Glutamine-dependent synthesis of citrulline by isolated hepatic mitochondria from Squalus acanthias

Investigating nitrogen movement in North Pacific spiny dogfish (Squalus acanthias suckleyi), with focus on UT, Rhp2, and Rhbg mRNA abundance

For ureosmotic marine elasmobranchs, the acquisition and retention of nitrogen is critical for the synthesis of urea. To better understand whole-body nitrogen homeostasis, we investigated mechanisms of nitrogen trafficking in North Pacific spiny dogfish (Squalus acanthias suckleyi). We hypothesized that the presence of nitrogen within the spiral valve lumen would affect both the transport of nitrogen and the mRNA abundance of a urea transporter (UT) and two ammonia transport proteins (Rhp2, Rhbg) within the intestinal epithelium. The in vitro preincubation of intestinal tissues in NH₄Cl, intended to simulate dietary nitrogen availability, showed that increased ammonia concentrations did not significantly stimulate the net uptake of total urea or total methylamine. We also examined the mRNA abundance of UT, Rhp2, and Rhbg in the gills, kidney, liver, and spiral valve of fasted, fed, excess urea fed, and antibiotic-treated dogfish. After fasting, hepatic UT mRNA abundance was significantly lower, and Rhp2 mRNA in the gills was significantly higher than the other treatments. Feeding significantly increased Rhp2 mRNA levels in the kidney and mid spiral valve region. Both excess urea and antibiotics significantly reduced Rhbg mRNA levels along all three spiral valve regions. The antibiotic treatment also significantly diminished UT mRNA abundance levels in the anterior and mid spiral valve, and Rhbg mRNA levels in the kidney. In our study, no single treatment had significantly greater influence on the overall transcript abundance of the three transport proteins compared to another treatment, demonstrating the dynamic nature of nitrogen balance in these ancient fish.

Ammonia and urea handling by early life stages of fishes

Nitrogen metabolism in fishes has been a focus of comparative physiologists for nearly a century. In this Review, we focus specifically on early life stages of fishes, which have received considerable attention in more recent work. Nitrogen metabolism and excretion in early life differs fundamentally from that of juvenile and adult fishes because of (1) the presence of a chorion capsule in embryos that imposes a limitation on effective ammonia excretion, (2) an amino acid-based metabolism that generates a substantial ammonia load, and (3) the lack of a functional gill, which is the primary site of nitrogen excretion in juvenile and adult fishes. Recent findings have shed considerable light on the mechanisms by which these constraints are overcome in early life. Perhaps most importantly, the discovery of Rhesus (Rh) glycoproteins as ammonia transporters and their expression in ion-transporting cells on the skin of larval fishes has transformed our understanding of ammonia excretion by fishes in general. The emergence of larval zebrafish as a model species, together with genetic knockdown techniques, has similarly advanced our understanding of ammonia and urea metabolism and excretion by larval fishes. It has also now been demonstrated that ammonia excretion is one of the primary functions of the developing gill in rainbow trout larvae, leading to new hypotheses regarding the physiological demands driving gill development in larval fishes. Here, we highlight and discuss the dramatic changes in nitrogen handling that occur over early life development in fishes.

Ornithine carbamoyltransferase unfolding states in the presence of urea and guanidine hydrochloride

Ornithine carbamoyltransferase folding/unfolding is a complex and not completely understood process. Our experimental results suggest that ornithine carbamoyltransferase interacts in a completely different way with urea and guanidine hydrochloride. In fact, we noticed that, increasing concentration from 0.0 to 8.0 M of the two additives, the enzyme follows a simple one-step transition mechanism in the presence of guanidine hydrochloride, with two macroscopic states (the native and the denatured one) significantly populated, whereas in the presence of urea a lot of different protein states can be detected and analyzed. Circular dichroism and UV-visible spectroscopy reveal a similar mechanism of perturbation at high temperature, with opening of hydrophobic core and a significant loss in α-helix structure in the presence of guanidine hydrochloride that cannot be found in the presence of urea.

Waste nitrogen metabolism and excretion in zebrafish embryos: effects of light, ammonia, and nicotinamide

Bony fish primarily excrete ammonia as adults however the persistence of urea cycle genes may reflect a beneficial role for urea production during embryonic stages in protecting the embryo from toxic effects of ammonia produced from a highly nitrogenous yolk. This study aimed to examine the dynamic scope for changes in rates of urea synthesis and excretion in one such species (zebrafish, Danio rerio) by manipulating the intrinsic developmental rate (by alteration of light:dark cycles), as well as by direct chemical manipulation via ammonia injection (to potentially activate urea production) and nicotinamide exposure (to potentially inhibit urea production). Continuous dark exposure delayed development in embryos as evidenced by delayed appearance of hallmark anatomical features (heartbeat, eye pigmentation, body pigmentation, lateral line, fin buds) at 30 and 48 hr post-fertilization, as well by a lower hatching rate compared to embryos reared in continuous light. Both ammonia and urea excretion were similarly effected and were generally higher in embryos continuously exposed to light. Ammonia injection resulted in significant increases (up to fourfold) of urea N excretion and no changes to ammonia excretion rates along with modest increases in yolk ammonia content during 2-6 hr post-injection. Nicotinamide (an inhibitor of urea synthesis in mammals) reduced the ammonia-induced increase in urea excretion and led to retention of ammonia in the yolk and body of the embryo. Our results indicate that there is a relatively rapid and large scope for increases in urea production/excretion rates in developing embryos. Potential mechanisms for these increases are discussed.

Nitrogen metabolism of the intestine during digestion in a teleost fish, the plainfin midshipman (Porichthys notatus)

Digestion affects nitrogen metabolism in fish, as both exogenous and endogenous proteins and amino acids are catabolized, liberating ammonia in the process. Here we present a model of local detoxification of ammonia by the intestinal tissue of the plainfin midshipman (Porichthys notatus) during digestion, resulting in an increase in urea excretion of gastrointestinal origin. Corroborating evidence indicated whole-animal ammonia and urea excretion increased following feeding, and ammonia levels within the lumen of the midshipman intestine increased to high levels (1.8±0.4 μmol N g(-1)). We propose that this ammonia entered the enterocytes and was detoxified to urea via the ornithine-urea cycle (O-UC) enzymes, as evidenced by a 1.5- to 2.9-fold post-prandial increase in glutamine synthetase activity (0.14±0.05 and 0.28±0.02 μmol min(-1) g(-1) versus 0.41±0.03 μmol min(-1) g(-1)) and an 8.7-fold increase in carbamoyl phosphate synthetase III activity (0.3±1.2 versus 2.6±0.4 nmol min(-1) g(-1)). Furthermore, digestion increased urea production by isolated gastrointestinal tissue 1.7-fold, supporting our hypothesis that intestinal tissue synthesizes urea in response to feeding. We further propose that the intestinal urea may have been excreted into the intestinal lumen via an apical urea transporter as visualized using immunohistochemistry. A portion of the urea was then excreted to the environment along with the feces, resulting in the observed increase in urea excretion, while another portion may have been used by intestinal ureolytic bacteria. Overall, we propose that P. notatus produces urea within the enterocytes via a functional O-UC, which is then excreted into the intestinal lumen. Our model of intestinal nitrogen metabolism does not appear to be universal as we were unab le to activate the O-UC in the intestine of fed rainbow trout. However, literature values suggest that multiple fish species could follow this model.

A single glutamine synthetase gene produces tissue-specific subcellular localization by alternative splicing

Glutamine synthetase (GS) plays a key role in two major biochemical pathways: In liver GS catalyzes ammonia detoxification, whereas in neural tissues it also functions in recycling of the neurotransmitter glutamate. In most species the GS gene gives rise to a cytoplasmic protein in both liver and neural tissues. However, in species that utilize the ureosmotic or uricotelic system for ammonia detoxification, the enzyme is cytoplasmic in neural tissues, but mitochondrial in liver cells. Since most vertebrates have a single copy of the GS gene, it is not clear how tissue-specific subcellular localization is achieved. Here we show that in the ureosmotic elasmobranch, Squalus acanthias (spiny dogfish), two different GS transcripts are generated by tissue-specific alternative splicing. The liver transcript contains an alternative exon that is not present in the neural one. This exon leads to acquisition of an upstream in-frame start codon and formation of a mitochondrial targeting signal (MTS). Therefore, the liver product is targeted to the mitochondria while the neural one is retained in the cytoplasm. These findings present a mechanism in which alternative splicing of an MTS-encoding exon is used to generate tissue-specific subcellular localization.

Expression of Four Glutamine Synthetase Genes in the Early Stages of Development of Rainbow Trout (Oncorhynchus mykiss) in Relationship to Nitrogen Excretion

The incorporation of ammonia into glutamine, catalyzed by glutamine synthetase, is thought to be important in the detoxification of ammonia in animals. During early fish development, ammonia is continuously formed as yolk proteins and amino acids are catabolized. We followed the changes in ammonia and urea-nitrogen content, ammonia and urea-nitrogen excretion, glutamine synthetase activity, and mRNA expression of four genes coding for glutamine synthetase (Onmy-GS01-GS04) over 3-80 days post fertilization and in adult liver and skeletal muscle of the rainbow trout (Oncorhynchus mykiss). Both ammonia and urea-nitrogen accumulate before hatching, although the rate of ammonia excretion is considerably higher relative to urea-nitrogen excretion. All four genes were expressed during early development, but only Onmy-GS01 and -GS02 were expressed at appreciable levels in adult liver, and expression was very low in muscle tissue. The high level of expression of Onmy-GS01 and -GS03 prior to hatching corresponded to a linear increase in glutamine synthetase activity. We propose that the induction of glutamine synthetase genes early in development and the subsequent formation of the active protein are preparatory for the increased capacity of the embryo to convert the toxic nitrogen end product, ammonia, into glutamine, which may then be utilized in the ornithine-urea cycle or other pathways.

Hepatic urea biosynthesis in the euryhaline elasmobranchCarcharhinus leucas

Plasma urea levels and hepatic urea production in the euryhaline bull shark, Carcharhinus leucas, acclimated to freshwater and seawater environments were measured. It was found that plasma urea concentration increased with salinity and that this increase was, in part, the result of a significant increase in hepatic production of urea. This study provides direct evidence that hepatic production of urea plays an important role in the osmoregulatory strategy of C. leucas.

Ureotelism is inducible in the neotropical freshwater Hoplias malabaricus (Teleostei, Erythrinidae)

Increased environmental pH decreases ammonia transport through the gills, impairing nitrogenous waste. The consequent toxicity is usually drastic to most fishes. A few species are able to synthesize urea as a way to detoxify plasma ammonia. We studied three teleosts of the family Erythrinidae living in distinct environments, and assumed the biochemical behaviors would be different in spite of their being closely related species. Adult fish collected in the wild were submitted to alkaline water and the urea excretion rate was determined. The specific activity of urea cycle enzymes was determined in liver samples of fish from neutral waters. The studied species Hoplias lacerdae, Hoplerithrynus unitaeniatus, and Hoplias malabaricus are ureogenic. Urea synthesis is not a metabolic way to detoxify ammonia in H. lacerdae and Hoplerithrynus unitaeniatus exposed to an alkaline environment. The plasma ammonia profile of both species showed two distinct biochemical responses. Urea excretion of H. malabaricus was high in alkaline water, and the transition to ureotelism is proposed. The nitrogen excretion rate of H. malabaricus was among the highest values reported and the high urea excretion leads us to include this species as ureotelic in alkaline water.

The osmotic response of the Asian freshwater stingray (Himantura signifer) to increased salinity: a comparison with marine (Taeniura lymma) and Amazonian freshwater (Potamotrygon motoro) stingrays

The white-edge freshwater whip ray Himantura signifer can survive in freshwater (0.7 per thousand ) indefinitely or in brackish water (20 per thousand ) for at least two weeks in the laboratory. In freshwater, the blood plasma was maintained hyperosmotic to that of the external medium. There was approximately 44 mmol l(-1) of urea in the plasma, with the rest of the osmolality made up mainly by Na(+) and Cl(-). In freshwater, it was not completely ureotelic, excreting up to 45% of its nitrogenous waste as urea. Unlike the South American freshwater stingray Potamotrygon motoro, H. signifer has a functional ornithine-urea cycle (OUC) in the liver, with hepatic carbamoylphosphate synthetase III (CPS III) and glutamine synthetase (GS) activities lower than those of the marine blue-spotted fan tail ray Taeniura lymma. More importantly, the stomach of H. signifer also possesses a functional OUC, the capacity (based on CPS III activity) of which was approximately 70% that in the liver. When H. signifer was exposed to a progressive increase in salinity through an 8-day period, there was a continuous decrease in the rate of ammonia excretion. In 20 per thousand water, urea levels in the muscle, brain and plasma increased significantly. In the plasma, osmolality increased to 571 mosmol kg(-1), in which urea contributed 83 mmol l(-1). Approximately 59% of the excess urea accumulated in the tissues of the specimens exposed to 20 per thousand water was equivalent to the deficit in ammonia excretion through the 8-day period, indicating that an increase in the rate of urea synthesis de novo at higher salinities would have occurred. Indeed, there was an induction in the activity of CPS III in both the liver and stomach, and activities of GS, ornithine transcarbamoylase and arginase in the liver. Furthermore, there was a significant decrease in the rate of urea excretion during passage through 5 per thousand, 10 per thousand and 15 per thousand water. Although the local T. lymma in full-strength sea water (30 per thousand ) had a much greater plasma urea concentration (380 mmol l(-1)), its urea excretion rate (4.7 micromol day(-1) g(-1)) was comparable with that of H. signifier in 20 per thousand water. Therefore, H. signifer appears to have reduced its capacity to retain urea in order to survive in the freshwater environment and, consequently, it could not survive well in full-strength seawater.

Glutamine synthetase expression in liver, muscle, stomach and intestine ofBostrichthys sinensisin response to exposure to a high exogenous ammonia concentration

A previous study provided evidence that the adaptive strategy used by the teleost fish Bostrichthys sinensis (sleeper) for detoxifying ammonia during extended periods of air exposure was to synthesize and store glutamine,primarily in the muscle, accompanied by an increase in glutamine synthetase(GSase) activity in liver. The aim of the present study was to assess the effect on GSase expression in various tissues of exposure of B. sinensis to exogenous ammonia. Exogenous ammonia increases internal ammonia concentrations in fish, mimicking environmental situations such as air exposure that preclude loss of ammonia across the gills, and thus triggering alternative mechanisms for ammonia detoxification. The results reveal relatively high levels of GSase activity, not only in liver but also,unexpectedly, in muscle, and even higher levels in intestine and, in particular, stomach. Exposure to ammonia results in significant increases in GSase activity, GSase protein and GSase mRNA levels in all of these tissues except stomach. The amino acid sequences of GSases from liver and stomach deduced from the cDNA sequences are essentially identical and are >97 %identical to the amino acid sequences of GSases from Gulf toadfish(Opsanus beta) and marble goby (Oxyeleotris marmoratus).

Characterization and sequencing of glutamine synthetase cDNA from liver of the ureotelic gulf toadfish (Opsanus beta)

The hepatic enzyme, glutamine synthetase (GSase) is a pivotal protein in the regulation of urea synthesis in fish. The sequence of the DNA encoding for GSase from liver of the ureotelic gulf toadfish (Opsanus beta) was analyzed through a suite of molecular techniques (including cDNA cloning, RACE PCR, and genomic PCR). An open reading frame (ORF) was identified in the cDNA sequence which codes for a protein of 394 amino acids with high identity (86%) to dogfish shark GSase. In the course of generating a suitable probe, a partial sequence was also obtained for horned shark GSase which also had high identity with the dogfish shark gene (93%). Like the dogfish shark GSase, the toadfish gene has two methionine translation initiation sites; the downstream site apparently codes for a cytoplasmic isozyme, while the upstream site adds an N-terminal peptide leader sequence of 23 amino acids to the 'cytoplasmic' protein. This leader sequence has characteristics consistent with a mitochondrial targeting peptide, including a cleavage recognition motif (Arg-X-Phe) and the apparent ability to form an amphiphathic helix. Northern analysis revealed that there is a single predominant transcript of approximately 2 kb in size. These results are consistent with the interpretation that in the gulf toadfish GSase cytoplasmic and mitochondrial isozymes are coded for by a single gene and mRNA transcript which is differentially translated at either initiation site. These results are discussed in the context of prior results for enzyme kinetic characteristics and urea synthesis/excretion physiology.

Nitrogen excretion and expression of carbamoyl-phosphate synthetase III activity and mRNA in extrahepatic tissues of largemouth bass (Micropterus salmoides)

Low levels of all of the enzymes required for urea synthesis via the urea cycle, including mitochondrial glutamine- and acetylglutamate-dependent carbamoyl-phosphate synthetase III (CPSase III) and cytosolic glutamine synthetase, are known to be present in liver of the teleost fish largemouth bass (Micropterus salmoides). The levels of these enzymes are higher than those in most other teleosts, but they are significantly lower than the levels present in liver of ureoosmotic elasmobranchs. The purpose of this study was to assess the physiological role of CPSase III in the context of urea synthesis in adult bass. The results showed that urea-N accounts for about 30% of the total nitrogen (ammonia-N plus urea-N) excreted under control conditions. The rate of urea-N excretion did not increase in response to exposure to 1 mM NH4Cl (3 days) or 0.25 mM NH4Cl (12 days) in the external water, except for a transient increase after a day or two of exposure. CPSase III activity in liver also did not increase in response to exposure to ammonia. Adult largemouth bass, while apparently ureogenic, are primarily ammonotelic and remain so even in the presence of relatively high concentrations of ammonia in the external environment. The total units of CPSase III activity in liver are not sufficient to account for the quantity of urea that is excreted. However, CPSase III and ornithine carbamoyltransferase (OCTase) activities were found to be present in intestinal tissue and, unexpectedly, in muscle tissue. The total units of CPSase III and OCTase in muscle, intestine, and liver appear to be sufficient to account for the observed rate of urea excretion. The sequence of CPSase III cDNA was determined, which permitted the use of ribonuclease protection assays to demonstrate the presence of CPSase III mRNA in these tissues.

N-acetyl-L-glutamate and the urea cycle in gulf toadfish (Opsanus beta) and other fish

Carbamoyl phosphate synthetase I (CPSase I) catalyzes the first reaction of the urea cycle in mammalian ureotelic species. The positive allosteric cofactor N-acetyl-L-glutamate (AGA) is required for CPSase I activity and is important for regulation of the urea cycle. A similar enzyme, CPSase III, catalyzes this reaction in fish; CPSase III differs from CPSase I in that it utilizes glutamine as the nitrogen-donating substrate instead of ammonia. AGA also stimulates the CPSase III-catalyzed reaction, but is not absolutely required for activity if the glutamine concentration is high. There has been no report of the presence or function of AGA in fish. Here we report that AGA is present in those species and tissues of fish that have significant levels of CPSase III and urea cycle activity; the levels of AGA were higher in liver of adult gulf toadfish (Opsanus beta) and spiny dogfish shark (Squalus acanthias), both of which have high CPSase III activity, than in bass (Micropterus salmoides) or trout (Oncorhynchus mykiss), which have much lower or no CPSase III activity, respectively. In the toadfish the levels of AGA in liver and muscle tissue were considerably higher in the fed than in the fasting state, as is observed in mammalian species; in liver, but not in muscle, the level of AGA increased when the toadfish were confined (stressed), which has been shown to induce a ureotelic response. Toadfish muscle had CPSase III and ornithine carbamoyltransferase activities; the increase in AGA concentration in muscle when fed suggests that the presence of these first two enzymes of the urea cycle in muscle may be physiologically significant. The results indicate that the fish investigated have physiologically significant levels of AGA and that the levels correlate with parameters related to urea cycle activity.

Urea production and transport in teleost fishes

Teleosts appear to have retained the genes for the urea cycle enzymes. A few species express the full complement of enzymes and are ureotelic (e.g., Lake Magadi tilapia) or ammoniotelic (e.g., largemouth bass), whereas most species have low or non-detectable enzyme activities in liver tissue and excrete little urea (e.g., adult rainbow trout). It was surprising, therefore, to find the expression of four urea cycle enzymes during early life stages of rainbow trout. The urea cycle may play a role in ammonia detoxification during a critical time of development. Exposure to alkaline water (pH 9.0-9.5) or NH4Cl (0.2 mmol/l) increased urea excretion by several-fold in trout embryos, free embryos and alevin. Urea transport is either by passive simple diffusion or via carried-mediated transport proteins. Molecular studies have revealed that a specialised urea transport protein is present in kidney tissue of elasmobranchs, similar to the facilitated urea transporter found in the mammalian inner medulla of the kidney.

Expression of carbamoyl-phosphate synthetase III mRNA during the early stages of development and in muscle of adult rainbow trout (Oncorhynchus mykiss)

It has been reported that the activities of the urea cycle-related enzymes ornithine carbamoyltransferase and carbamoyl-phosphate synthetase III (CPSase III) are induced during early life stages of ammonotelic rainbow trout (Oncorhynchus mykiss), suggesting that the urea cycle may play a physiological role in early development in teleost fish (Wright, P. A., Felskie, A., and Anderson, P. M. (1995) J. Exp. Biol. 198, 127-135). CPSase III cDNA prepared from embryo mRNA was sequenced, confirming the existence of the CPSase III gene in trout and its expression. The deduced amino acid sequence of the CPSase III is homologous to other CPSases. Supporting evidence for the expression of CPSase III activity in trout embryos was obtained by demonstrating expression of CPSase III mRNA as early as day 3 post-fertilization, reaching a maximum at 10-14 days, declining to a minimum at day 70, and then increasing to a relatively constant level from days 90 to 110 (relative to total RNA). Unexpectedly, in tissues of adult and fingerling trout, CPSase III mRNA was found to be present in muscle but not in other tissues, including liver. This finding was confirmed by assay of extracts, which showed CPSase III and ornithine carbamoyltransferase activity in muscle but not in other tissues. The pyrimidine nucleotide pathway-related CPSase II mRNA was expressed in all tissues.

The promoter region of the carbamoyl-phosphate synthetase III gene of Squalus acanthias

Carbamoyl-phosphate synthetase III (CPSase III) of Squalus acanthias (spiny dogfish) is a nuclear-encoded mitochondrial enzyme that catalyzes glutamine-dependent formation of carbamoyl phosphate for urea synthesis. In this paper we report the results of cloning a 10-kb segment of genomic DNA which includes the region flanking the 5' end of the spiny dogfish CPSase III gene. A total of 1,295 base pairs of sequence straddling the start codon was obtained. Primer extension experiments revealed that the transcription start site is the G located 114 residues upstream of the translation start codon ATG. The first exon has 240 base pairs, including the 5' untranslated region, the coding sequence for the signal peptide (38 amino acids), and the four N-terminal amino acids of the mature enzyme. The boundary of the first exon and the first intron of the CPSase III gene is concordant with that of rat and frog (Rana catesbeiana) CPSase I, which have been suggested to have evolved from CPSase III. The putative TATA box sequence, TACAAA, is located at position -31 with an uncommonly found C at the third position. Two C/EBP binding site sequences, ATTCTGCAAG (-405 to -397) and GTGCAGTAAG (-168 to -160), were identified in the promoter region, which suggests that spiny dogfish CPSase III might be subjected to transactivation of transcription by C/EBP-related proteins, as has been reported for rat CPSase I. The preparation and binding of a recombinant RcC/EBP-1 protein (the R. catesbeiana homolog of the mammalian C/EBP alpha) to the two spiny dogfish C/EBP binding sequences are described. Two putative heat-shock binding elements were also identified in the promoter region.

Distribution of glutamine synthetase in the snapper (Pagrus auratus) and implications for the immune system

A sensitive radiotracer method was used to detect glutamine synthetase activity in fish. The distribution of glutamine synthetase activity using this method was shown to be widespread in organs and tissues of the marine finfish, snapper,Pagrus auratus. The optimum pH and temperature for glutamine synthetase activity and Km of glutamate from the brain of the snapper are also reported. Interestingly no glutamine synthetase activity was detected in lymphoid organs, indicating, that as in the mammal, the teleostean immune system is likely to rely on glutamine in circulation for energy and nucleotide synthesis. Furthermore circulating glutamine levels fell as fish became stressed or became ill. Implications of these observations on the function of the immune system of fish are discussed.

Genetic, molecular and developmental analysis of the glutamine synthetase isozymes of Drosophila melanogaster

The glutamine synthetase isozymes of Drosophila melanogaster offer an attractive model for the study of the molecular genetics and evolution of a small gene family encoding enzymatic isoforms that evolved to assume a variety of specific and sometimes essential biological functions. In Drosophila melanogaster two GS isozymes have been described which exhibit different cellular localisation and are coded by a two-member gene family. The mitochondrial GS structural gene resides at the 21B region of the second chromosome, the structural gene for the cytosolic isoform at the 10B region of the X chromosome. cDNA clones corresponding to the two genes have been isolated and sequenced. Evolutionary analysis data are in accord with the hypothesis that the two Drosophila glutamine synthetase genes are derived from a duplication event that occurred near the time of divergence between Insecta and Vertebrata. Both isoforms catalyse all reactions catalysed by other glutamine synthetases, but the different kinetic parameters and the different cellular compartmentalisation suggest strong functional specialisation. In fact, mutations of the mitochondrial GS gene produce embryo-lethal female sterility, defining a function of the gene product essential for the early stages of embryonic development. Preliminary results show strikingly distinct spatial and temporal patterns of expression of the two isoforms at later stages of development.

Mutations in the glutamine synthetase I (gsI) gene produce embryo-lethal female sterility in Drosophila melanogaster

A female-sterile mutation (fs(2) PM11-19) was recovered in a screen for P-M hybrid dysgenesis induced mutations uncovered by a deletion of region 21B and was identified as an allele of the gene encoding the Drosophila glutamine synthetase I (GSI) mitochondrial isozyme. Molecular analysis has shown that fs(2)PM11-19 contains a 5 kb insert within 500 bp upstream of the transcriptional start site of the gsI gene. Mutant flies have extremely low levels of gsI transcription and GSI activity. A pre-existing deficiency (Df(2L) netPM1) with a breakpoint near the transcription start site was also found to be a female-sterile allele of gsI. All eggs laid by PM11-19 homozygous females, as well as by females heterozygous for this mutation and a deletion or any of several recessive lethal alleles of the gsI gene, fail to hatch. We conclude that an adequate level of maternally supplied GSI activity is necessary in the early stages of Drosophila embryonic development.

Purification and properties of mitochondrial phosphoenolpyruvate carboxykinase from liver of Squalus acanthias

Liver from Squalus acanthias (spiny dogfish), a representative elasmobranch, contains approximately 1.4 units (mumol/min) of phosphoenolpyruvate carboxykinase activity per gram and approximately 90% of the total units of activity are localized in the mitochondria. The mitochondrial phosphoenolpyruvate carboxykinase was isolated and characterized. The purified enzyme has properties generally similar to those found in mammalian and avian species. The enzyme has a molecular weight of approximately 70,000 and exists in a functional state as a monomer. The isolated enzyme displays a dual cation requirement (e.g., 6 mM Mg2+ and 10 microM Mn2+) for maximal activity; very little activity is observed when Mg2+ is present alone, and the maximal activity attained with Mn2+ alone (millimolar concentrations required) is significantly less than that observed under optimal conditions with both cations present. When assayed in the direction of oxalacetate formation there is a lag in product formation with time; the lag can be eliminated by the presence of 50 microM GTP (product). The Km for substrates is not affected by Mn2+ concentration, suggesting that the role of Mn2+ may not be related to substrate binding. The apparent Km for phosphoenolpyruvate (approximately 1 mM) is substantially higher than that reported for phosphoenolpyruvate carboxykinase from other species. The activity of phosphoenolpyruvate carboxykinase is increased 70% by physiological concentrations of urea. Maximal velocity of the reaction in the direction of oxalacetate formation is approximately half that of the reverse reaction.

Homologous nuclear genes encode cytoplasmic and mitochondrial glutamine synthetase in Drosophila melanogaster

We describe the cloning of the glutamine synthetase 1 (GS1) gene based on cross-homology with the glutamine synthetase 2 (GS2) gene in Drosophila melanogaster. We have determined the GS gene number in the Drosophila genome, and we describe the isolation of cDNA clones corresponding to the two isoforms, their entire sequence and their transcription pattern. We looked for subcellular localization of one enzymic isoform; in this way, we were able to locate the GS1 enzyme within the mitochondria of D. melanogaster. We have compared different GS sequences from plants and humans; emerging evolutionary implications are discussed. In addition, we have identified a certain highly stable secondary structure at the nucleotide level in the coding region of isoforms located in the organella.

Purification and properties of ornithine carbamoyl transferase from liver of Squalus acanthias

Citrulline synthesis from ammonia by hepatic mitochondria in elasmobranchs involves intermediate formation of glutamine as the result of the presence of high levels of glutamine synthetase and a unique glutamine- and N-acetyl-glutamate-dependent carbamoyl phosphate synthetase, both of which have properties unique to the function of glutamine-dependent synthesis of urea, which is retained in the tissues of elasmobranchs at high concentrations for the purpose of osmoregulation [P.M. Anderson and C.A. Casey (1984) J. Biol. Chem. 259, 456-462; R.A. Shankar and P.M. Anderson (1985) Arch. Biochem. Biophys. 239, 248-259]. The objective of this study was to determine if ornithine carbamoyl transferase, which catalyzes the last step of mitochondrial citrulline synthesis and which has not been previously isolated from any species of fish, also has properties uniquely related to this function. Ornithine carbamoyl transferase was highly purified from isolated liver mitochondria of Squalus acanthias, a representative elasmobranch. The purified enzyme is a trimer with a subunit molecular weight of 38,000 and a native molecular weight of about 114,000. The effect of pH is significantly influenced by ornithine concentration; optimal activity is at pH 7.8 when ornithine is saturating. The apparent Km values for ornithine and carbamoyl phosphate at pH 7.8 are 0.71 and 0.05 mM, respectively. Ornithine displays considerable substrate inhibition above pH 7.8. The activity is not significantly affected by physiological concentrations of the osmolyte urea or trimethylamine-N-oxide or by a number of other metabolites. The results of kinetic studies are consistent with a steady-state ordered addition of substrates (carbamoyl phosphate binding first) and rapid equilibrium random release of products. Except for an unusually low specific activity, the properties of the purified elasmobranch enzyme are similar to the properties of ornithine carbamoyl transferase from mammalian ureotelic and other species and do not appear to be unique to its role in glutamine-dependent synthesis of urea for the purpose of osmoregulation.

Effects of urea, trimethylamine oxide, and osmolality on respiration and citrulline synthesis by isolated hepatic mitochondria from Squalus acanthias

The effects of osmolality and of urea and trimethylamine oxide on citrulline synthesis and respiration by isolated hepatic mitochondria from Squalus acanthias (spiny dogfish) were determined. Optimal rates of citrulline synthesis and of respiration, as well as maximal respiratory control ratios, were obtained when the osmolality was about 300 mOsm when physiological concentrations of urea and trimethylamine oxide were present, analogous to mammalian mitochondria. Urea and trimethylamine oxide do not act as osmolytes and do not significantly affect these rates. When glutamate is not saturating, increasing concentrations of urea over the range of concentrations of physiological significance (e.g. 0.1-0.5 M) significantly inhibit citrulline synthesis, but not respiration. This response to urea concentration may reflect a specific homeostatic mechanism for maintaining physiological concentrations of urea.

Support of respiration and citrulline synthesis by isolated hepatic mitochondria from Squalus acanthias by acyl-CoAs and other nitrogen-donating substrates

The effects of different substrates supporting respiration and glutamine-dependent citrulline synthesis from ornithine, ammonia, and bicarbonate by isolated hepatic mitochondria from Squalus acanthias (spiny dogfish) were determined. Highest rates of respiration were achieved with succinate, palmitoyl-CoA, and beta-hydroxybutyrate as oxidizable substrates. All acyl-CoAs tested (from C-2 to C-22) supported carnitine-dependent respiration at a substantial rate. Short-chain fatty acids did not support respiration. Ammonia required for citrulline synthesis could be formed from glutamate, or from leucine plus alpha-ketoglutarate which gives rise to glutamate by transamination, as the result of glutamate dehydrogenase activity, but the reaction was inhibited by succinate or other oxidizable substrates. Alanine or ornithine could not be substituted for leucine, suggesting that leucine may specifically activate glutamate dehydrogenase. Glutamate required for citrulline synthesis could be formed from alpha-ketoglutarate and ammonia as the result of glutamate dehydrogenase activity if succinate was present. Transamination of alpha-ketoglutarate with ornithine present in the reaction mixtures provided glutamate at a rapid rate whether or not succinate was present. These results are consistent with the view that hepatic dogfish mitochondria efficiently utilize acyl-CoAs derived from triglyceride stores in the liver to support respiration, glutamine-dependent citrulline synthesis from ammonia, and formation of ketone bodies as a major fuel for muscle.

Purification and properties of glutamine synthetase from liver of Squalus acanthias

Ammonia assimilation for urea synthesis by liver mitochondria in marine elasmobranchs involves, initially, formation of glutamine which is subsequently utilized for mitochondrial carbamoyl phosphate synthesis [P. M. Anderson and C. A. Casey (1984) J. Biol. Chem. 259, 456-462]. The purpose of this study was to determine if the glutamine synthetase catalyzing this first step in urea synthesis has properties uniquely related to this function. Glutamine synthetase has been highly purified from isolated liver mitochondria of Squalus acanthias, a representative elasmobranch. The purified enzyme has a molecular weight of approximately 400,000 in the presence of Mg2+, MgATP, and L-glutamate, but dissociates reversibly to a species with a molecular weight of approximately 200,000 in the absence of MgATP and L-glutamate. Association with the glutamine- and acetylglutamate-dependent carbamoyl phosphate synthetase, also located in the mitochondria, could not be demonstrated. The subunit molecular weight is approximately 46,000. The pH optimum of the biosynthesis reaction is 7.1-7.4. The purified enzyme is stabilized by MgATP and glutamate and by ethylene glycol, and is activated by 5-10% ethylene glycol. The apparent Km values for MgATP, L-glutamate, and ammonia (NH4+-NH3) are 0.7, 11.0, and 0.015 mM, respectively. Mg2+ in excess of that required to complex ATP as MgATP is required for maximal activity; Mn2+ cannot replace Mg2+. The enzyme is activated by low concentrations of chloride, bromide, or iodide; this effect appears to be related to decreases in the apparent Km for glutamate. The enzyme is inhibited by physiological concentrations of urea, but is not significantly affected by physiological concentrations of trimethylamine-N-oxide. Except for activation by halogen anions and the very low apparent Km for ammonia, this elasmobranch glutamine synthetase has properties similar to those reported for mammalian and avian glutamine synthetases. The very low apparent Km for ammonia may be specifically related to the unique role of this glutamine synthetase in mitochondrial assimilation of ammonia for urea synthesis.

Submitochondrial localization of arginase and other enzymes associated with urea synthesis and nitrogen metabolism, in liver of Squalus acanthias

The submitochondrial localization of the four mitochondrial enzymes associated with urea synthesis in liver of Squalus acanthias (spiny dogfish), a representative elasmobranch, was determined. Glutamine- and acetylglutamate-dependent carbamoyl-phosphate synthetase, ornithine carbamoyltransferase, glutamine synthetase, and arginase were all localized within the matrix of liver mitochondria. The subcellular and submitochondrial localization and activities of several related enzymes involved in nitrogen metabolism and gluconeogenesis in liver and dogfish are also reported. Pyruvate carboxylase and phosphoenolpyruvate carboxykinase were localized in the mitochondrial matrix. Synthesis of citrulline by isolated mitochondria from ornithine proceeds at a near optimal rate at ornithine concentrations as low as 0.08 mM. The same stoichiometry and rates of citrulline synthesis are observed when ornithine is replaced by arginine. The mitochondrial location of arginase does not appear to reflect a mechanism for regulating ornithine availability.