Acute effects of aldosterone on water and electrolyte transport in the colon and coprodeum of the domestic fowl (Gallus domesticus) in vivo.

White Leghorn laying hens were maintained on commercial poultry food (medium-Na+ diet) and fresh water. High-Na+ diet birds received, in addition, 10 ml 9% (w/v) NaCl/kg by stomach load for 2 days before perfusion experiments. The lumen of the coprodeum and colon of anaesthetized birds was perfused with a hyperosmotic solution resembling ureteral urine. Transmural solute and water fluxes and potential difference (p.d.) values were measured for 2.5 h before and for 8 h after i.v. injection of aldosterone (120 microgram/kg). After administration of aldosterone, the lag, increasing and stabilized plateau phases were identified for Na+, K+ and Cl- fluxes (which together formed an electroneutral ion-exchange system); plateau flux values were significantly greater than preinjection values and were comparable to values for birds maintained on low-Na+ diets in parallel experiments. Ammonium, phosphate and water fluxes were unresponsive to aldosterone and p.d. values showed a transient increase in medium-Na+ diet birds only. In parallel experiments on birds on low sodium diets the ammonium flux and p.d. increased but the osmotic flow and phosphate transfer did not respond. Therefore acute injection of aldosterone reproduced some but not all of the responses to dietary Na+ restriction in fowls.

Simple and rapid visual sensing of saccharides.

Solutions of compound 1 exhibit dramatic, characteristic color changes in response to sugar analytes. Structurally related saccharides including glucose phosphates and amino and carboxylic acid sugars can be readily distinguished by visual inspection. These findings should promote the design of unique color sensory materials based on readily available, functional macrocyclic hosts.

Effector-sensitive cross-linking of phosphorylase b kinase by the novel cross-linker 4-phenyl-1,2,4-triazoline-3,5-dione.

The dienophile 4-phenyl-1,2,4-triazoline-3,5-dione (PTD) was identified as a novel protein cross-linker, and utilized as a conformational probe of phosphorylase b kinase (PhK), a hexadecameric enzyme with the subunit composition (alphabetagammadelta)4. In its reaction with this enzyme, PTD produced five major cross-linked conjugates as resolved by denaturing gel electrophoresis: alphabeta, betagammagamma, alphagamma and a doublet of differently migrating homodimers, betabeta1 and betabeta2. Cross-linking in the presence of six different activators of the kinase targeted to its various subunits caused substantial changes in the amounts of three of the conjugates. The formation of alphagamma was increased by all of the activators but the largest enhancement was caused by exogenous Ca2+/calmodulin. All except one of the activators decreased the amount of betagammagamma formed, with Mg2+ having the greatest effect, and all except two increased the amount of betabeta1, with Mg2+ again having the largest influence. From the overall similarity of the changes in cross-linking by PTD induced by the various activators, we conclude that, even though they are targeted to different sites and subunits, they induce activated conformations of PhK that have certain structural features in common. Regarding the mechanism of cross-linking by PTD, its reaction with a model nucleophile suggests that its initial reaction with a side chain nucleophile of PhK involves a 1,4-conjugate addition to form a urazole adduct, with the secondary cross-linking reaction occurring through an as yet unknown pathway.