Differential design for hopping in two species of wallabies

We explored molecular and morphological alteration in gill mitochondria-rich (MR) cells of Mozambique tilapia, Oreochromis mossambicus, acclimated to deionized freshwater (DFW), freshwater (FW), 1/3-diluted seawater (1/3 SW) and seawater (SW). Scanning electron microscopic observations revealed that the apical membrane of MR cells appeared as a flat or slightly projecting disk in DFW and FW, being larger in DFW than in FW. In contrast, the apical membrane typically formed a pit structure in 1/3 SW and SW. The mRNA expression levels of Na(+)/H(+) exchanger-3 (NHE3) and Na(+)/Cl(-) cotransporter (NCC) in the gills were increased with decreasing environmental salinity, whereas Na(+)/K(+)/2Cl(-) cotransporter-1a (NKCC1a) expression was upregulated by increasing salinity. Immunofluorescence staining showed that the MR cell population of DFW- and FW-acclimated tilapia consisted mostly of MR cells with apical NHE3 and those with apical-NCC; MR cells with basolateral NKCC1a dominated in SW-acclimated tilapia. These results indicated that apical-NHE3 and apical-NCC MR cells were ion-absorbing cells, and that basolateral-NKCC1a MR cells were ion-secreting cells. In fish acclimated to 1/3 SW, both ion-absorbing and secreting cells existed in the gills, suggesting that fish in near-isotonic water were equipped with mechanisms of both hyper- and hypoosmoregulation to prepare for environmental salinity changes.     

Microtubule‐dependent changes in morphology and localization of chloride transport proteins in gill mitochondria‐rich cells of the tilapia,Oreochromis mossambicus

The tilapia (Oreochromis mossambicus) is a euryhaline fish exhibiting adaptive changes in cell size, phenotype, and ionoregulatory functions upon salinity challenge. Na⁺/Cl^? cotransporter (NCC) and Na⁺/K⁺/2Cl^? cotransporter (NKCC) are localized in the apical and basolateral membranes of mitochondria‐rich (MR) cells of the gills. These cells are responsible for chloride absorption (NCC) and secretion (NKCC), respectively, thus, the switch of gill NCC and NKCC expression is a crucial regulatory mechanism for salinity adaptation in tilapia. However, little is known about the interaction of cytoskeleton and these adaptive changes. In this study, we examined the time‐course of changes in the localization of NKCC/NCC in the gills of tilapia transferred from fresh water (FW) to brackish water (20‰) and from seawater (SW; 35‰) to FW. The results showed that basolateral NKCC disappeared and NCC was expressed in the apical membrane of MR cells. To further clarify the process of these adaptive changes, colchicine, a specific inhibitor of microtubule‐dependent cellular regulating processes was used. SW‐acclimated tilapia were transferred to SW, FW, and FW with colchicine (colchicine‐FW) for 96 h. Compared with the FW‐treatment group, in the MR cells of colchicine‐FW‐treatment group, (1) the average size was significantly larger, (2) only wavy‐convex‐subtype apical surfaces were found, and (3) the basolateral (cytoplasmic) NKCC signals were still exhibited. Taken together, our results suggest that changes in size, phenotype, as well as the expression of NCC and NKCC cotransporters of MR cells in the tilapia are microtubule‐dependent. J. Morphol. 277:1113–1122, 2016. © 2016 Wiley Periodicals, Inc.     

Ambient salinity modulates the expression of sodium pumps in branchial mitochondria-rich cells of Mozambique tilapia,Oreochromis mossambicus

Na,K-ATPase (sodium pumps) provide the primitive driving force for ion transport in branchial epithelial cells. Immunoblots of epithelial homogenates of both seawater (SW)- and freshwater (FW)-adapted tilapia gills as well as rat brain homogenate, a positive control, revealed one major band with a molecular weight of about 100 kDa. SW-adapted tilapia gills possessed larger (about 2-fold) amounts of sodium pumps compared with FW-adapted tilapia gills. (3)H-ouabain binding representing functional binding sites of Na,K-ATPase was also higher (about 3.5-fold) in gills of SW-adapted tilapia compared to that of FW-adapted fish. Moreover, specific activities of SW fish were higher (about 2-fold) than those of FW fish. Double labeling of Na,K-ATPase and Con-A, a fluorescent marker of MR cells, in tilapia gills followed by analysis with confocal microscopy showed that sodium pumps were localized mainly in MR cells, including the SW type and different FW types. Although more-active expression of Na,K-ATPase was demonstrated in gills of SW-adapted tilapia, no significant differences in densities of apical openings of MR cells were found between SW- and FW-adapted fish. These results indicate that, during salinity challenge, tilapia develop more "functional" Na,K-ATPase in SW-type MR cells to meet physiological demands.     

Recruitment and degeneration of mitochondrion-rich cells in the gills of Mozambique tilapia Oreochromis mossambicus during adaptation to a hyperosmotic environment

Cellular recruitment and degeneration of branchial mitochondrion-rich (MR) cells were examined in Mozambique tilapia transferred from hypoosmotic to hyperosmotic water. To examine apoptosis in the gills associated with salinity change, tilapia were directly transferred from freshwater to 70% seawater. The TUNEL assay showed that apoptotic cells in the gills were significantly increased at 1 day after transfer, which was supported by an electron-microscopic observation that gill MR cells underwent morphological changes characteristic of apoptosis such as an irregularly shaped electron-dense nucleus and distension of the tubular system. To further examine MR-cell recruitment, freshwater-acclimated tilapia were transferred either to freshwater or to 70% seawater after BrdU injection. Immunohistochemical detection of BrdU-labeled nuclei and Na(+)/K(+)-ATPase-rich MR cells allowed us to classify BrdU-labeled MR cells into two subtypes: a single MR cell and an MR-cell complex. Although newly generated single MR cells were observed similarly in both freshwater and 70% seawater-transferred fish, the density of MR-cell complexes was much higher in 70% seawater than in freshwater. Our findings indicated that transfer from hypoosmotic to hyperosmotic water enhanced apoptosis of freshwater-type MR cells, resulting in reduction in hyperosmoregulatory ability for freshwater adaptation, and stimulated the recruitment of MR-cell complexes to develop hypoosmoregulatory ability for seawater adaptation.     

Responses of gill mitochondria-rich cells in Mozambique tilapia exposed to acidic environments (pH 4.0) in combination with different salinities

On exposure to hyposmotic acidic water, teleost fish suffer from decreases in blood osmolality and pH, and consequently activate osmoregulatory and acid-base regulatory mechanisms to restore disturbed ion and acid-base balances. In Mozambique tilapia Oreochromis mossambicus exposed to acidic (pH 4.0) or neutral (pH 7.4-7.7) freshwater in combination with 0mM or 50mM NaCl, we examined functional and morphological changes in gill mitochondria-rich (MR) cells. We assessed gene expression of Na(+)/H(+) exchanger-3 (NHE3), Na(+)/Cl(-) cotransporter (NCC), vacuolar-type H(+)-ATPase (V-ATPase) and Na(+)/HCO(3)(-) cotransporter-1 (NBC1) in the gills. The mRNA expression of NHE3 and NCC in tilapia gills were higher in acidic freshwater than in that supplemented with 50mM NaCl, while there was no significant difference in mRNA levels of V-ATPase and NBC1. In addition, immunocytochemical observations showed that apical-NHE3 MR cells were enlarged, and frequently formed multicellular complexes with developed deep apical openings in acidic freshwater with 0mM and 50mM NaCl. These findings suggest that gill MR cells respond to external salinity and pH treatments, by parallel manipulation of osmoregulatory and acid-base regulatory mechanisms.     

Differential responses in gills of euryhaline tilapia, Oreochromis mossambicus, to various hyperosmotic shocks

Euryhaline tilapia (Oreochromis mossambicus) survived in brackish water (BW; 20‰) but died in seawater (SW; 35‰) within 6 h when transferred directly from fresh water (FW). The purpose of this study was to clarify responses in gills of FW tilapia to various hyperosmotic shocks induced by BW or SW. In FW-acclimated tilapia, scanning electron micrographs of gills revealed three subtypes of MR cell apical surfaces: wavy-convex (subtype I), shallow-basin (subtype II), and deep-hole (subtype III). Density of apical surfaces of mitochondrion-rich (MR) cell in gills of the BW-transfer tilapia decreased significantly within 3 h post-transfer due to disappearance of subtype I cells, but increased from 48 h post-transfer because of increasing density of subtype III cells. SW-transfer individuals, however, showed decreased density of MR cell openings after 1 h post-transfer because subtype I MR cell disappeared. On the other hand, relative branchial Na⁺/K⁺-ATPase (NKA) α1-subunit mRNA levels, protein abundance, and NKA activity of the BW-transfer group increased significantly at 6, 12, and 12 h post-transfer, respectively. In the SW-transfer group, relative mRNA and protein abundance of gill NKA α1-subunit did not change while NKA activity declined before dying in 5 h. Upon SW transfer, dramatic increases (nearly 2-fold) of plasma osmolality, [Na⁺], and [Cl⁻] were found prior to death. For the BW-transfer group, plasma osmolality was eventually controlled by 96 h post-transfer by enhancement of NKA expression and subtype III MR cell. The success or failure of NKA activation from gene to functional protein as well as the development of specific SW subtype in gills were crucial for the survival of euryhaline tilapia to various hyperosmotic shocks.     

Heterogeneous cellular expression of creatine kinase isoenzyme during normal rat heart development

The degree to which developmentally related alterations in cardiac creatine kinase (CK) activity reflect modification of CK isoenzyme gene expression remains uncertain. The present studies addressed this question by assessing multiple aspects of CK in rat heart during the perinatal to adult transition. In addition to whole tissue, isolated and purified muscle and nonmuscle cells were studied, as well as myofibrillar, mitochondrial, and cytosolic subcellular fractions. Whole homogenate CK enzyme specific activity nearly doubled during the weanling to adult developmental period. Muscle cell CK activity increased by a similar magnitude. Nonmuscle cell activity decreased. In the adult heart, both myofibrillar and mitochondrial CK activities were augmented versus the weanling heart. The cytoplasmic fraction activity held constant during development. Electrophoretic isoenzyme analyses of both weanling and adult cardiac muscle cells indicated the presence of mitochondrial CK and MM-CK isoforms. Weanling heart nonmuscle cells contained mitochondrial, MM, MB, and BB isoforms; however, BB isoform was not detected in the adult heart nonmuscle cells. Arrhenius plots provided information regarding heart muscle and nonmuscle cell alterations during development. CK activation energies were also determined for whole tissue, muscle/nonmuscle cells, myofibrils, mitochondria, and cytosol. Results demonstrate that heterogeneous muscle/nonmuscle cellular composition and differential myofibrillar/mitochondrial subcellular composition account for normal, developmentally related changes in heart CK enzyme activity. CK isoenzyme gene expression changes were not detected in cardiac muscle cells, and transition of CK-B to CK-M gene expression is limited to nonmuscle cells during normal, weanling to adult development in the rat heart.     

Expression of Key Ion Transporters in the Gill and Esophageal-Gastrointestinal Tract of Euryhaline Mozambique Tilapia Oreochromis mossambicus Acclimated to Fresh Water,Seawater and Hypersaline Water

The ability of euryhaline Mozambique tilapia to tolerate extreme environmental salinities makes it an excellent model for investigating iono-regulation. This study aimed to characterize and fill important information gap of the expression levels of key ion transporters for Na⁺ and Cl⁻ in the gill and esophageal-gastrointestinal tract of Mozambique tilapia acclimated to freshwater (0 ppt), seawater (30 ppt) and hypersaline (70 ppt) environments. Among the seven genes studied, it was found that nkcc2, nkcc1a, cftr, nka-α1 and nka-α3, were more responsive to salinity challenge than nkcc1b and ncc within the investigated tissues. The ncc expression was restricted to gills of freshwater-acclimated fish while nkcc2 expression was restricted to intestinal segments irrespective of salinity challenge. Among the tissues investigated, gill and posterior intestine were found to be highly responsive to salinity changes, followed by anterior and middle intestine. Both esophagus and stomach displayed significant up-regulation of nka-α1 and nka-α3, but not nkcc isoforms and cftr, in hypersaline-acclimated fish suggesting a response to hypersalinity challenge and involvement of other forms of transporters in iono-regulation. Changes in gene expression levels were partly corroborated by immunohistochemical localization of transport proteins. Apical expression of Ncc was found in Nka-immunoreactive cells in freshwater-acclimated gills while Nkcc co-localized with Nka-immunoreactive cells expressing Cftr apically in seawater- and hypersaline-acclimated gills. In the intestine, Nkcc-stained apical brush border was found in Nka-immunoreactive cells at greater levels under hypersaline conditions. These findings provided new insights into the responsiveness of these genes and tissues under hypersalinity challenge, specifically the posterior intestine being vital for salt absorption and iono-osmoregulation in the Mozambique tilapia; its ability to survive in hypersalinity may be in part related to its ability to up-regulate key ion transporters in the posterior intestine. The findings pave the way for future iono-regulatory studies on the Mozambique tilapia esophageal-gastrointestinal tract.     

Ontogenic change in tissue osmolality and developmental sequence of mitochondria-rich cells in Mozambique tilapia developing in freshwater

We investigated a change in tissue fluid osmolality and developmental sequences of mitochondria-rich (MR) cells during embryonic and larval stages of Mozambique tilapia, Oreochromis mossambicus, developing in freshwater. Tissue osmolality, representing body fluid osmolality, ranged from 300 to 370 mOsm/kg during embryonic and larval stages. This suggests that tilapia embryos and larvae are also able to regulate body fluid osmolality to some extent, although the levels are somewhat higher and fluctuate more greatly in embryos and larvae than in adults. Na⁺/K⁺-ATPase-immunoreactive MR cells were first detected in the yolk-sac membrane 3 days before hatching (day − 3), followed by their appearance in the body skin on day − 2. Subsequently, MR cells in both the yolk-sac membrane and body skin increased in number, and most densely observed on days − 1 and 0. Whereas yolk-sac and skin MR cells decreased after hatching, MR cells in turn started developing in the gills after hatching. Thus, the principal site for MR cell distribution shifted from the yolk-sac membrane and body skin during embryonic stages to the gills during larval stages, and tilapia could maintain continuously their ion balance through those MR cells during early life stages.     

Phenotypic changes in mitochondrion-rich cells and responses of Na+/K+-ATPase in gills of tilapia exposed to deionized water

The aim of this study was to illustrate the phenotypic modification of mitochondrion-rich (MR) cells and Na(+)/K(+)-ATPase (NKA) responses, including relative protein abundance, specific activity, and immunolocalization in gills of euryhaline tilapia exposed to deionized water (DW) for one week. The plasma osmolality was not significantly different between tilapia of the local fresh water (LFW) group and DW group. Remodeling of MR cells occurred in DW-exposed fish. After transfer to DW for one week, the relative percentage of subtype-I (wavy-convex) MR cells with apical size ranging from 3 to 9 microm increased and eventually became the dominant MR cell subtype. In DW tilapia gills, relative percentages of lamellar NKA immunoreactive (NKIR) cells among total NKIR cells increased to 29% and led to significant increases in the number of NKIR cells. In addition, the relative protein abundance and specific activity of NKA were significantly higher in gills of the DW-exposed fish. Our study concluded that tilapia require the development of subtype-I MR cells, the presence of lamellar NKIR cells, and enhancement of NKA protein abundance and activity in gills to deal with the challenge of an ion-deficient environment.     

Expression of creatine kinase isoenzymes in myogenic cell lines.

Investigation of creatine kinase isoenzyme activity in several cloned myogenic cell lines showed differences in B-type subunit expression. In cultures of myoblasts isolated from rat skeletal muscle by selective cell plating and in the cell lines M58 and M41, the activity of the mononucleated cells was of the BB isoenzyme. After cell fusion, MM, MB, and BB isoenzymes were present; the main activity was of the MM isoenzyme. In the myogenic lines L8 and L84, in cultures of mononucleated cells, creatine kinase activity was absent or barely detectable. The high creatine kinase activity after cell fusion was of the MM type. No BB and MB activity was detected in these lines at any stage of differentiation. The difference in expression of creatine kinase isoenzymes seems not to affect the expression of other parameters of differentiation.     

Acute changes in gill Na+-K+-ATPase and creatine kinase in response to salinity changes in the euryhaline teleost, tilapia (Oreochromis mossambicus)

Some freshwater (FW) teleosts are capable of acclimating to seawater (SW) when challenged; however, the related energetic and physiological consequences are still unclear. This study was conducted to examine the changes in expression of gill Na(+)-K(+)-ATPase and creatine kinase (CK) in tilapia (Oreochromis mossambicus) as the acute responses to transfer from FW to SW. After 24 h in 25 ppt SW, gill Na(+)-K(+)-ATPase activities were higher than those of fish in FW. Fish in 35 ppt SW did not increase gill Na(+)-K(+)-ATPase activities until 1.5 h after transfer, and then the activities were not significantly different from those of fish in 25 ppt SW. Compared to FW, the gill CK activities in 35 ppt SW declined within 1.5 h and afterward dramatically elevated at 2 h, as in 25 ppt SW, but the levels in 35 ppt SW were lower than those in 25 ppt SW. The Western blot of muscle-type CK (MM form) was in high association with the salinity change, showing a pattern of changes similar to that in CK activity; however, levels in 35 ppt SW were higher than those in 25 ppt SW. The activity of Na(+)-K(+)-ATPase highly correlated with that of CK in fish gill after transfer from FW to SW, suggesting that phosphocreatine acts as an energy source to meet the osmoregulatory demand during acute transfer.     

Salinity tolerance and structure of external and internal gills in tadpoles of the crab-eating frog,Rana cancrivora

Summary Salinity tolerance and histology of gills were studied in Rana cancrivora larvae. The tadpoles at the external gill stages (W stages 21–22) were able to survive in media containing up to 40% seawater, but died in water of higher salinity. Their external gills appear to have no critical role in adaptation to seawater. However, advanced tadpoles with internal gills (T-K stages I–XVIII) were able to tolerate 50% or higher seawater. In the internal gills, there are numerous mitochondriarich cells (MR cells) scattered on the ventral and lateral epithelia of the gill arches and the gill tufts in both freshwater-and seawater-acclimated tadpoles. In freshwater-acclimated tadpoles there are three types of MR cell: (1) microplicated, (2) microvillous, and (3) apically vacuolated. In tadpoles acclimated to dilute seawater, the ratio of type-1 to type-2 cells is lower, although all three types of MR cell are present. In 60%-seawater-acclimated tadpoles, a few MR cells with a lumen and concave cytoplasm at the apical membrane (type 4) are present. The changes in MR cell morphology under ambient conditions of low or high salinity may reflect alterations in the physiological roles of the gills with regard to transport of ions.     

Ion-deficient environment induces the expression of basolateral chloride channel, ClC-3-like protein, in gill mitochondrion-rich cells for chloride uptake of the tilapia Oreochromis mossambicus

Gill mitochondrion-rich (MR) cells contain different molecules to carry out functionally distinct mechanisms. To date, the putative mechanism of Cl(-) uptake through the basolateral chloride channel, however, is less understood. To clarify the Cl(-)-absorbing mechanism, this study explored the molecular and morphological alterations in branchial MR cells of tilapia acclimated to seawater (SW), freshwater (FW), and deionized water (DW). Scanning electron microscopic observations revealed that three subtypes of MR cells were exhibited in gill filament epithelia of tilapia. Furthermore, in DW-acclimated tilapia, the subtype I (ion-absorbing subtype) of MR cells predominantly occurred in gill filament as well as lamellar epithelia. Whole-mount double immunofluorescent staining revealed that branchial ClC-3-like protein and Na(+)/K(+)-ATPase (NKA), the basolateral marker of MR cells, were colocalized in tilapia. In SW-acclimated tilapia, all MR cells of gill filament epithelia exhibited faint fluorescence of ClC-3-like protein. In contrast, only some MR cells in gill filament epithelia of FW and DW tilapia expressed basolateral ClC-3-like protein; however, the fluorescence was more intense in FW and DW tilapia than in SW fish. In hyposmotic groups, the number of MR cells immunopositive for ClC-3-like protein was significantly higher in DW-exposed tilapia. Meanwhile, in gill lamellar epithelia of DW tilapia, all MR cells (subtype I) were ClC-3-like protein immunopositive. Double immunostaining of ClC-3-like protein and Na(+)/Cl(-) cotransporter (NCC) revealed that basolateral ClC-3-like protein and apical NCC were colocalized in some MR cells in FW and DW tilapia. Moreover, both mRNA and protein amounts of branchial ClC-3-like protein were significantly higher in DW-acclimated tilapia. To identify whether the expression of branchial ClC-3-like protein responded to changes in environmental [Cl(-)], tilapia were acclimated to artificial waters with normal [Na(+)]/[Cl(-)] (control), lower [Na(+)] (low Na), or lower [Cl(-)] (low Cl). Immunoblotting of crude membrane fractions for gill ClC-3-like protein showed that the protein abundance was evidently enhanced in tilapia acclimated to the low-Cl environment compared with the other groups. Our findings integrated morphological and functional classifications of ion-absorbing MR cells and indicated that ion-deficient water elevated the numbers of subtype I MR cells in both filament and lamellar epithelia of gills with positive ClC-3-like protein immunostaining and increased the expression levels of ClC-3-like protein. This study is the first to illustrate the exhibition of a basolateral chloride channel potentially responsible for Cl(-) absorption in the ion-absorbing subtype of gill MR cells of tilapia.     

Biochemical characterization of isolated branchial mitochondria-rich cells of Oreochromis mossambicus acclimated to fresh water or hyperhaline sea water

Mitochondria-rich cells have been separated from other epithelial cells of tilapia (Oreochromis mossambicus) gills by density gradient centrifugation on Percoll. During centrifugation two main bands of cells formed. The viability of the cells in both bands was high (>90%). In one band, 45–47% of the total cell number was mitochondria-rich cells. The other band contained at least 80% pavement cells, representing the majority of other gill epithelial cell types. A comparison of the activities of four enzymes involved in major metabolic and ion regulatory functions was made between these two different fractions of cells. Furthermore, the separation of gill epithelial cells and determination of enzymatic activity was carried out in tilapia after the fish were acclimated to fresh water or hyperhaline sea water (60 mg·ml^-1 S) to gain an indication of the relative contribution of mitochondria-rich cells and pavement cells to both NaCl excretion and absorption. Regardless of acclimation salinity, the activities of Na⁺/K⁺-ATPase, glutamate dehydrogenase and glucose-6-phosphate dehydrogenase were significantly higher in mitochondria-rich cells than in pavement cells. However, tilapia acclimated to hyperhaline sea water possessed significantly lower carbonic anhydrase activity in mitochondria-rich cells than in pavement cells. In contrast, no significant difference of carbonic anhydrase activity was observed between the two cell fractions in tilapia acclimated to fresh water.Abbreviations ATPase adenosine triphosphatase - CA carbonic anhydrase - DASPMI dimethylaminostyrylmethylpyridinium iodine - FW fresh-water - GIDH glutamate dehydrogenase - G6PDH glucose-6-phosphate dehydrogenase - HSW hyperhaline sea water (60 mg·ml^-1) - MR cells, mitochondria-rich cells - S salinity     

Effect of denervation on the distribution and developmental transition of phosphoglycerate mutase and creatine phosphokinase isozymes in rat muscles of different fiber-type composition

Phosphoglycerate mutase (PGM) and creatine phosphokinase (CK) occur as three isozymes (types MM, MB and BB) in mammals and these exhibit similar transitions during skeletal muscle development. To study the influence of innervation on this transition and on the maintenance of the isozyme phenotype in mature muscle, we have determined the changes produced by sciatic neurectomy in neonatal and adult rat hindlimb muscles. In 40-day-old rats, denervation decreased both PGM and CK activity, the effect being more pronounced in the fast-twitch extensorum digitorum longus (EDL) and gastrocnemius muscles than in the slow-twitch soleus muscle. It also produced a progressive increase in the proportion of MB- and BB-PGM isozymes in EDL and gastrocnemius but not in soleus, and an increase of MB- and BB-CK isozymes in all three muscles. In 5-day-old rats, denervation prevented the developmental increase of PGM and CK activity in all three muscles. Denervation also prevented the normal decrease in the relative amounts of the MB and BB isozymes of both enzymes which occur during postnatal muscle development. These results can be explained by the different effects of denervation upon slow and fast muscles, and by the distinct distribution of PGM and CK isozymes in rat type I and II muscle fibers.     

Time-course changes in the expression of Na, K-ATPase and the morphometry of mitochondrion-rich cells in gills of euryhaline tilapia (Oreochromis mossambicus) during freshwater acclimation

Changes in expression of Na, K-ATPase (NKA) and morphometry of mitochondrion-rich (MR) cells in gills of tilapia were investigated on a 96-hr time course following transfer from seawater (SW) to fresh water (FW). A transient decline in plasma osmolality and Na+, Cl- concentrations occurred from 3 hrs onward. Gills responded to FW transfer by decreasing NKA activity as early as 3 hrs from transfer. This response was followed by a significant decrease in the NKA isoform alpha1-mRNA abundance, which was detected by real-time PCR at 6 hrs post transfer. Next, a decrease of alpha1-protein amounts were observed from 6 hrs until 24 hrs post transfer. Additionally, during the time course of FW transfer, modifications in number and size of subtypes of gill MR cells were observed although no significant difference was found in densities of all subtypes of MR cells. These modifications were found as early as 3 hrs, evident at 6 hrs (exhibition of 3 subtypes of MR cells), and mostly completed by 24 hrs post transfer. Such rapid responses (in 3 hrs) as concurrent changes in branchial NKA expression and modifications of MR cell subtypes are thought to improve the osmoregulatory capacity of tilapia in acclimation from hypertonic SW to hypotonic FW.     

Carbonic anhydrase 2-like a and 15a are involved in acid-base regulation and Na+ uptake in zebrafish H+-ATPase-rich cells

H⁺-ATPase-rich (HR) cells in zebrafish gills/skin were found to carry out Na⁺ uptake and acid-base regulation through a mechanism similar to that which occurs in mammalian proximal tubular cells. However, the roles of carbonic anhydrases (CAs) in this mechanism in zebrafish HR cells are still unclear. The present study used a functional genomic approach to identify 20 CA isoforms in zebrafish. By screening with whole mount in situ hybridization, only zca2-like a and zca15a were found to be expressed in specific groups of cells in zebrafish gills/skin, and further analyses by triple in situ hybridization and immunocytochemistry demonstrated specific colocalizations of the two zca isoforms in HR cells. Knockdown of zca2-like a caused no change in and knockdown of zca15a caused an increase in H⁺ activity at the apical surface of HR cells at 24 h postfertilization (hpf). Later, at 96 hpf, both the zca2-like a and zca15a morphants showed decreased H⁺ activity and increased Na⁺ uptake, with concomitant upregulation of znhe3b and downregulation of zatp6v1a (H⁺-ATPase A-subunit) expressions. Acclimation to both acidic and low-Na⁺ fresh water caused upregulation of zca15a expression but did not change the zca2-like a mRNA level in zebrafish gills. These results provide molecular physiological evidence to support the roles of these two zCA isoforms in Na⁺ uptake and acid-base regulation mechanisms in zebrafish HR cells. ionocytes; Na⁺/H⁺ exchanger; skin; gill; embryo     

Glucose Homeostasis in the Teleost Fish Tilapia: Insights from Brockmann Body Xenotransplantation Studies

Certain teleost fish have large anatomically discrete isletorgans called Brockmann bodies (BBs). When transplanted intostreptozotocin diabetic athymic nude mice, tilapia BBs providelong-term normoglycemia. This has afforded us the opportunityto examine tilapia islet in vivo function in a non-piscine environmentand compare this with in vivo function in the donor species.As expected, fasting and non-fasting glycemic levels in long-termmurine recipients of tilapia BBs were analogous to correspondingvalues in donor tilapia, but, surprisingly, tilapia BB graftsprovided mammalian-like glucose tolerance profiles. Teleostfish, in general, are severely glucose intolerant. When glucosetolerance tests were performed in tilapia, the mean glucosedisappearance rates were very low; however, diabetic nude micebearing long-term tilapia BB grafts were extremely glucose responsive.This suggested a severe or absolute peripheral resistance tothe glucostatic effects of insulin. Using Western blotting withpolyclonal antibodies and then confirmed by Northern analysis,tilapia peripheral tissues appear to be devoid of GLUT-4, theinsulin-sensitive glucose transporter responsible for the hypoglycemiceffect of insulin in mammals, but not GLUT-1, the insulin independentglucose transporter. This may explain why tilapia, and possiblyother teleost fish, are severely glucose intolerant after pharmacologicglucose-loading. Because tilapia do not tend to consume largequantities of glucose in the wild, it is not surprising thatthey have evolved without a mechanism to move glucose rapidlyfrom the bloodstream into muscle and fat. Nevertheless, insulinstill appears to play an important role in maintaining normoglycemiain tilapia; however, this is mostly likely a result of its effecton glucose uptake in the liver. We also present comparativedata on tilapia beta cell function, quantification of isletcell numbers and types, islet products, insulin gene structureand expression, and beta cell sensitivity to the diabetogenicdrug streptozotocin.     

Impact of environmental DDT concentrations on gill adaptation to increased salinity in the tilapia Sarotherodon melanotheron

Estuaries of tropical developing countries suffering from severe droughts induced by climate change are habitats to fish, which face drastic salinity variations and the contact with pollutants. The Western Africa tilapia Sarotherodon melanotheron is highly resistant to hypersalinity, but the effect of human-released xenobiotics on its adaptation is barely known. Controlled experiments were conducted to observe S. melanotheron gill adaptation to abrupt salinity variations in the presence of waterborne DDT, at concentrations detected in their natural habitat. The gills appeared as an important site of DDT conversion to DDD and/or depuration. A 12-days DDT exposure resulted in decreased gill epithelium thickness at all salinities (from fresh- to hypersaline-water), and the structure of gills from freshwater fish was particularly altered, relative to controls. No unbalance in tilapia blood osmolality was observed following DDT exposure, which however caused a decrease in branchial Na(+)-K(+)-ATPase (NKA) activity. Gill cellular NKA expression was reduced in salt-water, together with the expression of the CFTR chloride channel in hypersaline water. Although S. melanotheron seems very resistant (especially in seawater) to short-term waterborne DDT contamination, the resulting alterations of the gill tissue, cells and enzymes might affect longer term respiration, toxicant depuration and/or osmoregulation in highly fluctuating salinities.