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Campinho, Marco António

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0E18-2560-6EC1
0000-0002-5238-0506

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2004 - 20097
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End date: 2009 × Start date: 2004 ×

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Now showing 1 - 7 of 7
  • The molecular and endocrine basis of flatfish metamorphosis
    Publication . Power, Deborah; Einarsdóttir, Ingibjörg E.; Pittman, Karin; Sweeney, Glen E.; Hildahl, Jon; Campinho, Marco António; Silva, Nadia; Saele, Oystein; Galay-Burgos, M.; Smaàradóttir, Heiddis; Björnsson, Björn Thrandur
    A significant component of aquaculture is the production of good quality larvae, and, in the case of flatfish, this is tied up with the change from a symmetric larva to an asymmetric juvenile. Despite the pioneering work carried out on the metamorphosis of the Japanese flounder (Paralichthys olivaceus) and summer flounder (Paralichthys dentatus), the underlying molecular basis of flatfish metamorphosis is still relatively poorly characterized. It is a thyroid hormone (TH) driven process, and the role of other hormones in the regulation of the process along with the interplay of abiotic factors are still relatively poorly characterized as is the extent of tissue and organ remodeling, which underlie the profound structural and functional modifications that accompany the larval/juvenile transition. The isolation of genes for hormones, receptors, binding proteins, and other accessory factors has provided powerful tools with which to pursue this question. The application of molecular methodologies such as candidate gene approaches and microarray analysis coupled to functional genomics has started to contribute to understanding the complexity of tissue and organ modifications that accompany flatfish metamorphosis. A better understanding of the biology of normal metamorphosis is essential to identify factors contributing to abnormal metamorphosis.
    2008Journal article Restricted Show more
  • Temperature sensitivity of skeletal ontogeny in Oreochromis mossambicus
    Publication . Campinho, Marco António; Moutou, K. A.; Power, Deborah
    Sensitivity of skeletal ontogenesis to temperature was assessed in Mozambican tilapia Oreochromis mossambicus and culture temperature manipulations (22, 27 and 32 C) were used to establish if age or length gave the most suitable metric for standardization. Oreochromis mossambicus larval growth was composed of two growth stanzas: an initialpe riod of rapid growth, followed by a slower growth phase. Irrespective of culture temperature chondrogenesis occurred during the first rapid growth phase and ossification was initiated during the second slower growth phase. The sequence of events and rate at which ossification occurred was much more sensitive to temperature than chondrogenesis. Cumulative counts provide a useful developmental index for skeletal ontogenesis; overall, age (effective days-degrees) gave the best estimation of developmental status during chondrogenesis and the initiation of ossification, although standard length (as log10LS) was a better metric for completion of ossification. The timing of development of functionally important structures, such asMeckel’s cartilage, the branchial arches, the centra and the cleithrum important for breathing, feeding and swimming, was well conserved at all temperatures and may be a good index of teleost developmental stages.
    2004-10Journal article Restricted Show more
  • Troponin T isoform expression is modulated during Atlantic Halibut metamorphosis
    Publication . Campinho, M. A.; Silva, Nadia; Nowell, Mari; Llewellyn, Lynda; Sweeney, Glen E.; Power, Deborah
    Background: Flatfish metamorphosis is a thyroid hormone (TH) driven process which leads to a dramatic change from a symmetrical larva to an asymmetrical juvenile. The effect of THs on muscle and in particular muscle sarcomer protein genes is largely unexplored in fish. The change in Troponin T (TnT), a pivotal protein in the assembly of skeletal muscles sarcomeres and a modulator of calcium driven muscle contraction, during flatfish metamophosis is studied. Results: In the present study five cDNAs for halibut TnT genes were cloned; three were splice variants arising from a single fast TnT (fTnT) gene; a fourth encoded a novel teleost specific fTnTlike cDNA (AfTnT) expressed exclusively in slow muscle and the fifth encoded the teleost specific sTnT2. THs modified the expression of halibut fTnT isoforms which changed from predominantly basic to acidic isoforms during natural and T4 induced metamorphosis. In contrast, expression of red muscle specific genes, AfTnT and sTnT2, did not change during natural metamorphosis or after T4 treatment. Prior to and after metamorphosis no change in the dorso-ventral symmetry or temporal-spatial expression pattern of TnT genes and muscle fibre organization occurred in halibut musculature. Conclusion: Muscle organisation in halibut remains symmetrical even after metamorphosis suggesting TH driven changes are associated with molecular adaptations. We hypothesize that species specific differences in TnT gene expression in teleosts underlies different larval muscle developmental programs which better adapts them to the specific ecological constraints.
    2007Journal article Open Access Show more
  • Regulation of troponin T expression during muscle development in sea bream Sparus auratus Linnaeus: the potential role of thyroid hormones
    Publication . Campinho, Marco António; Sweeney, Glen E.; Power, Deborah
    In the sea bream Sparus auratus three stage-specific fast troponin T (fTnT) isoforms have been cloned and correspond to embryonic-, larval- and adult-specific isoforms. Characterisation, using database searches, of the putative genomic organisation of Fugu rubripes and Tetraodon nigroviridis fTnT indicates that alternative exon splicing in the 59 region of the gene generates the different isoforms. Moreover, comparison of teleost fTnTs suggests that alternative splicing of fTnT appears to be common in teleosts. A different temporal expression pattern for each fTnT splice variant is found during sea bream development and probably relates to differing functional demands, as a highly acidic embryonic form (pI 5.16) is substituted by a basic larval form (pI 9.57). Thyroid hormones (THs), which play an important regulatory role in muscle development in flatfish and tetrapods, appear also to influence TnT gene expression in the sea bream. However, THs have a divergent action on different sea bream TnT genes and although the slow isoform (sTnT1) is TH-responsive, fTnT, sTnT2 and the itronless isoform (iTnT) are unaffected. The present results taken together with those published for flatfish seem to suggest differences may exist in the regulation of larval muscle development in teleosts.
    2006Journal article Open Access Show more
  • Molecular, cellular and histological changes in skin from a larval to an adult phenotype during bony fish metamorphosis
    Publication . Campinho, Marco António; Silva, Nadia; Sweeney, Glen E.; Power, Deborah
    Developmental models for skin exist in terrestrial and amphibious vertebrates but there is a lack of information in aquatic vertebrates. We have analysed skin epidermal development of a bony fish (teleost), the most successful group of extant vertebrates. A specific epidermal type I keratin cDNA (hhKer1), which may be a bony-fishspecific adaptation associated with the divergence of skin development (scale formation) compared with other vertebrates, has been cloned and characterized. The expression of hhKer1 and collagen 1α1 in skin taken together with the presence or absence of keratin bundle-like structures have made it possible to distinguish between larval and adult epidermal cells during skin development. The use of a flatfish with a well-defined larval to juvenile transition as a model of skin development has revealed that epidermal larval basal cells differentiate directly to epidermal adult basal cells at the climax of metamorphosis. Moreover,hhKer1 expression is downregulated at the climax of metamorphosis and is inversely correlated with increasing thyroxin levels. We suggest that, whereas early mechanisms of skin development between aquatic and terrestrial vertebrates are conserved, later mechanisms diverge.
    2007-02Journal article Restricted Show more
  • Disruption of the thyroid system by diethylstilbestrol and ioxynil in the sea bream (Sparus aurata)
    Publication . Morgado, Isabel; Campinho, Marco António; Costa, Rita; Jacinto, R.; Power, Deborah
    Some environmental contaminants are thought to cause disruption of the thyroid system in vertebrates acting as endocrine disrupting chemicals (EDCs). Such chemicals may affect synthesis, transport and metabolism of thyroid hormones (THs). Ioxynil (IOX) and diethylstilbestrol (DES) are potential EDCs with strong affinity in vitro for sea bream transthyretin (TTR), a TH distributor protein (THDP). The aim of the present study was to establish how such chemicals influence the thyroid axis in sea bream (Sparus aurata). DES, IOX and propilthyouracil (PTU, a goitrogen) were administered in the diet to sea bream juveniles at 1 mg/kg fish (n = 14/treatment) for 21 days. After exposure plasma TH levels, quantified by RIA, were similar to those of control fish (p > 0.05) in all treatment groups. Analysis by quantitative PCR revealed that all treatments down-regulated TSH gene transcription (p < 0.05) in the brain and pituitary and deiodinase II and III transcription in the brain (p < 0.001). In contrast, PTU caused DII up-regulation in the liver (p < 0.05). Thyroid receptor beta (TR ) transcription was down-regulated in the pituitary by PTU (p < 0.001) and DES (p < 0.05). TTR plasma levels, quantified by ELISA, were elevated by all the chemicals including PTU (p < 0.001) which also increased TTR gene transcription in the liver (p < 0.05). Thyroid histology indicated follicular hyperstimulation in all treatments with marked hyperplasia, hypertrophy and colloid depletion in the PTU group. It appears therefore, that in vitro TTR-binders, IOX and DES, can strongly influence several components of the fish thyroid system in vivo but that the thyroid axis may have the ability to maintain or re-establish plasma TH homeostasis.
    2009Journal article Restricted Show more
  • Identification and analysis of teleost slow muscle troponin T (sTnT) and intronless TnT genes
    Publication . Campinho, Marco António; Power, Deborah; Sweeney, Glen E.
    In the present study cDNA clones representing two slow skeletal muscle troponin T genes (sTnT1sb and sTnT2sb) in the sea bream (Sparus auratus), an important aquaculture species, were isolated and characterised. A third, intronless, TnT gene (iTnTsb), which is an apparent orthologue of a previously described zebrafish TnT, was also isolated. In adult sea bream sTnT expression was restricted to red muscle and, using northern blotting, a single low abundance transcript was identified for sTnT1sb (1260 nucleotides) and a single high abundance transcript was identified for sTnT2sb (1000 nucleotides). In contrast, iTnTsb is predominantly expressed in adult fast muscle. All three TnT genes are also expressed during larval development. Phylogenetic analysis of sea bream sTnT proteins to identify maximum parsimony showed that iTnTsb, sTnT1sb and sTnT2sb each cluster in independent groups. sTnT1sb clustered with other vertebrate sTnTs, while sTnT2 clustered with a group of fish specific sequences (from Fugu rubripes, Oryzia latipes and Salmo trutta). The teleost sTnT2 and iTnT each constitute new, apparently teleost specific, TnT groups. Analysis of the corresponding Fugu scaffold indicates that sTnT2sb is encoded by a gene with twelve exons. The two sTnT cDNAs isolated in sea bream probably arose by duplication of an ancestral gene, and iTnT by reverse transcription. It remains to be established if the encoded proteins have different structural and mechanistic roles in fish muscle.
    2005Journal article Restricted Show more