Peripheral insulin resistance is early, progressive, and correlated with cachexia in Walker-256 tumor-bearing rats.

Insulin (INS) resistance is often found in cancer-bearing, but its correlation with cachexia development is not completely established. This study investigated the temporal sequence of the development of INS resistance and cachexia to establish the relationship between these factors in Walker-256 tumor-bearing rats (TB rats). INS hepatic sensitivity and INS resistance-inducing factors, such as free fatty acids (FFA) and tumor necrosis factor-α (TNF-α), were also evaluated. Studies were carried out on Days 2, 5, 8, and/or 12 after inoculation of tumor cells in rats. The peripheral INS sensitivity was assessed by the INS tolerance test and the INS hepatic sensitivity in in situ liver perfusion. TB rats with 5, 8, and 12 days of tumor, but not 2 days, showed decreased peripheral INS sensitivity (INS resistance), retroperitoneal fat, and body weight, compared to healthy rats, which were more pronounced on Day 12. Gastrocnemius muscle wasting was observed only on Day 12 of tumor. The peripheral INS resistance was significantly correlated (r = -.81) with weight loss. Liver INS sensitivity of TB rats with 2 and 5 days of tumor was unchanged, compared to healthy rats. TB rats with 12 days of tumor showed increased plasma FFA and increased TNF-α in retroperitoneal fat and liver, but not in the gastrocnemius, compared to healthy rats. In conclusion, peripheral INS resistance is early, starts along with fat and weight loss and before muscle wasting, progressive, and correlated with cachexia, suggesting that it may play an important role in the pathogenesis of the cachectic process in TB rats. Therefore, early correction of INS resistance may be a therapeutic approach to prevent and treat cancer cachexia.

New insight into the mechanisms associated with the rapid effect of T3 on AT1R expression.

The angiotensin II type 1 receptor (AT1R) is involved in the development of cardiac hypertrophy promoted by thyroid hormone. Recently, we demonstrated that triiodothyronine (T3) rapidly increases AT1R mRNA and protein levels in cardiomyocyte cultures. However, the molecular mechanisms responsible for these rapid events are not yet known. In this study, we investigated the T3 effect on AT1R mRNA polyadenylation in cultured cardiomyocytes as well as on the expression of microRNA-350 (miR-350), which targets AT1R mRNA. The transcriptional and translational actions mediated by T3 on AT1R levels were also assessed. The total content of ubiquitinated proteins in cardiomyocytes treated with T3 was investigated. Our data confirmed that T3 rapidly raised AT1R mRNA and protein levels, as assessed by real-time PCR and western blotting respectively. The use of inhibitors of mRNA and protein synthesis prevented the rapid increase in AT1R protein levels mediated by T3. In addition, T3 rapidly increased the poly-A tail length of the AT1R mRNA, as determined by rapid amplification of cDNA ends poly-A test, and decreased the content of ubiquitinated proteins in cardiomyocytes. On the other hand, T3 treatment increased miR-350 expression. In parallel with its transcriptional and translational effects on the AT1R, T3 exerted a rapid posttranscriptional action on AT1R mRNA polyadenylation, which might be contributing to increase transcript stability, as well as on translational efficiency, resulting to the rapid increase in AT1R mRNA expression and protein levels. Finally, these results show, for the first time, that T3 rapidly triggers distinct mechanisms, which might contribute to the regulation of AT1R levels in cardiomyocytes.

Thyroid hormone induction of actin polymerization in somatotrophs of hypothyroid rats: potential repercussions in growth hormone synthesis and secretion.

Thyroid hormone was shown to induce actin cytoskeleton polymerization in hypothyroid astrocytes and osteoblastic cells by a nongenomic mechanism. Polyadenylation of GH mRNA, a process that depends on cytoskeleton-associated proteins, was also shown to be regulated by thyroid hormone. Here we investigated by histochemistry and immunohistochemistry whether acute (100 microg per 100 g body weight, iv, for 30 min) or chronic (5 microg per 100 g body weight, ip, 5 d) administration of T3 to thyroidectomized (Tx) and sham-operated rats affects the somatotrophs F-actin cytoskeleton arrangement and its potential repercussion on GH synthesis and secretion. Thyroidectomy dramatically decreased the amount of somatotrophs F-actin content and induced the disassembly of the actin cytoskeleton. These effects were reversed by acute and chronic administration of T3. In addition, in Tx rat somatotrophs, GH labeling was detected mostly at the cell periphery. After 30 min of T3 administration, GH labeling decreased at periphery and increased in the perinuclear region, suggesting that GH secretion and synthesis were stimulated by T3. No differences were detected in the total actin protein content, although a decrease in the F- and increase in G-actin contents were detected in Tx rat pituitaries, a panorama that was reversed by acute T3 treatment, as shown by Western blotting analysis. The sham-operated animals' somatotrophs were only mildly affected by acute T3 administration. The results indicate that the T3-induced rapid alterations on somatotroph actin cytoskeleton and GH cellular distribution resulted from actin filaments rearrangement, which characterizes a nongenomic action.

Effect of neonatal hyperthyroidism on GH gene expression reprogramming and physiological repercussions in rat adulthood.

UNLABELLED: The neonatal period (NP) is a critical phase of the development in which the expression pattern of most genes is established. Thyroid hormones (TH) play a key role in this process and, alterations in its availability in the NP may lead to different patterns of gene expression, which might reflect in the permanent expression of several genes in the adulthood. GH gene expression in the pituitary is greatly dependent on TH in the early postnatal life; thus, modifications of thyroid state in NP might lead to alterations in GH gene expression as well as to physiological repercussions in the adult life. This study aimed to investigate this possibility by means of the induction of a neonatal hyperthyroidism in rats (4 mug of 3,5,3'-triiodo-l-thyronine (T3)/100 g body weight, s.c.) for 5, 15 or 30 days, and further evaluation of GH gene expression, as well as its physiological consequences in adult rats subjected to a transient hyperthyroidism in the first 30 days of life. GH mRNA level was shown to be increased in T3-treated rats for 5 days; when the treatment was extended to 15 or 30 days, the GH mRNA levels were similar to the control group. Moreover, rats treated with T3 for 30 days and killed when 90 days old, i.e., 60 days at the end of the T3 treatment, showed decreased GH mRNA content, body weight, bone mineral density, and lean body mass. IN CONCLUSION: (1) T3 effects on GH gene expression depend on the period of life in which the hyperthyroidism is set and on the length of T3 treatment in the NP and (2) transient neonatal hyperthyroidism leads to a lower GH mRNA expression in adult life accompanied by physiological repercussions indicative of GH deficiency.