immense potential for good—but also for catastrophe.
Molecular Biology
The Scientist Staff | Aug 22, 1993 | 2 min read
M. Leid, P. Kastner, R. Lyons, et al., "Purification, cloning and RXR identity of the HeLa cell factor with which RAR or TR heterodimerizes to bind target sequences efficiently," Cell, 68:377-95, 1992. Mark Leid (Oregon State University, Corvallis): "The diverse effects of retinoic acid (RA) on development, cellular growth and differentiation, and homeostasis are mediated by two families of RA receptors that arose independently during evolution and belong to the steroid/thyroid hormone super
MOLECULAR BIOLOGY
Paris | Jul 19, 1992 | 1 min read
Michel Philippe (Universite de Rennes, Rennes Cédex, France): "In yeast, two critical points of the cell cycle (Start and G1/S) are regulated by the same protein. This protein, called p34cdc2, is coded by the genes cdc2 in Schizzosaccharomyces pombe and CDC28 in Saccharomyces cerevisiae. By complementation of yeast mutants, proteins from higher eucaryotes homologous to cdc2 have been cloned. Moreover, p34cdc2 has been shown to be one of the main components of the well-known M-phase promotin
A person moving the hands of a vintage clock backwards.
Synthetic Circuits Reveal the Key to Rewinding the Cellular Clock
Charlene Lancaster, PhD | Mar 12, 2024 | 4 min read
Using a circuit-based system, scientists determined the ideal transcription factor levels to promote the successful reprogramming of fibroblasts into induced pluripotent stem cells.
Conceptual image showing molecules making up a brain shape
The Noncoding Regulators of the Brain
Christie Wilcox, PhD | Sep 12, 2022 | 10+ min read
Noncoding RNAs are proving to be critical players in the evolution of brain anatomy and cognitive complexity.
Molecular Biology
The Scientist Staff | Mar 1, 1992 | 2 min read
D.W. Nebert, D.R. Nelson, M.J. Coon, R.W. Estabrook, et al., "The P450 superfamily: update on new sequences, gene mapping, and recommended nomenclature," DNA and Cell Biology, 10:1-14, 1991. Daniel W. Nebert (University of Cincinnati Medical Center): "This review is the third in a series of comprehensive, up- to-date compilations of data about members of the large cytochrome P450 gene superfamily. It serves to organize a large--and growing--body of sequencing and mapping data on 154 P450 genes
A bat flying in a dark cave
Turning on the Bat Signal
Hannah Thomasy, PhD | Mar 15, 2024 | 10+ min read
Scientists around the world investigate how bat immune systems cope with viral attacks and how this information could be used to keep humans safe.
One Protein to Rule Them All
Shelby Bradford, PhD | Feb 28, 2024 | 10+ min read
p53 is possibly the most important protein for maintaining cellular function. Losing it is synonymous with cancer.

Run a Search

ADVERTISEMENT