ABC transporters in fish species: a review.

ATP-binding cassette (ABC) proteins were first recognized for their role in multidrug resistance (MDR) in chemotherapeutic treatments, which is a major impediment for the successful treatment of many forms of malignant tumors in humans. These proteins, highly conserved throughout vertebrate species, were later related to cellular detoxification and accounted as responsible for protecting aquatic organisms from xenobiotic insults in the so-called multixenobiotic resistance mechanism (MXR). In recent years, research on these proteins in aquatic species has highlighted their importance in the detoxification mechanisms in fish thus it is necessary to continue these studies. Several transporters have been pointed out as relevant in the ecotoxicological context associated to the transport of xenobiotics, such as P-glycoproteins (Pgps), multidrug-resistance-associated proteins (MRPs 1-5) and breast cancer resistance associated protein (BCRP). In mammals, several nuclear receptors have been identified as mediators of phase I and II metabolizing enzymes and ABC transporters. In aquatic species, knowledge on co-regulation of the detoxification mechanism is scarce and needs to be addressed. The interaction of emergent contaminants that can act as chemosensitizers, with ABC transporters in aquatic organisms can compromise detoxification processes and have population effects and should be studied in more detail. This review intends to summarize the recent advances in research on MXR mechanisms in fish species, focusing in (1) regulation and functioning of ABC proteins; (2) cooperation with phase I and II biotransformation enzymes; and (3) ecotoxicological relevance and information on emergent pollutants with ability to modulate ABC transporters expression and activity. Several lines of evidence are clearly suggesting the important role of these transporters in detoxification mechanisms and must be further investigated in fish to underlay the mechanism to consider their use as biomarkers in environmental monitoring.

Cloning and expression analysis of the 17ß hydroxysteroid dehydrogenase type 12 (HSD17B12) in the neogastropod Nucella lapillus.

HSD17B12 is a member of the hydroxysteroid dehydrogenase superfamily, a multifunctional group of enzymes involved in the metabolism of steroids, retinoids, bile and fatty acids. Whether the main role of HSD17B12 in mammals is in steroid or fatty acid metabolism is a subject of intense debate. In mollusks it has been shown that an HSD17B12 orthologue can convert estrone into estradiol in vitro, although its primary in vivo function remains unknown. To gain insight into its role in gastropods, we provide here the first cloning of Hsd17b12 in Nucella lapillus and its detailed tissue distribution through quantitative PCR. Furthermore, given that the endocrine disruptor tributyltin (TBT) has been reported to unbalance steroid and lipid levels in gastropods, we tested its impact in on NlHsd17b12 transcript expression. Our results show that NlHsd17b12 is ubiquitously expressed in all tissues analyzed, with higher levels in organs with high metabolic rates, such as kidney and digestive gland, a pattern consistent with an involvement in lipid metabolism. Exposure to TBT chloride at 100 ng Sn/L caused a decrease in NlHsd17b12 mRNA levels in digestive gland, after one and two months, while no effect was observed in gonads. Overall, these results suggest that in mollusks, as in mammals, this enzyme is likely to be involved in lipid metabolism, and emphasize the need to perform more detailed studies on its in vivo function, in order to understand its physiological role and the biological impact of its disruption by pollutants such as TBT.

A novel Acetyl-CoA synthetase short-chain subfamily member 1 (Acss1) gene indicates a dynamic history of paralogue retention and loss in vertebrates.

Acetyl-CoA short chain synthetases (ACSSs) are key enzymes in the activation of fatty acids through the formation of thioesters with CoA. Three subfamily members are currently recognized in the human genome, ACSS1, ACSS2 and ACSS3, all single copy genes. The mitochondrial isoform, Acss1, plays a key role in the metabolism of acetate for energy production. While the single copy condition has been accurately established in humans, the evolutionary history of the Acss1 subfamily in vertebrates has yet to be elucidated, in particular, the isoform diversity, origin and function. Through genome database mining we analyzed the diversity of Acss1 isoforms in vertebrate classes. We detected the presence of a novel Acss1 isoform, which we name Acss1B. This new gene, Acss1B, has a curious phylogenetic distribution being found in teleosts (except zebrafish), sauropsids (birds and reptiles) and probably chondrichthyes. In contrast Acss1A is found in all the investigated species, except the teleost medaka. By means of comparative genomics and phylogenetics we show that Acss1A and Acss1B were generated in the quadruplication of the vertebrate genome. In effect, we find that amphioxus, a pre-genome duplication chordate, has a single Acss1 gene in a genomic region equally related to a quadrupled vertebrate genomic set. Consequently, Acss1B has been lost in some teleosts, amphibians and mammals, while Acss1A is probably absent in medaka. The reported findings illustrate an especially dynamic pattern of paralogue retention and independent loss in vertebrate species involving the Acss1 subfamily, whose functional consequences in energy metabolism are as yet unknown.

Adaptive evolution of the Retinoid X receptor in vertebrates.

Retinoid X receptors (RXR) are transcription factors with important roles in development, reproduction, homeostasis, and cell differentiation. Different types of vertebrate RXRs (α (RXRA), ß (RXRB) and γ (RXRG)) have arisen from multiple duplication events. The adaptive evolution mechanism that has preserved duplicate RXR paralogs, as well as their role in development and adaptation, is thus far unknown. In this work, we have investigated different aspects of vertebrate RXR evolution. Codon based tests of positive selection identified that RXR was under significant positive selection immediately after the whole genome duplications in vertebrates. Amino acid based rate shift analysis also revealed significant rate shifts immediately after the whole genome duplications and functional divergence between all the pairs of RXRs. However, the extant RXR genes are highly conserved, particularly the helix involved in dimerization and the DNA-binding domain, but positively selected sites can nevertheless be found in domains for RXR regulation.

Spatial relationships of the intrahepatic vascular-biliary tracts and associated pancreatic acini of Nile tilapia, Oreochromis niloticus (Teleostei, Cichlidae): a serial section study by light microscopy.

Reports on teleost liver morphology reflect both controversial and confirmed interspecies variations. Choosing Nile tilapia as a model, we described the histology and 3D organization of all types of vascular-biliary tracts and their spatial relationships from the organ hilum toward the hepatic vein opening(s). The portal tracts entering the hilum, termed pancreatic-venous-biliary-arteriolar tracts (P-VBAT), are associated with pancreocytes and have an afferent axially located vein, plus biliary duct(s) and small artery(ies). The P-VBAT gradually disappears toward the anterior (efferent) end of the liver; those tracts ramify and originate new types of tracts, which may carry one type of element (vascular or biliary) or groups of two, in all possible combinations. Most tracts carrying afferent veins had pancreocytes, thus forming (pancreatic-venous tracts (P-VT), pancreatic-venous-biliary tracts (P-VBT), and pancreatic-venous-arteriolar tracts (P-VAT). There were terminal (and smaller) afferent isolated veins that had no associated pancreocytes. Also, the pancreatic sleeve of a vein could end abruptly or attenuate and disappear, reappearing in distal portions of the same vein. Thus, veins without pancreatic covering as seen in sections are not always efferent. Small arterioles can enter the liver retrogradely, via the adventitia of efferent hepatic veins, thus forming venous-arteriolar tracts (VAT). In comparison with the salmonid-liver type, there were no VBAT without associated pancreocytes and there was a smaller degree of ambiguity in identification of the afferent vs. efferent veins. Thus, the tilapine-liver type is proposed to be a more promising model for studying hepatic metabolic zonation in fish, defined not as in mammals, but eventually considering a gradient radiating from the hilum. Our data and differences from mammals supported the adequacy of the previously proposed nomenclature for the vascular-biliary tracts of fish livers, extending it to those that contain the exocrine pancreas.

Mixtures of estrogenic chemicals enhance vitellogenic response in sea bass.

BACKGROUND: The potential impact of natural and synthetic estrogens on aquatic ecosystems has attracted considerable attention because it is currently accepted that their joint effects are more severe when they are present in mixtures. Although it is well-known that they occur as mixtures in the marine environment, there is little information about the combined effects of estrogenic chemicals on marine biota. OBJECTIVE: In 14-day tests with juvenile sea bass, we analyzed singly and in combination the estrogenic activity of estradiol (E(2)), ethynylestradiol (EE(2)), and bisphenol A (BPA) using vitellogenin induction as an end point. METHODS: Fish were exposed to each compound, and on the basis of these concentration-response data, we predicted mixture effects by applying the model of concentration addition. The mixtures were tested using a fixed-ratio design, and the resulting mixture effects were compared to the predictions. RESULTS: EE(2) was the most potent steroid, with an EC(50) (median effective concentration) of 0.029 microg/L, 3.6 times more potent than E(2) (EC(50) = 0.104 microg/L); BPA was the least potent chemical, with an EC(50) of 77.94 microg/L. The comparative assessment yielded a good agreement between observed and predicted mixture effects. CONCLUSIONS: This study demonstrates the potential hazard of these compounds to seawater life by their ability to act together in an additive manner. It provides evidence that concentration addition can be used as a predictive tool for assessing the combined effects of estrogenic chemicals in marine ecosystems.

Temperature and gender influences on the hepatic stroma (and associated pancreatic acini) of Nile tilapia, Oreochromis niloticus (Teleostei, Cichlidae): a stereological analysis by light microscopy.

The normal organ morphology and function in fishes varies according to several natural factors, and such variability is found in liver. Knowledge about the normal liver microanatomy is fundamental to pathological evaluation. Even though gender and temperature are important factors for modulating morphophysiological processes in fishes, their influences on liver stroma are virtually unknown. Because temperature- and gender-related changes exist in liver parenchyma, we predict both factors should also influence the normal stromal structure. Using Nile tilapia as a model, we undertook a study to: 1) establish baseline quantitative structural data on the hepatic stroma (and intimately associated pancreatic acini); 2) compare data with those available from other species, namely, salmonids that do not have a liver with pancreatic acini; and 3) test our hypothesis that, within normal healthy limits, the stroma and its structural components may vary significantly with temperature and gender. We used 1-year-old male and female specimens acclimated to 17 degrees C (breeding noncompatible) and 27 degrees C (breeding compatible) for 45 days. Basic morphometric fish parameters were recorded. After estimation of liver volume, the organ was sliced and pieces systematically sampled for light microscopy. Stereology allowed estimation of the relative volumes of organ components. The total volumes were computed by combining the relative volumes with the total liver volumes. Nile tilapia of both genders, held at 17 vs. 27 degrees C, showed structural quantitative differences in the relative volumes of stroma and most of its components, and in the total volumes of certain stromal elements. The total volume of the stroma and of associated pancreatic acini did not differ. We first established that, in fishes, the total amount (volume) of liver biliary ducts and of eosinophilic granule cells might significantly change (increase and decrease, respectively) with a higher acclimation temperature. Indeed, virtually all the stereological changes were, essentially, temperature- and not gender-related. At 27 degrees C, parallel changes in the parenchyma caused a decreased liver volume and hepatic-somatic index (HSI). The relative volumetric proportion of stroma vs. parenchyma in tilapia is higher than in salmonids. The differences found in this study could not be detected with a qualitative approach, thus stressing the importance of using stereology for analyzing histological patterns and for establishing reliable baseline values in healthy conditions. It was also anticipated that in experimental settings with fish the baseline liver stromal architecture may be different according to temperature and breeding status; in consequence, the effects of the tested variable may also diverge. Our data do not fully explain the lower liver volume and HSI at 27 degrees C, thus justifying studies on the parenchyma, particularly on cell size and number.

The genomic environment around the Aromatase gene: evolutionary insights.

BACKGROUND: The cytochrome P450 aromatase (CYP19), catalyses the aromatisation of androgens to estrogens, a key mechanism in vertebrate reproductive physiology. A current evolutionary hypothesis suggests that CYP19 gene arose at the origin of vertebrates, given that it has not been found outside this clade. The human CYP19 gene is located in one of the proposed MHC-paralogon regions (HSA15q). At present it is unclear whether this genomic location is ancestral (which would suggest an invertebrate origin for CYP19) or derived (genomic location with no evolutionary meaning). The distinction between these possibilities should help to clarify the timing of the CYP19 emergence and which taxa should be investigated. RESULTS: Here we determine the "genomic environment" around CYP19 in three vertebrate species Homo sapiens, Tetraodon nigroviridis and Xenopus tropicalis. Paralogy studies and phylogenetic analysis of six gene families suggests that the CYP19 gene region was structured through "en bloc" genomic duplication (as part of the MHC-paralogon formation). Four gene families have specifically duplicated in the vertebrate lineage. Moreover, the mapping location of the different paralogues is consistent with a model of "en bloc" duplication. Furthermore, we also determine that this region has retained the same gene content since the divergence of Actinopterygii and Tetrapods. A single inversion in gene order has taken place, probably in the mammalian lineage. Finally, we describe the first invertebrate CYP19 sequence, from Branchiostoma floridae. CONCLUSION: Contrary to previous suggestions, our data indicates an invertebrate origin for the aromatase gene, given the striking conservation pattern in both gene order and gene content, and the presence of aromatase in amphioxus. We propose that CYP19 duplicated in the vertebrate lineage to yield four paralogues, followed by the subsequent loss of all but one gene in vertebrate evolution. Finally, we suggest that agnathans and lophotrocozoan protostomes should be investigated for the presence of aromatase.