Urea

About: Urea is a research topic. Over the lifetime, 21394 publications have been published within this topic receiving 382444 citations. The topic is also known as: carbamide & carbonic acid diamide.

Vasopressin activates collecting duct urea transporters and water channels by distinct physical processes

Abstract: The present studies were performed to investigate the kinetics of regulation of water channels and urea carriers in the rat terminal (IMCD) in response to vasopressin (AVP). The time courses of osmotic water permeability (Pf) and urea permeability (P(urea)) were measured in isolated perfused rat terminal IMCD segments following AVP stimulation and subsequently following AVP washout. Under control conditions, Pf and P(urea) kinetics were similar. Both transport processes exhibited complex patterns of activation with a period of rapid permeability increase followed by a period of slower increase. Both transporters also exhibited complex patterns of reversal following AVP washout, with a rapid permeability decrease (5 min) followed by a slower decrease toward the baseline value. The measurements were repeated in the presence of a lumen > bath osmotic gradient, a condition associated with a decreased rate of apical endocytosis in collecting ducts. The lumen > bath gradient did not alter the kinetics of Pf increase after AVP addition, but completely blocked the decrease in Pf normally seen with washout of AVP. In contrast, the lumen > bath osmotic gradient did not affect the decrease in urea permeability after AVP washout, but blocked the rapid phase of urea permeability increase following AVP addition. Thus imposition of a lumen > bath osmotic gradient resulted in separation of the time courses of P(urea) and Pf changes associated with AVP addition and washout. This finding indicates that the physical processes responsible for AVP-mediated alteration of urea transporter and water channel activity in the apical membrane are distinct.

Facile Coating of Urea With Low-Dose ZnO Nanoparticles Promotes Wheat Performance and Enhances Zn Uptake Under Drought Stress.

Abstract: Zinc oxide nanoparticles (ZnO-NPs) hold promise as novel fertilizer nutrients for crops. However, their ultra-small size could hinder large-scale field application due to potential for drift, untimely dissolution or aggregation. In this study, urea was coated with ZnO-NPs (1%) or bulk ZnO (2%) and evaluated in wheat (Triticum aestivum L.) in a greenhouse, under drought (40% field moisture capacity; FMC) and non-drought (80% FMC) conditions, in comparison with urea not coated with ZnO (control), and urea with separate ZnO-NP (1%) or bulk ZnO (2%) amendment. Plants were exposed to ≤ 2.17 mg/kg ZnO-NPs and ≤ 4.34 mg/kg bulk-ZnO, indicating exposure to a higher rate of Zn from the bulk ZnO. ZnO-NPs and bulk-ZnO showed similar urea coating efficiencies of 74-75%. Drought significantly (p ≤ 0.05) increased time to panicle initiation, reduced grain yield, and inhibited uptake of Zn, nitrogen (N), and phosphorus (P). Under drought, ZnO-NPs significantly reduced average time to panicle initiation by 5 days, irrespective of coating, and relative to the control. In contrast, bulk ZnO did not affect time to panicle initiation. Compared to the control, grain yield increased significantly, 51 or 39%, with ZnO-NP-coated or uncoated urea. Yield increases from bulk-ZnO-coated or uncoated urea were insignificant, compared to both the control and the ZnO-NP treatments. Plant uptake of Zn increased by 24 or 8% with coated or uncoated ZnO-NPs; and by 78 or 10% with coated or uncoated bulk-ZnO. Under non-drought conditions, Zn treatment did not significantly reduce panicle initiation time, except with uncoated bulk-ZnO. Relative to the control, ZnO-NPs (irrespective of coating) significantly increased grain yield; and coated ZnO-NPs enhanced Zn uptake significantly. Zn fertilization did not significantly affect N and P uptake, regardless of particle size or coating. Collectively, these findings demonstrate that coating urea with ZnO-NPs enhances plant performance and Zn accumulation, thus potentiating field-scale deployment of nano-scale micronutrients. Notably, lower Zn inputs from ZnO-NPs enhanced crop productivity, comparable to higher inputs from bulk-ZnO. This highlights a key benefit of nanofertilizers: a reduction of nutrient inputs into agriculture without yield penalities.

Urea transport in the central nervous system.

Abstract: The kinetics of urea transport in the central nervous system have been studied in rabbits during sustained intravenous and intracisternal infusions of C12 and C14 urea. The steady state content of ...