Reversible covalent immobilization of ligands and proteins on polyacrylamide gels

Ligands and proteins were covalently but reversibly immobilized on polyacrylamide gels using novel acrylic monomers whose syntheses are reported here. These reagents have an acrylyl group at one end for copolymerization into gels, an N-succinimidyl ester at the other allowing rapid immobilization of molecules having an available primary amino group, and a cleavable disulfide bond in the middle. Two immobilization methods were developed using these reagents. In the first method, a ligand with a primary amino group was treated with the immobilization reagent in anhydrous ethanol and the resulting amide derivative was purified and copolymerized with acrylamide and bisacrylamide resulting in the desired reversible immobilization. In the second method, the immobilization reagents (at densities up to 50 mumol/ml) were directly copolymerized with acrylamide and bisacrylamide to form activated gels of the desired shape and porosity. Proteins or other ligands in aqueous buffers were then added to the activated gels resulting in their covalent immobilization. Ligands or proteins immobilized using the methods reported here remained stably bound even when gels were subjected to boiling in detergents or high-ionic-strength buffers. Immobilized ligands were readily released (greater than 97%) from gels by treatment with quantitative amounts of aqueous dithiothreitol (DTT) under mild conditions. Immobilized proteins were also released (up to 87%) from the gels by DTT treatment. Small ligands (e.g., aminohexyl glycosides), active enzymes, and glycoproteins were immobilized, and then recovered, using these reagents.     

Genome-wide CRISPR Screens Reveal Host Factors Critical for SARS-CoV-2 Infection

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Environmentally constrained mutation and adaptive evolution in Salmonella

The relationship between environment and mutation is complex [1]. Claims of Lamarkian mutation [2] have proved unfounded [3], [4] and [5]; it is apparent, however, that the external environment can influence the generation of heritable variation, through either direct effects on DNA sequence [6] or DNA maintenance and copying mechanisms [7], [8], [9] and [10], or as a consequence of evolutionary processes [11], [12], [13], [14], [15] and [16]. The spectrum of mutational events subject to environmental influence is unknown [6] and precisely how environmental signals modulate mutation is unclear. Evidence from bacteria suggests that a transient recombination-dependent hypermutational state can be induced by starvation [5]. It is also apparent that chnages in the mutability of specific loci can be influenced by alterations in DNA topology [10] and [17]. Here we describe a remarkable instance of adaptive evolution in Salmonella which is caused by a mutation that occurs in intermediate-strength osmotic environments. We show that the mutation is not ‘directed’ and describe its genetic basis. We also present compelling evidence in support of the hypothesis that the mutational event is constrained by signals transmitted from the external environment via changes in the activity of DNA gyrase.     

Galectin 9 is the sugar-regulated urate transporter/channel UAT

UAT, also designated galectin 9, is a multifunctional protein that can function as a urate channel/transporter, a regulator of thymocyte-epithelial cell interactions, a tumor antigen, an eosinophil chemotactic factor, and a mediator of apoptosis. We review the evidence that UAT is a transmembrane protein that transports urate, describe our molecular model for this protein, and discuss the evidence from epitope tag and lipid bilayer studies that support this model of the transporter. The properties of recombinant UAT are compared with those of urate transport into membrane vesicles derived from proximal tubule cells in rat kidney cortex. In addition, we review channel functions predicted by our molecular model that resulted in the novel finding that the urate channel activity is regulated by sugars and adenosine. Finally, the presence and possible functions of at least 4 isoforms of UAT and a closely related gene hUAT2 are discussed. Published in 2004.