Biology Reference
In-Depth Information
Kulkarni, S. S., & Buchholz, D. R. (2012). Beyond Synergy: Corticosterone and Thyroid
Hormone Have Numerous Interaction Effects on Gene Regulation in.
Xenopus tropicalis
Tadpoles.
Endocrinology
,
153
, 5309-5324.
Laudet, V. (2011). The origins and evolution of vertebrate metamorphosis.
Current Biology
,
21
, R726-R737.
Leonard, J. L., & Visser, T. J. (1986). Biochemistry of deiodination. In G. Hennemann (Ed.),
Thyroid hormone metabolism
(pp. 189-229). New York: Dekker.
Liang, V. C., Sedgwick, T., & Shi, Y. B. (1997). Characterization of the
Xenopus
homolog of
an immediate early gene associated with cell activation: Sequence analysis and regulation
of its expression by thyroid hormone during amphibian metamorphosis.
Cell Research
,
7
,
179-193.
Lindsay, R. H., Buettner, L., Wimberly, N., & Pittman, J. A. (1967). Effects of thyroxine
analogs on isolated tadpole tail tips.
General and Comparative Endocrinology
,
9
, 416-421.
Lorenz, C., Opitz, R., Lutz, I., & Kloas, W. (2009). Corticosteroids disrupt amphibian meta-
morphosis by complex modes of action including increased prolactin expression.
Com-
parative Biochemistry and Physiology. Toxicology & Pharmacology
,
150
, 314-321.
Macchi, I. A., & Phillips, J. G. (1966). In vitro effect of adrenocorticotropin on corticoid se-
cretion in the turtle, snake, and bullfrog.
General and Comparative Endocrinology
,
6
, 170-182.
Manzon, R. G., & Denver, R. J. (2004). Regulation of pituitary thyrotropin gene expression
during Xenopus metamorphosis: Negative feedback is functional throughout metamor-
phosis.
The Journal of Endocrinology
,
182
, 273-285.
Marsh-Armstrong, N., Huang, H. C., Remo, B. F., Liu, T. T., & Brown, D. D. (1999).
Asymmetric growth and development of the Xenopus laevis retina during metamorpho-
sis is controlled by type III deiodinase.
Neuron
,
24
, 871-878.
Mendel, C. M. (1989). The free hormone hypothesis: A physiologically based mathematical
model.
Endocrine Reviews
,
10
, 232-274.
Miranda, L. A., Affanni, J. M., & Paz, D. A. (2000). Corticotropin-releasing factor accelerates
metamorphosis in Bufo arenarum: Effect on pituitary ACTH and TSH cells.
The Journal
of Experimental Zoology
,
286
, 473-480.
Murata, T., & Yamauchi, K. (2005). Low-temperature arrest of the triiodothyronine-
dependent
transcription in Rana catesbeiana red blood cells.
Endocrinology
,
146
,
256-264.
Nieuwkoop, P. D., & Faber, J. (1956).
Normal table of
Xenopus laevis
Daudin.
Amsterdam:
North Holland Publishers.
Niinuma, K., Mamiya, N., Yamamoto, K., Iwamuro, S., Vaudry, H., & Kikuyama, S.
(1989). Plasma concentrations of aldosterone and prolactin in Bufo japonicus tadpoles
during metamorphosis.
Bulletin of Science and Engineering Research Laboratory, Waseda
University
,
122
, 17-21.
Niinuma, K., Yamamoto, K., & Kikuyama, S. (1991). Changes in plasma and pituitary pro-
lactin levels in yoad (
Bufo japonicus
) larvae during metamorphosis.
Zoological Science
,
8
,
97-101.
Niki, K., Yoshizato, K., & Kikuyama, S. (1981). Augmentation of nuclear binding capacity
for triiodothyronine by aldosterone in tadpole tail.
Proceedings of the Japan Academy. Series
B, Physical and Biological Sciences
,
57
, 271-275.
Norris, D. O., & Dent, J. N. (1989). Neuroendocrine aspects of amphibian metamorphosis.
In C. G. Scanes & M. P. Schreibman (Eds.),
Development, maturation and senescence of neu-
roendocrine systems: A comparative approach
(pp. 63-90). San Diego, CA: Academic Press.
Okada, R., Iwata, T., Kato, T., Kikuchi, M., Yamamoto, K., & Kikuyama, S. (2000). Clon-
ing of bullfrog thyroid-stimulating hormone (TSH) beta subunit cDNA: Expression of
TSH beta mRNA during metamorphosis.
General and Comparative Endocrinology
,
119
,
224-231.