Effects of methylprednisolone on bone mineral density and microarchitecture of trabecular bones in rats with administration time and assessed by micro-computed tomography

BACKGROUND

Little research exists on the dynamic effects of glucocorticoids on bone mineral density (BMD) and microarchitecture of trabecular bones of rats assessed by micro-computed tomography (micro-CT).

PURPOSE

To investigate time-related changes in the BMD and microarchitecture of trabeculae in rats exposed to glucocorticoid.

MATERIAL AND METHODS

Female Sprague-Dawley rats were recruited into a baseline group, glucocorticoid-treated groups, or control groups. Glucocorticoid-treated rats were given daily subcutaneous injections of methylprednisolone at a dosage of 3.5 mg/kg for 1 or 9 weeks. A high-resolution micro-CT was used to identify the densitometric and microarchitectural properties of trabeculae in both the proximal metaphysis of tibiae and the sixth lumbar vertebrae (L6).

RESULTS

Compared with baseline rats, volumetric BMD, tissue BMD, bone volume fraction, trabecular number, and degree of anisotropy of trabeculae from tibiae or L6 increased in control rats and glucocorticoid-treated rats with time; however, changes in the latter group were smaller. Compared with control rats at each time point, a decrease occurred in volumetric BMD, tissue BMD, bone volume fraction, trabecular number, degree of anisotropy, and trabecular connectivity density in trabecular bones from tibiae or L6 in glucocorticoid-treated rats. The decrease was greater in week 9 compared to week 1. Contrarily, an increase was noted in trabecular thickness, trabecular separation, and structure model index in glucocorticoid-treated rats. A time-related analysis within glucocorticoid-treated groups in both skeletal regions showed a decline in bone volume fraction, trabecular connectivity density, trabecular number, and degree of anisotropy with time, but trabecular thickness and trabecular separation were elevated.

CONCLUSION

Methylprednisolone can inhibit bone mineralization and bone mass gain with growth in rats. It can also deteriorate microarchitecture of trabeculae in a time-dependent or an accumulative dose-dependent manner. Further, the remaining trabeculae appear to thicken in order to adapt to altered stress.

Regionally specific compensation for bone loss in the tibial trabeculae of estrogen-deficient rats

BACKGROUND

Bone mineral density (BMD) and microstructural variations have been extensively investigated in recent years; however, the compensation for bone loss between different regions is still unclear.

PURPOSE

To fully characterize regional variations in bone mineral density (BMD) as well as the microstructure and dynamic changes of rat tibial trabeculae that occur with bone loss associated with estrogen deficiency.

MATERIAL AND METHODS

Female Sprague-Dawley rats were ovariectomized (OVX), sham-operated (sham), or left unoperated (baseline control). The left tibiae were harvested at baseline, and at postoperative weeks 3 and 15. High-resolution micro-computed tomography (microCT) was used to identify the densitometric and microstructural properties of trabeculae in the proximal ends of the rat tibia, specifically the epiphysis and metaphysis.

RESULTS

Volumetric BMDs at the organ (organ BMD) and tissue (tissue BMD) levels were significantly higher for trabeculae at the epiphysis than metaphysis. Moreover, trabeculae at the epiphysis were thicker, and fewer in number and connectivity than those at the metaphysis, which were more rod like. Trabeculae at the metaphysis were more susceptible to bone loss induced by estrogen deprivation than at the epiphysis, and the regions varied greatly in their adaptation to this loss. At the metaphysis, trabecular tissue BMD and thickness were unexpectedly higher at postoperative week 15 than week 3 or baseline. In contrast, at the epiphysis, tissue BMD did not change with time, but trabecular thickness significantly increased at week 15 compared to baseline and was also greater in OVX compared to sham rats.

CONCLUSION

Metaphyseal and epiphyseal trabeculae show regionally specific variations in BMD and microstructure. The former are more susceptible to bone loss induced by estrogen deficiency and would be strengthened by either hypertrophy or hypermineralization, while epiphyseal trabeculae are mainly strengthened by thickening.

Effects of tyrosine-->phenylalanine mutations on auto- and trans-phosphorylation reactions catalyzed by the insulin receptor beta-subunit cytoplasmic domain

Activation of the insulin receptor kinase is closely associated with autophosphorylation of several tyrosine residues in the cytoplasmic domain of the receptor's two beta-subunits. To determine the contribution of these tyrosine phosphorylations to autoactivation of the receptor kinase, we have blocked phosphorylation at specific tyrosine by replacing these tyrosine residues, individually and in combination, with phenylalanine in a soluble 45-kD analog of the cytoplasmic insulin receptor kinase domain (CIRK). Kinetic studies of auto- and transphosphorylation with this panel of mutated CIRKs indicate that: (i) None of the tyrosines (953, 960, 1,146, 1,150, 1,151, 1,316, or 1,322) are necessary for catalysis: all single Y-->F mutants retain the ability to autoactivate comparable to the parent CIRK. (ii) Two of the tyrosine autophosphorylation sites, either tyrosine 1,150 or 1,151, contribute most (70-80%) of the autoactivation, because replacement of these two tyrosines by phenylalanine was the minimal change that abolishes autoactivation. (iii) A mutant CIRK having all seven reported tyrosine phosphorylation sites replaced by phenylalanine retained basal kinase activity but was incapable of autoactivation. These findings imply that autoactivation can occur without phosphorylation having occurred at any single site (953, 960, 1,146, 1,150, 1,151, 1,316, or 1,322), and autophosphorylation need not follow an ordered, sequential pathway beginning, for example, at tyrosine 1,146 as proposed for the intact insulin receptor.

Activation of PI 3-kinase in 3T3-L1 adipocytes by association with insulin receptor substrate-1

Insulin treatment of adipocytes causes the rapid phosphorylation of the insulin receptor substrate-1 (IRS-1) on tyrosine. The phosphotyrosine [Tyr(P)] form of IRS-1 then complexes with the enzyme phosphatidylinositol (PI) 3-kinase. In this study, we have investigated the effect of this association on PI 3-kinase activity in 3T3-L1 adipocytes. Insulin stimulated cytosolic PI 3-kinase activity about sevenfold. This stimulation was maximal after 1 min of exposure of cells to insulin, persisted for at least 1 h, and occurred over the range of insulin concentrations that saturate its receptor. By means of immunoprecipitation of IRS-1, it was shown that virtually all of the enhanced activity was due to PI 3-kinase complexed with IRS-1. Moreover, the purified Tyr(P) form of IRS-1, either isolated from 3T3-L1 adipocytes or obtained by phosphorylation of the recombinant protein with the insulin receptor, markedly stimulated the activity of purified rat liver PI 3-kinase. These results show that the association of Tyr(P) IRS-1 with PI 3-kinase activates the enzyme and thereby can explain the elevation of PI 3,4-bisphosphate and PI 3,4,5-trisphosphate in vivo observed upon treatment of adipocytes with insulin.