10 citations found
Mol Cell Endocrinol 113 (2): 235-243 (1995)
Contrasting patterns of expression of thyroid hormone and retinoid
X receptor genes during hormonal manipulation of Xenopus tadpole tail regression
in culture.
Iwamuro S, Tata JR
Division of Developmental Biochemistry, National Institute for Medical
Research, Mill Hill, London, UK.
The precocious induction of amphibian metamorphosis is an ideal system
for analyzing the developmental action of TH, while the hormonal activation
of tadpole tail regression offers the further advantage of studying programmed
cell death. One of the striking features of thyroid hormone (TH)-induced
tail regression (as with morphogenetic responses of all tadpole tissues)
in Xenopus is the rapid autoinduction of TRbeta gene, but it is not known
how TH would affect the expression of the genes encoding TR's heterodimeric
partner, retinoid X receptor (RXR). Here we first show that the synthetic
glucocorticoid dexamethasone (Dex) potentiates and prolactin (PRL) suppresses,
3,3',5-triiodothyronine (T3)-induced regression of pre-metamorphic Xenopus
tadpole tails in organ culture. T3 strongly upregulated (11-35-fold) the
concentration of Xenopus TRbeta (xTRbeta) mRNA in these cultures while
downregulating by 50% that of Xenopus RXRgamma (xRXRgamma) mRNA in the
same samples of tail RNA. DEX and PRL enhanced or diminished the T3-regulated
expression of these two transcripts, respectively, which parallels their
other effects in whole tadpoles or cultured tails. The contrasting effects
of the three hormones on the steady-state levels of xTRbeta and XRXRgamma
mRNAs were time- and dose-dependent. T3 and DEX also strongly upregulated
the transcription of xTRbeta gene transfected into Xenopus XTC-2 cells
but PRL failed to prevent this autoinduction. The actions of these three
hormones involved in amphibian metamorphosis, as judged by the expression
of xTRbeta and xRXRgamma genes, reveal a new facet of hormonal interplay
underlying their developmental actions.
Gen Comp Endocrinol 99 (1): 28-34 (1995)
Development and application of a homologous radioimmunoassay for Xenopus
prolactin.
Yamamoto K, Yamashita K, Hayakawa Y, Hanaoka Y, Kikuyama S
Department of Biology, School of Education, Waseda University, Tokyo, Japan.
A specific and sensitive homologous radioimmunoassay (RIA) for Xenopus
prolactin (xPRL) was developed. PRL isolated from X. laevis pituitary glands
was used for generating antiserum in a rabbit, for radioligand and for
the standard. Pituitary homogenates and plasma from adult Xenopus produced
displacement curves parallel to the xPRL standard. Plasma from hypophysectomized
Xenopus showed negligible cross-reactivity. Purified PRLs from other amphibian
species such as the bullfrog (Rana catesbeiana) and toad (Bufo japonicus)
gave inhibition curves which did not parallel the standard. Ovine PRL,
mouse PRL, newt (Cynops pyrrhogaster) PRL, bullfrog GH, and bullfrog LH
showed no inhibition of binding even at relatively high doses in this RIA.
The sensitivity of the RIA was 0.122 +/- 0.005 ng xPRL/100 microliters
assay buffer. Intraassay and interassay coefficients of variation were
2.46 and 6.65%, respectively. Histological studies of Xenopus adenohypophyses
revealed that the cells which reacted immunologically with the antiserum
against xPRL corresponded to those positively stained with antiserum against
bullfrog PRL. A preliminary application of this homologous RIA for xPRL
was performed by evaluating plasma and pituitary PRL levels in subadult
and adult Xenopus of both sexes.
Biochem Cell Biol 72 (11-12): 581-588 (1994)
Hormonal regulation of programmed cell death during amphibian metamorphosis.
Tata JR
Division of Developmental Biochemistry, National Institute for Medical
Research, London, U.K.
Extensive programmed cell death (PCD) is initiated at the onset of amphibian
metamorphosis, resulting in 100% of cells dying in some larval tissues,
as during total regression of tail and gills. All cell death during metamorphosis
is under the control of thyroid hormone (TH), which can initiate the process
precociously in whole tadpoles or in individual tissues in culture. The
hormone prolactin (PRL), given exogenously, prevents natural and TH-induced
metamorphosis. We have exploited this dual hormonal regulation in premetamorphic
Xenopus tails in organ culture to identify and characterize early genes
that are TH-induced and considered important for initiating cell death.
Among the earliest genes activated by TH are those encoding the two thyroid
hormone receptors TR alpha and TR beta. This autoinduction of TR genes
is considered important since, in blocking this process, PRL also inhibited
the expression of other TH-inducible genes and prevented cell death. The
expression of early genes other than TR genes, which are known to promote
cell death or survival, is also considered to be important for the initiation
of PCD during amphibian metamorphosis. We are, therefore, working on the
identification, characterization, and expression of members of the Xenopus
bcl-2-like gene family, as well as other genes, such as nur-77 and ICE,
which may act as early genes during tadpole tail regression.
Biochimie 76 (3-4): 320-328 (1994)
Modulation of the biological activity of thyrotropin-releasing hormone
by alternate processing of pro-TRH.
Ladram A, Bulant M, Delfour A, Montagne JJ, Vaudry H, Nicolas P
Laboratoire de Bioactivation des Peptides, Institut Jacques Monod, Paris,
France.
Thyrotropin-releasing hormone prohormone contains multiple copies of TRH
linked together by connecting sequences. Like other plurifunctional prohormone
proteins, pro-TRH undergoes differential proteolytic processing in various
tissues to generate, beside authentic TRH, several other novel peptides
corresponding to C-terminally extended forms of TRH and connecting fragments.
The pro-TRH connecting peptides are, together with TRH, predominant storage
forms of TRH-precursor related peptides in the rat hypothalamus. Connecting
peptides are co-localized with TRH in the median eminence nerve endings
and co-released through a mechanism involving voltage-operated Ca2+ channels.
The connecting peptide Ps4 is involved in potentiation of the action of
TRH on thyrotropin hormone release by pituitary in vitro and in vivo through
interactions with a specific pituitary cell receptor coupled to dihydropyridine
and omega-connotoxin sensitive Ca2+ channels of the L-type. It also causes
dose-dependent increases in the steady state levels of mRNAs of TSH and
prolactin through stimulation of the respective gene promoter activities.
These findings indicate that Ps4 and TRH, two peptides which originate
from a single multifunctional biosynthetic precursor, can function on the
same target tissues in a coordinate manner to promote hormonal secretion.
This suggests that differential processing of the TRH prohormone may have
the potential to modulate the biological activities of TRH.
Gen Comp Endocrinol 91 (3): 307-317 (1993)
Isolation and characterization of two forms of Xenopus prolactin.
Yamashita K, Matsuda K, Hayashi H, Hanaoka Y, Tanaka S, Yamamoto K,
Kikuyama S
Department of Biology, School of Education, Waseda University, Tokyo, Japan.
Two forms of highly purified prolactin (PRL) were obtained from pituitary
glands of Xenopus laevis by extraction of acetone-dried powder with acid
acetone and high-performance liquid chromatography on anion exchange, gel
filtration, and reverse-phase columns. Purification was monitored by SDS-polyacrylamide
gel electrophoresis (SDS-PAGE) and Western blot analysis employing antiserum
against bullfrog PRL. The Xenopus prolactins (xPRL-I and xPRL-II) thus
obtained were shown to have similar molecular weights of 23,000 as determined
by SDS-PAGE. The isoelectric points of xPRL-I and xPRL-II determined by
isoelectric focusing were 5.6 and 5.3, respectively. Both hormones blocked
T4-induced shrinkage of Xenopus tadpole tail fin in vitro. The amino acid
compositions of the xPRLs resembled that of bullfrog PRL. The partial amino
acid sequences of xPRL-I and of xPRL-II showed 78 and 68% homology with
the comparable portion of the sequence of bullfrog PRL, respectively. Homology
between xPRL-I and xPRL-II was 90%.
Proc Natl Acad Sci U S A 90 (9): 3820-3824 (1993)
Expression of the Xenopus laevis prolactin and thyrotropin genes during
metamorphosis.
Buckbinder L, Brown DD
Department of Embryology, Carnegie Institution of Washington, Baltimore,
MD 21210.
The cDNAs encoding Xenopus laevis prolactin (PRL) and the alpha and beta
subunits of thyroid-stimulating hormone (TSH alpha and TSH beta, respectively)
have been cloned from a pituitary library. Results of developmental RNA
blot analysis contradict the long-held biological role for PRL as a juvenilizing
hormone in amphibia. The pituitary gland of a premetamorphic tadpole expresses
PRL mRNA at very low levels. The abundance of PRL mRNA increases late in
metamorphosis as a response to thyroid hormone (TH), suggesting that PRL
is more likely to have a function in the frog than in the tadpole. TSH
alpha and -beta mRNA levels increase through prometamorphosis; this rise
does not appear to be regulated directly by TH. At climax, both TH and
TSH mRNA levels drop. The sequential morphological changes that characterize
prometamorphosis depend upon the gradual increase of endogenous TH, which
peaks at climax. This increase in TH in turn depends upon the lack of a
traditional thyroid-pituitary negative-feedback loop throughout prometamorphosis.
Dev Biol 149 (2): 463-467 (1992)
Prolactin prevents the autoinduction of thyroid hormone receptor mRNAs
during amphibian metamorphosis.
Baker BS, Tata JR
National Institute for Medical Research, The Ridgeway, Mill Hill, London,
United Kingdom.
We have recently reported that prolactin (PRL) inhibits both morphogenesis
and cell death in thyroid hormone (T3)-induced amphibian metamorphosis
(Tata et al., 1991), and that the autoinduction of T3 receptor (TR alpha
and beta) mRNA is among the most rapid responses of premetamorphic Xenopus
tadpoles to T3 (Kawahara et al., 1991). We now demonstrate that PRL prevents
the rapid T3-induced upregulation of TR alpha and beta mRNAs in stages
50-54 Xenopus tadpoles and in organ cultures of tadpole tails. This effect
is followed by the inhibition of the de novo activation of 63-kDa keratin
gene by T3. We present an experimentally testable model whereby PRL exerts
its juvenilizing action by preventing the amplification of TR by its autoinduction
by T3.
Dev Biol 146 (1): 72-80 (1991)
Prolactin inhibits both thyroid hormone-induced morphogenesis and cell
death in cultured amphibian larval tissues.
Tata JR, Kawahara A, Baker BS
Laboratory of Developmental Biochemistry, National Institute for Medical
Research, Mill Hill, London, United Kingdom.
We describe for the first time the successful organ culture, in a serum-free
chemically defined medium, of hind limb buds from stage 54/55 Xenopus laevis
tadpoles in which 2 x 10(-9) M triiodothyronine (T3) precociously induces
morphogenesis to give rise to morphologically normal limbs within 7 days.
It was important to retain the mesenchymal tissue joining the two limb
buds in order to obtain limb development in culture. T3 added to tail explants
from the same larvae, cultured in parallel with limb buds, induced regression
and cell loss at rates comparable to those seen during T3-induced metamorphosis
in intact tadpoles. We also demonstrate for the first time that 0.2 units
of prolactin (PRL) added at the same time as 2 x 10(-9) M T3 totally blocked
both limb development and tail regression over 8 days in culture. When
added after T3 had initiated its metamorphic action. PRL arrested further
morphogenesis and regression of these two tissues, respectively. Retinoic
acid at 10(-7) M had only a marginal effect. Histological examination showed
that T3 added to limb buds produced normal chondrogenesis and osteogenesis
in vitro as well as skin, muscle, and digit formation, while it produced
a rapid and marked histolysis of fin and connective tissue of the tail.
The ease of hormonally manipulating both morphogenesis and cell death in
culture in opposite directions offers a simple, effective model system
for molecular analysis of mechanisms underlying hormone-regulated postembryonic
developmental processes.
Horm Behav 25 (2): 128-136 (1991)
Thyrotropin-releasing hormone facilitates display of reproductive behavior
and locomotor behavior in an amphibian.
Taylor JA, Boyd SK
Department of Biological Sciences, University of Notre Dame, Indiana 46556.
In the amphibian brain, thyrotropin-releasing hormone (TRH) is present
in many regions outside the hypothalamus. The functions of this extrahypothalamic
TRH however are unknown. We sought to determine whether TRH or its metabolites
altered reproductive behaviors (amplectic clasping behavior) or locomotor
behaviors of the male South African clawed frog, Xenopus laevis. TRH-injected
(100 micrograms; dorsal lymph sac injection) male Xenopus displayed significantly
fewer amplectic clasp attempts and longer clasp durations than saline-injected
controls. The TRH metabolites, TRH acid and histidylproline diketopiperazine,
similarly altered clasping behavior. Several hormones released by TRH,
including thyroid-stimulating hormone, melanocyte-stimulating hormone,
prolactin, and dopamine, had no significant effect on clasp frequency or
duration. Locomotor activity in Xenopus males was increased significantly
after 15 min following TRH injection (150 micrograms); this effect persisted
for at least 1 hr. The metabolites did not alter locomotion. These studies
indicate that TRH can facilitate the display of two behaviors in the South
African clawed frog. Effects of TRH on locomotor and reproductive behaviors
thus appear in several vertebrate classes. These behavioral actions of
TRH likely occur through different mechanisms or at different sites.
Gen Comp Endocrinol 77 (2): 202-211 (1990)
Gonadal hormones inhibit the induction of metamorphosis by thyroid
hormones in Xenopus laevis tadpoles in vivo, but not in vitro.
Gray KM, Janssens PA
Department of Zoology, Australian National University, Canberra, ACT.
Although the major hormones controlling amphibian metamorphosis are those
of the thyroid, other hormones, notably prolactin and the adrenal steroids,
modulate the effects of thyroid hormones (TH). Some authors report that
the gonadal steroids stimulate the metamorphic actions of TH whereas others
report inhibition. The aims of the present study were to determine the
effects of gonadal steroids on TH-induced metamorphosis in Xenopus laevis
and to determine the site of action of these steroids. In all cases, hormones
were added to the water in which the tadpoles were swimming. The gonadal
steroids, testosterone and 17 beta-estradiol, inhibited triiodothyronine
(T3)-induced metamorphosis in living, premetamorphic tadpoles of X. laevis.
Both steroids, at 3.4 microM, prevented the reduction in body weight and
the shrinkage of head and alimentary canal brought about by 1 nM T3. In
contrast, 3.4 microM corticosterone stimulated T3-induced metamorphosis.
Addition of 100 nM T3 to the medium induced a large reduction in size of
X. laevis tails cultured in vitro. The antagonistic effects of testosterone
were not reproduced in such cultures, whereas the synergistic action of
corticosterone was maintained. Testosterone had no effect upon the specific
binding of T3 to X. laevis tail tissue, whereas corticosterone increased
such binding. These findings indicate that, while corticosterone stimulates
the metamorphic actions of T3 by acting directly in the peripheral tissues,
the gonadal steroids, particularly testosterone, inhibit T3 by acting at
a more central site. Prolactin is known to antagonize the metamorphic actions
of T3 and one such central action could be the stimulation of prolactin
synthesis. However, testosterone inhibited the prometamorphic actions of
bromocriptine, which stimulates metamorphosis by inhibiting production
of prolactin. Thus the central action of testosterone is unlikely to be
a stimulation of prolactin production.