Mineralisation of urea and urea derivatives in anaerobic soils

Summary The rates of mineralisation of urea and urea derivatives were studied in a laboratory anaerobic incubation experiment. Urea, urea phosphate and sulphur coated urea were hydrolysed rapidly and, even at the highest level of application, had disappeared in just over 8 days. The presence of the phosphate anion depressed pH in the early stages. Hydrolysis of the less soluble organic derivatives of urea, isobutylidine diurea, ureaform and glycoluril was very much slower and in the case of glycoluril a lag period of 8 to 16 days occurred before hydrolysis began.In the initial stages the system was anaerobic but between days 8 and 16 a change to partial aerobic conditions occurred. At this stage nitrification commenced and at day 16 nitrite was detected. Reduction of Fe(III) increased with time, reaching a maximum at day 32. More Fe(II) was produced in the presence of organic derivatives of urea than with the other fertilizers, possibly due to stabilisation by organic ligands. From day 16 nitrification, denitrification and reduction of Fe(III) proceeded together even through E_h values indicated that oxidation of Fe(II) would be expected. This did not occur until after day 32. Once nitrification began denitrification quickly followed so that for all six fertilisers, except at the highest level of application, virtually all the mineralised-N had been lost by denitrification at the end of the experiment.     

Molecular evolution of urea amidolyase and urea carboxylase in fungi

Background  

Urea amidolyase breaks down urea into ammonia and carbon dioxide in a two-step process, while another enzyme, urease, does this in a one step-process. Urea amidolyase has been found only in some fungal species among eukaryotes. It contains two major domains: the amidase and urea carboxylase domains. A shorter form of urea amidolyase is known as urea carboxylase and has no amidase domain. Eukaryotic urea carboxylase has been found only in several fungal species and green algae. In order to elucidate the evolutionary origin of urea amidolyase and urea carboxylase, we studied the distribution of urea amidolyase, urea carboxylase, as well as other proteins including urease, across kingdoms.     

Branchial and renal excretion of urea and urea analogues in the plainfin midshipman,Porichthys notatus

This study investigated whether urea transport mechanisms were present in the gills of the ammoniotelic plainfin midshipman (Porichthys notatus), similar to those recently documented in its ureotelic relative (family Batrachoididae), the gulf toadfish (Opsanus beta). Midshipmen were fitted with internal urinary and caudal artery catheters for repetitive sampling of urine and blood in experiments and radiolabeled urea analogues ([(14)C]-thiourea and [(14)C]-acetamide) were used to evaluate the handling of these substances. Isosmotically balanced infusions of urea were used to raise plasma and urine urea concentrations to levels surpassing physiological levels by 8.5-fold and 6.4-fold, respectively. Despite these high urea levels, there was no observable transport maximum in either renal or branchial urea excretion rate, a result mirrored by the total uptake of fish exposed to a range of environmental urea concentrations. Permeability to urea appeared to be symmetrical in the two directions. At comparable plasma concentrations the branchial clearance rate of acetamide was 74% that of urea while branchial clearance rate of thiourea was 55% that of urea. For influx, the comparable values were 60% and 36%, indicating the same pattern. In contrast, the secretion clearance rate of acetamide by the kidney was 56% that of urea while the rate of thiourea secretion clearance was 137% greater than that of urea, with both urea and thiourea being more concentrated in the urine than in the plasma. In addition, the secretion clearance rates of thiourea and urea were significantly greater than those of water and Cl(-), whereas acetamide, water and Cl(-) were found equally in the plasma and urine, appearing to passively equilibrate between the two fluids. Based on our findings, there appear to be two distinct transport mechanisms involved in urea excretion in the plainfin midshipmen, one in the gill (a facilitated diffusion type transporter) and one in the kidney (an active transport mechanism), each of which does not saturate even at plasma urea concentrations that greatly exceed physiological levels. These transporters appear to be similar to those in the midshipman's ureotelic relative, the gulf toadfish.     

Hyperosmotic NaCl and urea synergistically regulate the expression of the UT-A2 urea transporter in vitro and in vivo

The UT-A2 urea transporter is involved in the recycling of urea through the kidney, a process required to maintain high osmotic gradients. Dehydration increases UT-A2 expression in vivo. The tissue distribution of UT-A2 suggested that hyperosmolarity, and not vasopressin, might mediate this effect. We have analyzed the regulation of UT-A2 expression by ambiant osmolarity both in vitro (mIMCD3 cell line) and in vivo (rat kidney medulla). The UT-A2 mRNA was found to be synergistically up-regulated by a combination of NaCl and urea. Curiously, the UT-A2 protein was undetectable in this hypertonic culture condition, or after transfection of the UT-A2 cDNA, whereas it could be detected in HEK-293 transfected cells. Treating rats with furosemide, a diuretic which decreases the kidney interstitium osmolarity without affecting vasopressin levels, led to decreased levels of the UT-A2 protein. Our results show that the UT-A2 urea transporter is regulated by hyperosmolarity both in vitro and in vivo.     

Effects of the formaldehyde releasing preservatives dimethylol urea and diazolidinyl urea in several short-term genotoxicity tests

The two formaldehyde (FA)-releasers dimethylol urea (DMU) and diazolidinyl urea (DZU) are widely used as preservatives or additives. They were tested for genotoxicity in three short-term test systems, i.e. in the Salmonella typhimurium mutagenicity assay, in the in vitro micronucleus test with V79 Chinese hamster cells and in the in vitro tubulin assembly assay using isolated tubulin from pig brains. The polymerization products obtained in the tubulin assembly assay were examined additionally by electron microscopy.In the S. typhimurium mutagenicity assay with the pre-incubation assay both FA-releasers tested show a clear and concentration-dependent increase in the number of revertants in strains TA98, TA100 and TA102 with and without metabolic activation (rat liver S9 mix). In all cases, a biologically relevant increase in the number of revertants was achieved within the concentration range tested (DZU: 0.04-1.8 micromol per plate, DMU: 0.21-8.33 micromol per plate). FA was tested at 0.06-2.5 micromol per plate and lead to similar effects.Both compounds induce the formation of micronuclei (concentration range tested: DZU: 2.5-50 micromol/l, DMU: 3.3-333 micromol/l). However, DMU shows a comparatively weaker effect exclusively in the absence of the metabolizing enzymes. By contrast, DZU yields a distinct increase of the micronucleus rate in the absence and in the presence of S9. In addition, DZU predominantly causes an increase of large micronuclei, which suggests that this compound has a marked aneugenic potential. Cytotoxic effects accompany the clastogenic effects of both DMU and DZU.The examination of DMU and DZU in view of a possible aneugenic potential in the tubulin assembly assay yielded the following results: DMU at concentrations up to 10 mmol/l did not influence the formation of microtubuli, whereas DZU inhibited this process completely at 3 mmol/l. FA at 6 mmol/l completely inhibited the tubulin assembly. These results could clearly be confirmed by electron microscopy examination. The different potential of the two compounds with respect to the inhibition of tubulin formation is apparently due to a significant difference in the degree of FA release.According to these results, both compounds have to be considered as genotoxic in vitro. On account of these data and because of the widespread use of these two compounds in various products used in daily life, a reevaluation of the risk associated with these compounds seems to be necessary.     

Microbial decomposition of urea in the Menai Straits

The assimilation of urea by the microbial population of the Menai Strait (Anglesey, U.K.) was studied over a seasonal cycle. Samples incubated in the light produced higher assimilation rates than samples incubated in darkness. Higher ratios assimilation of urea: chlorophyll a during a time of a probable nitrogen limiting condition may be indicative of the importance of urea for phytoplankton nutrition. Assimilation rates of urea were higher during the diatom and Phaeocystis bloom than in times of low standing crop.Phytoplankton seem to be the major utilizers of urea in the Menai Strait waters. Bacteria may also be important in the decomposition of urea. However, with the methods employed it was not possible to estimate the extent of their participation in the urea decomposition.