Thyroxine and the development of the tibia in the embryonic chick

Maternal environment and craniofacial growth: geometric morphometric analysis of mandibular shape changes with in utero thyroxine overexposure in mice

An estimated 3% of US pregnancies are affected by maternal thyroid dysfunction, with between one and three of every 1000 pregnancies being complicated by overactive maternal thyroid levels. Excess thyroid hormones are linked to neurological impairment and excessive craniofacial variation, affecting both endochondral and intramembranous bone. Using a geometric morphometric approach, this study evaluates the role of in utero thyroxine overexposure on the growth of offspring mandibles in a sample of 241 mice. Canonical variate analysis utilized 16 unilateral mandibular landmarks obtained from 3D micro-computed tomography to assess shape changes between unexposed controls (n = 63) and exposed mice (n = 178). By evaluating shape changes in the mandible among three age groups (15, 20 and 25 days postnatal) and different dosage levels (low, medium and high), this study found that excess maternal thyroxine alters offspring mandibular shape in both age- and dosage-dependent manners. Group differences in overall shape were significant (P < 0.001), and showed major changes in regions of the mandible associated with muscle attachment (coronoid process, gonial angle) and regions of growth largely governed by articulation with the cranial base (condyle) and occlusion (alveolus). These results compliment recent studies demonstrating that maternal thyroxine levels can alter the cranial base and cranial vault of offspring, contributing to a better understanding of both normal and abnormal mandibular development, as well as the medical implications of craniofacial growth and development.

Skeletal advance and arrest in giant non-metamorphosing African clawed frog tadpoles (Xenopus laevis: Daudin)

This study examines the skeletons of giant non-metamorphosing (GNM) Xenopus laevis tadpoles, which arrest their development indefinitely before metamorphosis, and grow to excessively large sizes in the absence of detectable thyroid glands. Cartilage growth is isometric; however, chondrocyte size is smaller in GNM tadpoles than in controls. Most cartilages stain weakly with alcian blue, and several cartilages are calcified (unlike controls). However, cartilages subjacent to periosteum-derived bone retain strong affinities for alcian blue, indicating a role for periosteum-derived bone in the retention of glycosaminoglycans during protracted larval growth. Bone formation in the head, limb, and axial skeletons is advanced in comparison with stage-matched controls, but arrests at various mid-metamorphic states. Both dermal and periosteum-derived bones grow to disproportionately large sizes in comparison to controls. Additionally, mature monocuspid teeth form in several GNM tadpoles. Advances in skeletal development are attributable to the old ages and large sizes of these tadpoles, and reveal unexpected developmental potentials of the pre-metamorphic skeleton.

Thyroid hormone interacts with the Wnt/beta-catenin signaling pathway in the terminal differentiation of growth plate chondrocytes

Thyroid hormone activates Wnt-4 expression and Wnt/beta-catenin signaling in rat growth plate chondrocytes. Wnt antagonists Frzb/sFRP3 and Dkk1 inhibit T3-induced Wnt/beta-catenin activation and inhibit the maturation-promoting effects of T3 in growth plate cells. This study indicates that thyroid hormone regulates terminal differentiation of growth plate chondrocytes in part through modulating Wnt/beta-catenin signaling.

INTRODUCTION

Thyroid hormone is a potent regulator of skeletal maturation in the growth plate, yet the molecular mechanisms underlying this profound effect remain unknown. Wnt signaling has recently been recognized as an important signal transduction pathway in regulating chondrogenesis and terminal differentiation of growth plate chondrocytes. The objective of this study was to explore the interaction between the thyroid hormone and Wnt signaling pathways in the growth plate.

MATERIALS AND METHODS

Rat epiphyseal chondrocytes were maintained in 3D pellet culture and treated with triiodothyronine (T3). Activation of Wnt/beta-catenin signaling pathway in response to T3 was detected by measurement of the expression of Wnt-4 mRNA, the cellular accumulation of beta-catenin, the transcriptional activity of TCF/LEF, and the expression of the Wnt/beta-catenin responsive gene Runx2/cbfa1. Terminal differentiation of the chondrocytes was assessed by measurement of alkaline phosphatase enzymatic activity and Col10a1 gene expression.

RESULTS

Thyroid hormone treatment of growth plate chondrocytes upregulated both Wnt-4 mRNA and protein expression, increased cellular accumulation of stabilized beta-catenin, increased TCF/LEF transcriptional activity, and stimulated the expression of the Runx2/cbfa1 gene. Overexpression of either Wnt-4 or a stabilized form of beta-catenin promoted growth plate chondrocyte terminal differentiation. Blocking Wnt ligand/receptor interactions with the secreted Wnt antagonists Frzb/sFRP3 or Dkk1 inhibited these T3-induced increases in beta-catenin accumulation and Runx2 gene expression and inhibited the maturation-promoting effects of T3 in growth plate cells.

CONCLUSIONS

These data suggest that thyroid hormone regulates terminal differentiation of growth plate chondrocytes in part through modulating canonical Wnt/beta-catenin signaling.

Peroxisome proliferator activated receptor-gamma (PPARgamma) represses thyroid hormone signaling in growth plate chondrocytes

Peroxisome proliferator activated receptors (PPARs) are DNA-binding nuclear hormone receptors that are upregulated in response to high fat diets. PPARs are structurally related to the type II nuclear receptors, including the thyroid hormone receptors (TRs). To investigate if PPARs modulate TR-mediated terminal differentiation of growth plate chondrocytes, primary cultures of epiphyseal chondrocytes transiently transfected with TRalpha and PPARgamma expression vectors were treated with the PPAR ligands ciglitazone or troglitazone. Forced overexpression of PPARgamma decreased TRalpha1-mediated transcriptional activity and suppressed T3-induced increases in alkaline phosphatase activity and type X collagen expression. Similar effects were observed when the cells were treated with the PPARgamma activator ciglitazone or troglitazone. Overexpression of retinoid X receptor-alpha (RXRalpha) partially restored not only the inhibition of transcriptional activation by PPARgamma but also T3-induced hypertrophic differentiation. These data demonstrate that activation of PPARgamma signaling by either addition of PPARgamma ligands or overexpression of PPARgamma in growth plate chondrocytes inhibits TR-mediated gene transcription and inhibits the biological effects of thyroid hormone on terminal differentiation. The molecular mechanism involved in this inhibition appears to be competition between PPARgamma and TRalpha for limiting amounts of the heterodimeric partner RXR.

Physiology and pathophysiology of the growth plate

Longitudinal growth of the skeleton is a result of endochondral ossification that occurs at the growth plate. Through a sequential process of cell proliferation, extracellular matrix synthesis, cellular hypertrophy, matrix mineralization, vascular invasion, and eventually apoptosis, the cartilage model is continually replaced by bone as length increases. The regulation of longitudinal growth at the growth plate occurs generally through the intimate interaction of circulating systemic hormones and locally produced peptide growth factors, the net result of which is to trigger changes in gene expression by growth plate chondrocytes. This review highlights recent advances in genetics and cell biology that are illuminating the important regulatory mechanisms governing the structure and biology of the growth plate, and provides selected examples of how studies of human mutations have yielded a wealth of new knowledge regarding the normal biology and pathophysiology of growth plate cartilage.

Expression of cyclin-dependent kinase inhibitors in epiphyseal chondrocytes induced to terminally differentiate with thyroid hormone

A growing body of evidence suggests that systemic hormones and peptide growth factors may exert their effects on cell growth and differentiation in part through regulation of the cell division cycle. We hypothesized that thyroid hormone regulates terminal differentiation of growth plate chondrocytes in part through controlling cell cycle progression at the G1/S restriction point. Our results support this hypothesis by demonstrating that treatment of epiphyseal chondrocytes with thyroid hormone under chemically defined conditions results in the arrest of DNA synthesis and the onset of terminal differentiation, indicating that thyroid hormone is one factor capable of regulating the transition between cell growth and differentiation in these cells. This terminal differentiation process is associated with induction of the cyclin/cyclin-dependent kinase inhibitors p21(cip-1 waf-1) and p27kip1, suggesting that thyroid hormone may regulate terminal differentiation in part by arresting cell cycle progression through induction of cyclin-dependent kinase inhibitors.

Expression of thyroid hormone receptor isoforms in rat growth plate cartilage in vivo

Although thyroid hormone has been known for many years to be a potent regulator of skeletal maturation in vivo, it has not definitively been determined whether this effect is a result of a direct or indirect action of the hormone. Previous in vivo studies have suggested that thyroid hormone may stimulate longitudinal bone growth by increasing the secretion of growth hormone; however, growth hormone alone is unable to stimulate cartilage maturation. There are also indications that thyroid hormone is able to act directly on growth plate chondrocytes through growth hormone-independent mechanisms. In this study, we demonstrate that rat growth plate chondrocytes in vivo express genes encoding three of the four isoforms of the thyroid hormone receptors described to date, but the corresponding protein can only be detected for the TRalpha1 and TRbeta1 isoforms of the receptor. As has been noted in other tissues, there is generally poor correlation between the mRNA levels for each isoform and the relative amount of corresponding protein as measured by immunoblotting, suggesting the possibility that receptor expression may be regulated by post-transcriptional mechanisms.

Growth hormone and insulin-like growth factors in poultry growth: required, optimal, or ineffective?

With a continually expanding market for poultry meat products, increased production demands of as much as 50% by the Year 2000 have been predicted. Indications already exist that this magnitude of expansion is not likely to be met by increased production output and genetic selection alone, and that other methods of improving growth performance per bird via exogenous manipulation of the growth process are needed. Studies in mammalian species clearly demonstrate the importance of growth hormone (GH) and its potential for enhancing productivity in domestic mammals. However, the role of GH in growth of poultry appears to be much more complex. Taken collectively, studies to date indicate that significant, positive effects of GH on growth performance of normal, growing poultry are possible. Expression of such effects appear to be largely contingent on the period of posthatch development (late posthatch being more responsive than early), and the pattern of several key metabolic regulatory hormones resulting in response to GH. Such regulatory hormone responses are largely influenced by the pattern or magnitude of exposure (acute versus chronic) to GH in birds. At this time, the available information on the potential for insulin-like growth factors to enhance growth is limited, and further studies are needed before a definitive role for these peptides in growth and development of poultry can be assigned.

Cartilage sulfation inhibitor from rat liver curtails growth of embryonic chicken cartilage in vitro

We studied the effect of high MW cartilage sulfation (somatomedin) inhibitors from rat liver on cartilage growth in vitro. Pelvic rudiments from 11-day-old chicken embryos (5.70 mg average weight) were incubated in an organ-culture system with defined tissue-culture medium; after two days (T0-2), media were changed and incubation continued for another three days (T2-5). Normal rat serum (10% vol/vol) stimulated cartilage growth (weight change + 1.33 +/- 0.16 mg, mean +/- SEM T0-2 and + 1.33 +/- 0.27 mg, T2-5). Partially purified cartilage sulfation inhibitors (CSI) caused a weight decrease (-1.09 +/- 0.17 mg T0-2 and -0.44 +/- 0.06 mg T2-5). Adding inhibitors to cartilage incubations containing normal serum abolished the growth-promoting effect of serum (-0.79 +/- 0.07 mg T0-2 and -0.40 +/- 0.08 mg T2-5). The growth-curtailing effect of CSI was reversible; after preincubating cartilage with CSI for two days (-0.62 +/- 0.11 mg T0-2), subsequently exposing it to normal serum allowed cartilage growth to resume (+1.02 +/- 0.21 mg T2-5). Cartilages incubated with normal serum and various concentrations of inhibitor exhibited a dose-dependent inhibition of serum-stimulated growth. Cartilage Length was not altered by the inhibitor; cartilage dry:wet weight ratio or protein concentration (microgram/mg wet weight) did not differ among groups. Triodothyronine (T3) stimulated cartilage growth in a dose-dependent manner as expected. Adding CSI to cartilage incubations containing T3 (1.5 nmol/l or 15 nmol/L) completely abolished the growth-stimulating effect of T3.(ABSTRACT TRUNCATED AT 250 WORDS)

Thyroidal influence on body growth

This review of thyroid influence on body growth in poultry is organized around the following parameters of growth: increase in body weight and skeletal size, muscle growth, and growth of cartilage and bone. The greatest effect of goitrogens on growth of embryos occurs during late embryogenesis at a time when normal thyroid hormone levels are increasing. Posthatching growth is reduced in severely hypothyroid animals, and body weight gain is affected more than bone growth. Thyroid hormone replacement restores body growth of thyroidectomized chickens, but supplemental hormone in normal animals has no beneficial effect on growth. Excessive T3 (fed at 1 ppm) is detrimental to growth and feed efficiency. No clear correlation between thyroid hormone concentration and growth rate of normal chickens has been identified. Growth depression in sex-linked dwarf birds is at least partially reversed by supplemental T3. Muscle growth is reduced in goitrogen-treated chickens and the growth reduction is reversed by supplemental thyroxine. Total DNA accumulation is reduced in hypothyroid chickens, but muscle mass relative to DNA content is normal following long-term treatment; this suggests some regulation of muscle mass relative to DNA content. T3 increases the number of muscle fiber nuclei in hypothyroid chickens and the uptake of 3H-thymidine into nuclei within the basal lamina. T3 directly stimulates growth and maturation of embryonic chick cartilage and enhances the in vitro action of somatomedins on cartilage growth. There is little information concerning the role of the thyroid in posthatching cartilage and bone growth in poultry.

Analysis of cartilage differentiation from skeletal muscle grown on bone matrix. III. Environmental regulation of glycosaminoglycan and proteoglycan synthesis

The ability of numerous nutritional and topographic factors to influence differentiation of embryonic mesenchyme has given rise to several theories which attempt to explain the development of muscle and cartilage from these similar-appearing cells. Some theories are challenged by the observation that a substratum of demineralized bone is capable of supporting the transformation of skeletal muscle into cartilage in vitro and that the potential to form cartilage still resides within cloned myoblasts and fibroblasts of skeletal muscle. In the present study, culture media CMRL-1066, minimal essential medium (MEM), and F-12 provide varied nutritional environments and are tested for their ability to support the morphological and biochemical transformation of skeletal muscle into cartilage. Morphologically, CMRL-1066 reproducibly supports hyaline cartilage formation, whereas MEM does so in only one out of three explants onto demineralized bone, and F-12 is incapable of supporting formation of a hyaline matrix. Biochemically, each medium is sufficient to elicit synthesis of cartilage-like patterns of sulfated glycosaminoglycans and proteoglycan monomer. Synthesis of hyaluronic acid (HA) initially increases in explants grown in CMRL-1066, but decreases prior to chondrogenesis. MEM elicits a similar increase in HA synthesis, but the subsequent decrease is not as rapid. In F-12, synthesis remains depressed throughout the experiment. The data show that increases in HA synthesis occur concurrent with the appearance of fibroblast-like cells, which normally precede chondroblasts. Decreases in HA synthesis correlate well with the onset of chondrogenesis. Explants grown in CMRL-1066 reproducibly from cartilage and synthesize the greatest amounts of proteoglycan aggregate. Those grown in MEM form cartilage infrequently, synthesize reduced amounts of proteoglycan aggregate-like material, and contain greater amounts of HA, of low molecular weight. The data demonstrate that chondrogenesis can be subtly regulated by environmental factors, and such factors regulate both the morphological and biochemical expression of the phenotype through HA synthesis.

Triiodothyronine stimulates maturation of porcine growth-plate cartilage in vitro

We studied the effect of triiodothyronine (T3) on mammalian growth-plate cartilage in vitro. Growth-plate cartilages from fetal pigs scapulae were incubated for 3 to 7 d in serum-free medium alone or medium containing T3. Alkaline phosphatase activity, a marker of hypertrophied chondrocytes, was increased in T3 (10 nM)-treated growth-plate cartilage 152 +/- 36% above that of cartilage incubated in medium alone after 3 d of incubation, and 324 +/- 47% after 7 d of incubation. There was a dose-response increase in alkaline phosphatase activity to T3 over the range of 0.01-10 nM. The rise in alkaline phosphatase activity was specific for T3 since growth-plate cartilage alkaline phosphatase activity was not increased by cortisol, insulin, parathyroid hormone, or 5% fetal calf serum. Histological studies of growth-plate cartilage showed that T3 in a concentration-dependent manner increased the width of the zone of maturation (hypertrophied chondrocytes). Histochemical staining for alkaline phosphatase activity demonstrated that T3 caused the recruitment of new cells into the zone of maturation. T3 also stimulated incorporation of L-[3H]leucine into protein and 35SO4 into proteoglycan in growth-plate cartilage. In contrast, T3 did not increase alkaline phosphatase activity or radiolabeled precursor incorporation into nongrowth-plate scapular cartilage. These studies demonstrate that T3 directly stimulates maturation and, to a lesser degree, growth-related processes in fetal mammalian growth-plate cartilage.