Evaluation of DNA damage in Dicentrarchus labrax sperm following cryopreservation.

In this paper, DNA laddering analysis and single-cell gel electrophoresis (SCGE) or Comet assay, were used to detect DNA damage in response to a cryopreservation process in sea bass spermatozoa. The results obtained demonstrate that the cryopreservation protocol used to cryopreserve the sea bass sperm cause significantly damage at DNA level. In fact, the degree of DNA damage in frozen-thawed sperm (%DNAT=38.2+/-11.2, MT=498.9+/-166.4, n=3) was different (P<0.01) from that measured in fresh sperm (%DNAT=32.7+/-11.1, MT=375.2+/-190.7, n=3). Data here reported also demonstrated the fundamental role played by cryoprotectants (BSA and Me2SO) in reducing fish sperm DNA fragmentation. Finally, from our results, the ability of SCGE to reveal DNA fragmentation in fish sperm is also confirmed.

Calcium channels are present in the apical plasma membranes of the hepatopancreatic B-cells of Marsupenaeus japonicus.

This study demonstrates the existence of calcium channels in the apical membranes of the hepatopancreatic blister (B) cells of Marsupenaeus japonicus. Using brush-border membrane vesicles we demonstrated that the channel-mediated calcium passive flux was saturable and was stimulated by a transmembrane electrical potential difference and inhibited by barium. We raised a monoclonal antibody (Mab 24A4) against the calcium channel, which allowed us to inhibit the channel-mediated calcium uptake. By immunocytochemistry, using Mab 24A4, we demonstrated that these channels are located at the apical membrane of hepatopancreatic B cells. Finally, by measuring the calcium uptake in R- and B-enriched cell suspensions, we showed that only the plasma membrane of the B cells expresses a channel-mediated calcium uptake inhibited by barium, verapamil and the monoclonal antibody 24A4. The plasma membrane of R cells did not show calcium channels.

Differential expression of Na+/D-glucose cotransport in isolated cells of Marsupenaeus japonicus hepatopancreas.

D-Glucose absorptive processes at the gastrointestinal tract of decapod crustaceans are largely under-investigated. We have studied Na(+)-dependent D-glucose transport (Na(+)/D-glucose cotransport) in the hepatopancreas of the Kuruma prawn, Marsupenaeus japonicus, using both brush-border membrane vesicles and purified R and B hepatopancreatic cell suspensions. As assessed by brush-border membrane vesicle studies, Na(+)/D-glucose cotransport was inhibited by phloridzin and responsive to the (inside negative) membrane potential. Furthermore, it was strongly activated by protons (although only in the presence of an inside-negative membrane potential), which correlates with the fact that the lumen of crustacean hepatopancreatic tubules is acidic. When assayed in purified R and B cell suspensions, Na(+)/D-glucose cotransport activity was restricted to B cells only. Mab 13, a monoclonal antibody recognizing an 80- to 85-KDa protein at the brush-border membrane location, inhibited Na(+)/D-glucose cotransport in brush-border membrane vesicles as well as in enriched B cell suspensions. Primers designed after comparison of highly homologous regions of various mammalian sodium-glucose transporter) nucleotide sequences failed to produce RT-PCR amplification products from Kuruma prawn hepatopancreatic RNA. The molecular nature of this Na(+)/D-glucose cotransport system is still to be established.

Changes in cell type composition and enzymatic activities in the hepatopancreas of Marsupenaeus japonicus during the moulting cycle.

The goal of the present study was to evaluate the changes in the cell type composition and ATPase activities (total ATPase, ouabain-sensitive Na+/K(+)-ATPase, furosemide-sensitive Na(+)-ATPase) that occur during the different stages of the moulting cycle in the hepatopancreas of the Marsupenaeus japonicus. The results clearly suggest that the number of resorptive and fibrillar cell types changes significantly during the different stages. An inverse correlation between resorptive and fibrillar cells is observed during moulting (both in normally fed and fasted animals). Fasting, but not the moulting cycle, affects the number of blister-like cells. In the resorptive cells the enzymatic activities (total ATPases and ouabain-sensitive Na+/K(+)-ATPase) also change during the moulting in a cyclical manner. All these results are in agreement with and confirm the different functions carried out by the two cell types within the hepatopancreas.

D-glucose transport in decapod crustacean hepatopancreas.

Physiological mechanisms of gastrointestinal absorption of organic solutes among crustaceans remain severely underinvestigated, in spite of the considerable relevance of characterizing the routes of nutrient absorption for both nutritional purposes and formulation of balanced diets in aquaculture. Several lines of evidence attribute a primary absorptive role to the digestive gland (hepatopancreas) and a secondary role to the midgut (intestine). Among absorbed organic solutes, the importance of D-glucose in crustacean metabolism is paramount. Its plasma levels are finely tuned by hormones (crustacean hyperglycemic hormone, insulin-like peptides and insulin-like growth factors) and the function of certain organs (i.e. brain and muscle) largely depends on a balanced D-glucose supply. In the last few decades, D-glucose absorptive processes of the gastrointestinal tract of crustaceans have been described and transport mechanisms investigated, but not fully disclosed. We briefly review our present knowledge of D-glucose transport processes in the crustacean hepatopancreas. A discussion of previous results from experiments with hepatopancreatic epithelial brush-border membrane vesicles is presented. In addition, recent advances in our understandings of hepatopancreatic D-glucose transport are shown, as obtained (1) after isolation of purified R-, F-, B- and E-cell suspensions from the whole organ by centrifugal elutriation, and (2) by protein expression in hepatopancreatic mRNA-injected Xenopus laevis oocytes. In a perspective, the applicability of these novel methods to the study of hepatopancreatic absorptive function will certainly improve our knowledge of this structurally complex organ.

An L-proline-dependent proton flux is located at the apical membrane level of the eel enterocytes.

This study has demonstrated the existence of an L-proline-dependent (Na independent) proton flux at the apical membrane level of the eel intestinal absorbing cells. Using isolated eel enterocytes and the pH-sensitive fluorescent dye 2', 7'-bis-(2-carboxyethyl)-5-(and-6)-carboxyfluorescein, acetoxymethyl ester (BCECF), it was shown that a 20 mM concentration of the imino acid L-proline in the extracellular medium determined an intracellular acidification of approximately 0.28 pH units. However, neither sucrose nor other amino acids were able to significantly acidify the resting intracellular pH. A hyperbolic relationship between extracellular proline concentration and intracellular proton accumulation was observed. Using both isolated brush-border and basolateral membrane vesicles, it was demonstrated that this proline-proton cotransport mechanism was located at the apical membrane level only. In addition, the existence of a coupling mechanism between proline and proton fluxes was demonstrated by the observation that, in brush-border membrane vesicles, the presence of a pH gradient (pH(in) > pH(out)) stimulated the uptake of L-proline.

Effects of zinc on l-

Epithelial brush-border membrane vesicles (BBMVs) from the hepatopancreas of the lobster Homarus americanus were prepared using a magnesium precipitation technique and employed in transport experiments designed to demonstrate the effects of external and internal divalent cationic heavy metals on the uptake of l-[(3)H]proline. When BBMVs were exposed to a high external concentration (2.5 mmol l(-)(1)) of Cd(2+), Cu(2+), Fe(2+), Mn(2+) or Zn(2+), l-[(3)H]proline (0.5 mmol l(-)(1)) uptake was significantly (P<0.05) decreased by each metal. However, if a 30 min pre-incubation period with each metal was used before incubation of the vesicles with amino acid and metal, a significant (P<0.05) enhancement of l-[(3)H]proline transport occurred. Zinc was the most stimulatory metal of those tested. Proline influxes (1.0 and 2.5 mmol l(-)(1)) were hyperbolic functions of bilateral [Zn(2+)], with a lower apparent zinc half-saturation constant (K(m)) at the higher amino acid concentration. l-[(3)H]proline influx was a hyperbolic function of external [l-proline] (K(m)=2.10+/-0.26 mmol l(-)(1); J(max)=2290+/-600 pmol mg(-)(1 )protein 10 s(-)(1)) (means +/- s.e.m., N=3), and bilateral exposure to zinc significantly (P<0.05) increased the maximal rate of influx, J(max), of proline (J(max)=4890+/-250 pmol mg(-)(1 )protein 10 s(-)(1)), but had no effect (P>0.05) on apparent l-[(3)H]proline binding to the membranes (K(m)=1.66+/-0.23 mmol l(-)(1)) (means +/- s.e.m., N=3). In the presence of 0.5 mmol l(-)(1 )l-pipecolate, bilateral zinc-stimulated, carrier-mediated, l-[(3)H]proline influx was abolished. At low external concentrations of zinc alone (e.g. below 1.0 mmol l(-)(1)), l-[(3)H]proline influx was enhanced by the metal. Enhanced amino acid uptake in the presence of external zinc alone was abolished by l-pipecolate. A model accounting for external and internal zinc enhancements of l-[(3)H]proline influx by the Na(+)-dependent l-pipecolate-sensitive IMINO transport system in these membranes is proposed.

Electroneutral Na+/H+ exchange in brush-border membrane vesicles from Penaeus japonicus hepatopancreas.

An electroneutral Na+/H+ exchange mechanism (dimethylamiloride inhibitable, Li+ sensitive, and Ca2+ insensitive) was identified in brush-border membrane vesicles (BBMV) from Kuruma prawn hepatopancreas by monitoring Na(+)-dependent H+ fluxes with the pH-sensitive dye acridine orange and measuring 22Na+ uptake. Kinetic parameters measured under short-circuited conditions were the Na+ concentration that yielded one-half of the maximal dissipation rate (Fmax) of the preset transmembrane delta pH (KNa) = 15 +/- 2 mM and Fmax = 3,626 +/- 197 delta F.min-1.mg protein-1, with a Hill coefficient for Na+ of approximately 1. In addition, the inhibitory constant for dimethylamiloride was found to be approximately 1 microM. The electroneutral nature of the antiporter was assessed in that an inside-negative transmembrane electrical potential neither affected kinetic parameters nor stimulated pH-dependent (intracellular pH > extracellular pH) 22Na+ uptake. In contrast, electrogenic pH-dependent 22Na+ uptake was observed in lobster hepatopancreatic BBMV. Substitution of chloride with gluconate resulted in increasing KNa and decreasing delta Fmax, which suggests a possible role of chloride in the operational mechanism of the antiporter. These results indicate that a Na+/H+ exchanger, resembling the electroneutral Na+/H+ antiporter model, is present in hepatopancreatic BBMV from the Kuruma prawn Penaeus japonicus.

An electroneutral anion exchange mechanism is present in brush-border membranes isolated from eel kidney.

The mechanism of bicarbonate translocation across the luminal membrane of the eel (Anguilla anguilla) kidney tubular cells was studied by monitoring the uptake of H14CO3- into isolated brush-border membrane vesicles. Results indicate that the presence of a transmembrane outwardly directed Cl- gradient was able to transiently accumulate H14CO3- into the vesicular space, whereas neither an inwardly directed sodium gradient nor a transmembrane electrical potential gradient (inside positive) was able to stimulate the H14CO3- influx. This anion-dependent H14CO3- uptake was inhibited by 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid, suggesting that an anion exchanger was present in the brush-border membrane vesicles.

Electrogenic, proton-coupled, intestinal dipeptide transport in herbivorous and carnivorous teleosts.

In both herbivorous tilapia (Oreochromis mossambicus) and carnivorous rockfish (Sebastes caurinus) intestinal and pyloric cecal brush-border membrane vesicles (BBMV), [14C]glycylsarcosine ([14C]Gly-Sar) uptake was stimulated by a transmembrane proton gradient. A transmembrane K(+)-diffusion potential (inside negative) stimulated [14C]Gly-Sar uptake above that observed with short-circuited vesicles, whereas an inwardly directed Na+ gradient in both fishes had no effect on peptide uptake. In tilapia, [14C]Gly-Sar influx occurred by the combination of 1) a high-affinity, saturable, proton gradient-dependent carrier system [Kt [concentration that equals one-half of maximum influx (Jmax)] = 0.56 +/- 0.08 mM; Jmax = 1,945.0 +/- 174.6 pmol.mg protein-1.10 s-1]; 2) a low-affinity, nonsaturable (within 1-10 mM), proton gradient-dependent carrier system (nonsaturable carrier-mediated transport component = 4,514.0 +/- 28.1 pmol.mg protein-1.10 s-1.mM-1); and 3) a diffusional component accounting for < 10% of total influx within the concentration range tested. Influx (10 s) of 1-10 mM [14C]Gly-Sar in tilapia intestine was significantly (P < 0.01) inhibited by 10 mM diethylpyrocarbonate, a specific inhibitor of proton-coupled peptide transport systems. [14C]Gly-Sar influx into tilapia BBMV showed cis-inhibition and trans-stimulation by Gly-Pro, suggesting that [14C]Gly-Sar and Gly-Pro shared the same mucosal peptide transporter in fish. These observations strongly suggest that intestinal transport of peptides in herbivorous and carnivorous fishes is proton gradient dependent, electrogenic, sodium independent, and qualitatively resembles the peptide transport paradigm proposed for mammals.

Basolateral dipeptide transport by the intestine of the teleost Oreochromis mossambicus.

Transport characteristics of [14C]glycylsarcosine ([14C]Gly-Sar) were measured in herbivorous tilapi (Oreochromis mossambicus) intestinal basolateral membrane vesicles (BLMV) purified with Percoll gradient centrifugation. Specific activity of the vesicle Na(+)-K(+)-adenosinetriphos- phatase was increased 12-fold, whereas specific activity of the brush-border enzyme alkaline phosphatase was enriched only by 0.8-fold. [14C]Gly-Sar uptake was stimulated by increasing concentrations of extravesicular protons rather than by a transmembrane proton gradient. A transmembrane K+ diffusion potential (inside negative) did not stimulate [14C]Gly-Sar uptake above that observed with short-circuited vesicles. An inwardly directed Na+ gradient had no effect on peptide uptake. Kinetic analysis of basolateral transport rate revealed that the transport occurred by a saturable process conforming to Michaelis-Menten kinetics [Kt [concentration of [14C]Gly-Sar that yielded one-half of maximal influx (Jmax)] = 13.27 +/- 3.80 mM, Jmax = 15,155 +/- 3,096 pmol.mg protein-1.6 s-1]. The basolateral transporter was insensitive to diethylpyrocarbonate (DEP), a specific inhibitor of proton-coupled peptide transport systems. [14C]Gly-Sar influx into tilapia BLMV showed cis-inhibition by several other dipeptides, suggesting that the [14C]Gly-Sar transporter was shared by other peptides too. These observations strongly suggest that the basolateral intestinal dipeptide transporter in herbivorous fishes is distinctly different from either the high- or low-affinity brush-border transporter. It is proton dependent, electroneutral, sodium independent and accepts a wide variety of dipeptides.

A monoclonal antibody to mammalian angiotensin II AT1 receptor recognizes one of the angiotensin II receptor isoforms expressed by the eel (Anguilla anguilla).

Using labelled ligand-binding methods, previous studies have identified specific angiotensin II receptors (Ang II-Rs) in eel liver, kidney and intestine membranes. Isoelectric focusing on polyacrylamide gels also showed that there are two Ang II-R isoforms in eel liver, focusing at isoelectric points (pI) 6.5 and 6.7. These may have different functions. In contrast, eel enterocyte plasma membrane and renal brush border membranes contain only the pI 6.5 form. To characterize the eel receptors more fully, a newly developed monoclonal antibody (6313/G2) which selectively recognizes the AT1 subtype of mammalian Ang II-R was used. In ligand-binding experiments, the preincubation of eel liver membranes with 6313/G2 antibody eliminated the specific [3,5-3H]Tyr4-Ile5-Ang II binding. Moreover, Ang II-receptor complexes from solubilized liver membranes, which were immunoprecipitated by 6313/G2-coated beads, had a pI of 6.5. In immunoblotting experiments, the antibody recognized the isoform focusing at pI 6.5 in eel intestine and liver preparations, but not the liver pI 6.7 isoform. Immunoblotting of SDS gels showed that the antibody bound to a single protein of molecular mass of 75 kDa in eel liver, gill and kidney and to a doublet of molecular mass of about 74 and 75 kDa in intestinal membrane preparations. Immunocytochemistry of paraffin-embedded and cryostat sections of eel liver, kidney, intestine and gill showed that antibody 6313/G2 bound to uniformly distributed intracellular sites and cell surface membranes in proximal tubular cells, absorptive intestinal cells, hepatocytes and chloride cells. It also stained endothelium and both the longitudinal and circular layers of smooth muscle cells in the intestine. The data suggest that the previously described Ang II-R from eel liver, kidney and intestine may be similar to the mammalian AT1 subtype.

Angiotensin II stimulation of the basolateral located Na+/H+ antiporter in eel (Anguilla anguilla) enterocytes.

The pH-sensitive fluorescent dye, 2',7'-bis-carboxyethyl-5, 6-carboxyfluorescein acetoxymethyl ester, was used to examine the effects of fish or human angiotensin II (Ang II) on the activity of the basolateral located Na+/H+ antiporter in eel intestinal cell suspensions. Exposure of eel enterocytes to either hormone led to an increased activity of the antiporter. This time- and dose-dependent stimulatory effect was inhibited by the specific antiporter inhibitor dimethylamiloride (DMA). Preincubation with a monoclonal antibody (6313/ G2), directed against the N-terminal extracellular domain of the mammalian AT1 Ang II receptor, prevented the stimulatory effect of the hormone and inhibited the binding of [3,5-3H] Tyr4-Ile5-Ang II to intestinal cell suspensions, suggesting specific binding of the antibody to the eel Ang II receptor. The results indicate that both fish and human Ang II stimulate the DMA-sensitive Na+/H+ antiporter present in eel intestinal cells by means of a mammalian AT1-like receptor.

Characterization of plasma membrane Na+/H+ exchange in eel (Anguilla anguilla) intestinal epithelial cells.

The ability of eel intestinal epithelial cells to recover from an acute acid load was analysed using the fluorescent dye 2',7'-bis-carboxy-ethyl-5,6-carboxyfluorescein (BCECF) and cell suspensions. Under these experimental conditions (bicarbonate-free solutions) the resting pHi in cells prepared from sea-water (7.52 +/- 0.031) and fresh-water (7.50 +/- 0.094) adapted animals proved to be similar. The recovery rate (following an acid load) increases by increasing the Na ion concentration in the extracellular medium. This pHi recovery is competitively inhibited by the specific inhibitor dimethylamiloride (DMA) with a low Ki in sea- (1.2 microM) as well as in fresh-water (1.3 microM) adapted animals, indicating the presence of a specific Na/H exchange activity in these cells. Using basolateral membrane vesicles it could be demonstrated that this activity is located on the basolateral side of the enterocyte membrane. The kinetic parameters (Kapp and Jmax) of this exchanger are similar in fresh-water and sea-water adapted animals suggesting that no salinity adaptation occurs, thus excluding the involvement of the antiporter in the osmoregulatory processes. These results are in agreement with the presence in the plasma membrane of the eel enterocytes of a Na/H-1 (housekeeper) form of the antiporter.

Ascorbic acid transport by intestinal brush-border membrane vesicles of the teleost Anguilla anguilla.

Transport of L-ascorbate by intestinal brush-border membrane vesicles of European eel Anguilla anguilla was stimulated by a transmembrane Na gradient (out > in) but not by a similarly directed gradient of K. Under short-circuited membrane potential conditions, a kinetic analysis of L-ascorbate influx indicated the presence of a single Na-dependent carrier process (Kapp = 0.75 +/- 0.07 mM and Jmax = 0.33 +/- 0.03 nmol.mg protein-1.min-1) and a nonsaturable transfer component with an apparent diffusional permeability (P) of 0.27 +/- 0.02 microliter.mg protein-1.min-1. D-Isoascorbate was a competitive inhibitor of L-ascorbate influx exhibiting a Ki of 8.21 +/- 0.63 mM. The electrogenic nature of +Na-L-ascorbate cotransport was confirmed by a stimulatory effect of an inside-negative membrane potential on vitamin uptake. Hill analysis of L-ascorbate influx over a wide range of external Na concentrations suggested a 2 Na-to-1 L-ascorbate binding ratio. Results indicate that the vitamin L-ascorbate is transported across fish intestinal brush-border membranes by an electrogenic Na-dependent carrier process in conjunction with more than one sodium ion.

Kinetic heterogeneity of Na-D-glucose cotransport in teleost gastrointestinal tract.

D-[3H]glucose transport properties of brush-border membrane vesicles (BBMV) of upper intestine and pyloric ceca of the Pacific copper rockfish (Sebastes caurinus) were characterized and compared. Vesicles from both organs exhibited Na-dependent, phloridzin-sensitive, carrier-mediated transport systems. Kinetic constants for D-[3H]glucose influx across vesicle membranes were as follows: upper intestine, apparent affinity of glucose (Kt) = 0.14 +/- 0.02 mM, maximal glucose influx (JM) = 1,649 +/- 57 pmol.mg protein-1.10 s-1; pyloric ceca, Kt = 0.58 +/- 0.12 mM, JM = 2,439 +/- 178 pmol.mg protein-1.10 s-1. A hyperbolic relationship, following Michaelis-Menten kinetics, occurred between D-glucose influx and external Na concentration for pyloric ceca, while a sigmoidal function, following Hill cooperativity kinetics (n = 1.71 +/- 0.31), was disclosed between the variables for the intestine. External phloridzin, D-glucose, methyl alpha-D-glucopyranoside, and D-galactose were the most potent inhibitors of D-[3H]glucose influx in each organ. Other compounds were generally more inhibitory in vesicles from the pyloric cecum than those of the intestine except for D-mannose which was considerably more potent in the intestine. Results suggest that there may be proximal-to-distal hexose- and Na-binding gradients in the teleost gut for optimizing sugar absorption during passage of food through the gastrointestinal tract.