Keisuke Yamano

Changes in whole body concentrations of thyroid hormones and cortisol in metamorphosing conger eel

SummaryTo clarify the hormonal regulation of metamorphosis of the conger eel (Conger myriaster), changes in whole body concentrations of thyroid hormones, thyroxine (T4) and triiodothyronine (T3), and cortisol during metamorphosis were examined, as well as the changes in the histological activity of the thyroid gland. In larvae before metamorphosis, T4 and T3 levels were less than 5 and 0.15 ng·g-1 respectively. Levels of T4 increased to about 30 ng·g-1 during early metamorphosis, and decreased subsequently. Levels of T3 increased gradually in early metamorphosis, and then increased abruptly to about 2.0 ng·g-1 in late metamorphosis. Before metamorphosis, cortisol levels of the leptocephali less than 11 cm in total length were greater than 200 ng·g-1. Cortisol levels decreased rapidly in larger premetamorphic leptocephali, and low levels were maintained throughout the metamorphic period. Histological observation revealed an activation of the thyroid gland in early metamorphosis; thyroid follicle epithelial cells became columnar and their nuclei larger. Active uptake of colloid by these cells and intensive vascularization of the gland were also observed. By the end of metamorphosis, follicle epithelial cells became squamous, indicating a low level of glandular activity. These results suggest that thyroid hormone plays an important role in regulation of conger eel metamorphosis.

The role of thyroid hormone in tissue development in metamorphosing flounder

Abstract Japanese flounder exhibit extensive morphological and functional changes in various organs during metamorphosis. The larval-type muscle characterized by abundant basophilic sarcoplasm and a small number of myofibrils, changes into the well developed adult-type muscle with abundant myofibrils. Concomitant with these morphological alterations, there are changes in the protein constituents of muscle, including troponin T and myosin light chains. Premetamorphic larvae have large, round erythrocytes with small, round nuclei. These larval erythrocytes are replaced by smaller and elliptical adult-type erythrocytes during metamorphosis. The composition of hemoglobin also changes during this period. Additionally, the gastric glands develop, and pepsinogen is first produced during metamorphosis. Four cDNAs encoding thyroid hormone receptors (THRs) were cloned from a cDNA library constructed from whole bodies of metamorphosing flounder. Deduced amino acid sequences of these four genes show high homology of two with those of α-type THRs and the other two with β-type THRs of higher vertebrates.

Thyroid hormone regulates developmental changes in muscle during flounder metamorphosis

Morphological and biochemical changes in the muscular tissue of metamorphosing flounder were studied in relation to the regulatory role of thyroid hormone. Premetamorphic larvae were reared in seawater alone or seawater containing either thyroxine (T4) or an antithyroid drug (thiourea, TU). Histological changes in the muscle were examined and biochemical changes in the muscle proteins were evaluated by SDS-PAGE and immunoblotting for troponin T (TNT). The muscle tissue of premetamorphic larvae was characterized by abundant vacuoles and basophilic sarcoplasm. In control fish, the larval muscle transformed into the adult type during metamorphic climax; the fibers were filled with abundant myofibrils and the vacuoles disappeared. Analysis by SDS-PAGE showed that the bands at 41.5, 35.5, 34.0, 33.5, 25.5, 23.0, 20.0, and 19.0 kDa clearly increased in density from the climax stage. Premetamorphic larvae possessed two immunoreactive TNT isoforms of 41.5 and 34.0 kDa, the former being predominant. At the climax stage an additional isoform appeared at 33.5 kDa, and the 34.0- and 33.5-kDa TNT became predominant. The administration of T4 precociously induced these histological and biochemical changes in the muscle tissue of flounder larvae. In contrast, TU treatment inhibited these developmental changes in the larval muscle. Our results suggest that the developmental changes in the muscular tissue of metamorphosing flounder are regulated by thyroid hormone.

Retinoic acid stimulates development of adult‐type chromatophores in the flounder

Premetamorphic flounder larvae were administered different doses of 9-cis retinoic acid (9cRA). 9cRA at 25 nM (the highest dose) not only stimulated adult-type (ad-) chromatophore development on the ocular (eyed) side, but also induced the development of ad-chromatophores on the blind (non-eyed) side of the metamorphosed fish. The ad-chromatophore development was stimulated by 9cRA only when administered to the larvae that were at late premetamorphosis and at early prometamorphosis. Ad-chromatophores actually appear much later, at the end of metamorphosis. 9cRA was not effective at later stages of metamorphosis. These results suggest that 9cRA stimulated the development or determination of the developmental fate of neural crest cells for chromatophores. The present results also suggest the presence of immature chromatophores or neural crest cells on both sides of the larval body of the flounder and that the ad-chromatophore development is somehow inhibited on the blind side in spontaneous metamorphosis. All-trans retinoic acid (atRA) had a similar effect on the ad-chromatophore development. In addition, both types of RAs affected the development of fin rays of the fish, resulting in deformity of fins when administered at high doses early in metamorphosis. The teratogenic effect of atRA was greater than that of 9cRA. J. Exp. Zool. 284:317–324, 1999.

Molecular cloning and expression of progestin membrane receptor component 1 (Pgmrc1) of the giant tiger shrimp Penaeus monodon.

Knowledge on molecular mechanisms of steroid hormonal induction on oocyte development may lead to the possible ways to effectively induce ovarian maturation in shrimp. In this study, progestin membrane receptor component 1 (Pgmrc1) of the giant tiger shrimp (Penaeus monodon) initially identified by EST analysis was further characterized. The full-length cDNA of Pgmrc1 was 2015bp in length containing an ORF of 573bp corresponding to a polypeptide of 190 amino acids. Northern blot analysis revealed a single form of Pgmrc1 in ovaries of P. monodon. Quantitative real-time PCR indicated that the expression level of Pgmrc1 mRNA in ovaries of both intact and eyestalk-ablated broodstock was greater than that of juveniles (P<0.05). Pgmrc1 was up-regulated in mature (stage IV) ovaries of intact broodstock (P<0.05). Unilateral eyestalk ablation resulted in an earlier up-regulation of Pgmrc1 since the vitellogenic (II) ovarian stage. Moreover, the expression level of Pgmrc1 in vitellogenic, early cortical rod and mature (II-IV) ovaries of eyestalk-ablated broodstock was greater than that of the same ovarian stages in intact broodstock (P<0.05). Pgmrc1 mRNA was clearly localized in the cytoplasm of follicular cells, previtellogenic and early vitellogenic oocytes. Immunohistochemistry revealed the positive signals of the Pgmrc1 protein in the follicular layers and cell membrane of follicular cells and various stages of oocytes. Taken the information together, Pgmrc1 gene products seem to play the important role on ovarian development and may be used as the bioindicator for monitoring progression of oocyte maturation of P. monodon.