Age-related reduction in bone matrix protein mRNA expression in rat bone tissues: application of histomorphometry to in situ hybridization

Effects of high phosphorus diet on bone metabolism-related gene expression in young and aged mice

In this study, the effects of high phosphorus (P) diet on bone metabolism-related gene expression were investigated in young and aged mice. Twelve- and 80-week-old ddY male mice were divided into two groups, respectively, and fed a control diet containing 0.3% P or a high P diet containing 1.2% P. After 4 weeks of treatment, serum parathyroid hormone (PTH) concentration was significantly higher in the high P groups than in the control groups in both young and aged mice and was significantly higher in aged mice than in young mice fed the high P diet. High P diet significantly increased receptor activator of NF-κB ligand (RANKL) mRNA in the femur of both young and aged mice and significantly increased the RANKL/osteoprotegerin (OPG) mRNA ratio only in aged mice. High P diet significantly increased mRNA expression of transient receptor potential vanilloid type 6, calbindin-D9k, and plasma membrane Ca(2+)-ATPase 1b in the duodenum of both young and aged mice. These results suggest that high P diet increased RANKL mRNA expression in the femur and calcium absorption-related gene expression in the duodenum regardless of age. Furthermore, the high P diet-induced increase in PTH secretion might increase the RANKL/OPG mRNA ratio in aged mice.

Aging and bone

Bones provide mechanical and protective function, while also serving as housing for marrow and a site for regulation of calcium ion homeostasis. The properties of bones do not remain constant with age; rather, they change throughout life, in some cases improving in function, but in others, function deteriorates. Here we review the modifications in the mechanical function and shape of bones, the bone cells, the matrix they produce, and the mineral that is deposited on this matrix, while presenting recent theories about the factors leading to these changes.

Dynamics of the transition from osteoblast to osteocyte

Osteocytes are derived from osteoblasts and make up over 90% of the cells in bone. However, the mechanisms that control the differentiation of osteoblasts into osteocytes embedded in bone matrix are not well understood. With the recent developments of transgenic models for manipulating gene expression in osteocytes and of transgenic mice carrying lineage reporters for osteoblasts and osteocytes, unprecedented new insights are becoming possible. In this article we review recent advances, such as comparative gene and protein expression studies, that are delineating the changes in gene and protein expression that accompany osteocyte differentiation. We also review recent studies in which time-lapse dynamic imaging approaches have been used to visualize osteoblast and osteocyte populations within bone. These approaches reveal the key role of cell motility in bone cell function and highlight the dynamic nature of mineralized tissues. Changes in motile properties of the cell may be key in the transition from osteoblast to osteocyte, as reflected in the altered expression of many molecules involved in cytoskeletal function.

Osteoclasts prefer aged bone

We investigated whether the age of the bones endogenously exerts control over the bone resorption ability of the osteoclasts, and found that osteoclasts preferentially develop and resorb bone on aged bone. These findings indicate that the bone matrix itself plays a role in targeted remodeling of aged bones.

INTRODUCTION

Osteoclasts resorb aging bone in order to repair damage and maintain the quality of bone. The mechanism behind the targeting of aged bone for remodeling is not clear. We investigated whether bones endogenously possess the ability to control osteoclastic resorption.

METHODS

To biochemically distinguish aged and young bones; we measured the ratio between the age-isomerized betaCTX fragment and the non-isomerized alphaCTX fragment. By measurement of TRACP activity, CTX release, number of TRACP positive cells and pit area/pit number, we evaluated osteoclastogenesis as well as osteoclast resorption on aged and young bones.

RESULTS

We found that the alphaCTX/betaCTX ratio is 3:1 in young compared to aged bones, and we found that both alpha and betaCTX are released by osteoclasts during resorption. Osteoclastogenesis was augmented on aged compared to young bones, and the difference was enhanced under low serum conditions. We found that mature osteoclasts resorb more on aged than on young bone, despite unchanged adhesion and morphology.

CONCLUSIONS

These data indicate that the age of the bone plays an important role in controlling osteoclast-mediated resorption, with significantly higher levels of osteoclast differentiation and resorption on aged bones when compared to young bones.

The function of connexin 43 on the differentiation of rat bone marrow cells in culture

Connexin (Cx) 43-mediated gap-junctional intercellular communication (GJC) mainly regulates the osteoblastic differentiation, but much of the function of Cx43 on the differentiation of bone marrow cells is unclear. This study is aimed to clarify relationship between the differentiation of rat bone marrow cells and the function of Cx43. Bone marrow cells derived from four-week-old Wistar strain rats were grown in the presence and absence of 18-alpha-glycyrrhetinic acid (AGA, 100 muM) to inhibit Cx43-mediated GJC. Expression of Cx43 gene and protein, and the level of intracellular cyclic adenosine monophosphate (cAMP) were determined as the assessment of the function in Cx43-mediated GJC, and alkaline phosphatase (ALP) activity and mineralization were measured as the assessment of osteoblastic differentiation. The Cx43 gene expression was first observed at 2 days, but under the condition in which rat bone marrow cells were treated with AGA, there was no significant effect on the Cx43 gene expression. By administrating AGA to rat bone marrow cells, all parameters of maturation but the Cx43 gene expression significantly decreased. The results of this experiment suggest that Cx43-mediated GJC plays a critical role in rat bone marrow cells, progress toward maturation.

Lifetime high calcium intake increases osteoporotic fracture risk in old age

Caloric restriction prolongs life span. Calcium restriction may preserve bone health. In osteoporosis, bone mineral density (BMD) has significantly decreased, due to a lack of osteoblast bone formation. Traditional osteoporosis prevention is aimed at maximizing BMD, but the lifetime effects of continuously maintaining a high BMD on eventual bone health in old age, have not been studied. Strikingly, in countries with a high mean BMD, fracture rates in the elderly are significantly higher than in countries with a low mean BMD. Studies show that this is not based on genetic differences. Also, in primary hyperparathyroidism, on the brink of osteoporosis, BMD levels may be significantly higher than normal. Maybe, BMD does not represent long term bone health, but merely momentary bone strength. And maybe, maintaining a high BMD might actually wear out bone health. Since osteoporosis particularly occurs in the elderly, and because in osteoporotic bone less osteoblasts are available, the underlying process may have to do with ageing of osteoblastic cells. In healthy subjects, osteoblastic bone cells respond to the influx of calcium by composing a matrix upon which calcium precipitates. In the process of creating this matrix, 50-70% of the involved osteoblasts die. The greater the influx of calcium, the greater osteoblast activity, and the greater osteoblast apoptosis rate. An increased osteoblast apoptosis rate leads to a decrease in the age-related osteoblast replicative capacity (ARORC). In comparison to healthy bone, in osteoporotic bone the decrease in the replicative capacity of osteoblastic cells is greater. Due to the eventual resulting lack of osteoblast activity, micro-fractures cannot be repaired. Continuously maintaining a high BMD comes with continuously high bone remodeling rates, which regionally exhaust the ARORC, eventually leading to irreparable microfractures. Regarding long time influences on bone health, adequate estrogen levels are known to be protective against osteoporosis. This is generally attributed to its inhibiting influence on osteoclast activity. Instead, its net effects on osteoblast metabolism may be the key to osteoporosis prevention. Adequate estrogen levels inhibit osteoblast activity, calcium apposition and osteoblast apoptosis rate, preserving the ARORC.

CONCLUSION

Regarding osteoporosis prevention, ARORC better than BMD represents bone health. Regarding ARORC, adequate estrogen levels are protective, opposing the similar effects of hyperparathyroidism and a high calcium diet. Tests need to be performed in mice to assess the lifetime effects of a high versus a low calcium diet, on eventual bone fracture toughness.

Age-related changes on bone regeneration in midpalatal suture during maxillary expansion in the rat

The purpose of the present study was to investigate age-related changes in bone regeneration during expansion of a midpalatal suture in rats. When the midpalatal suture was expanded for 7 days in rats of four different ages (6, 15, 24, and 52 weeks), it was found to have significantly widened in all groups by the analysis of a histomorphometric method. The expansion-induced widening of the suture was similar in 6, 15, and 24-week-old rats but was significantly less in 52-week-old rats. When the newly mineralized bone area and the osteoid area along the suture in all groups were quantified, newly mineralized bone area in all expansion groups significantly increased compared with corresponding controls, but expansion-induced newly mineralized bone area decreased in an age-dependent manner. Osteoid area also significantly increased by expansion, but expansion-induced osteoid area unexpectedly increased with age up to the 24-week-old rats. In the expansion-induced total bone area (expansion-induced newly mineralized bone area plus osteoid area), there was no significant difference among 6, 15, and 24-week-old rats, but it was markedly decreased in 52-week-old rats. Alkaline phosphatase activity in the suture strongly increased in all expansion groups, whereas increase in the rate of alkaline phosphatase activity clearly was less in 24 and 52-week-old rats. These results suggested that the difficulty of rapid-palatal expansion in 52-week-old rats and age-related decrease in bone regeneration after expansion of the suture within 24-week-old rats may be caused by decrease in mineralization of the bone matrix. Therefore, midpalatal suture can expand even in the cases exceeding the pubertal growth period, but more time may be necessary for mineralized bone to regenerate in the suture.

The mature osteoblast phenotype is characterized by extensive plasticity

While both morphological and biochemical-molecular attributes demarcate differentiation stages in specific cell and tissue types, what constitutes necessary and sufficient expression to define particular cell types is not always known. For example, mature osteoblasts (OBs) are defined morphologically as the cuboidal, biosynthetically active, basophilic cells residing on bone surfaces and responsible for the deposition of osteoid matrix. However, several recent observations suggest that not all mature OBs are identical. To explore further the validity of the hypothesis that heterogeneity of phenotype exists among mature OBs, we grew fetal rat calvaria cells in vitro at low density under conditions in which bone nodules form and mineralize in isolation of other contaminating cell and colony types. Cells resident in mature OB colonies, i.e., those comprising mainly cuboidal cells associated with an osteoid matrix that had begun to mineralize, were analyzed in situ for protein expression by immunocytochemistry with antibodies against collagen type I, alkaline phosphatase, osteopontin, bone sialoprotein, and osteocalcin. Consistent with the expected phenotype of mature OBs, many OBs expressed high levels of all of these markers, but strikingly even adjacent morphologically indistinguishable cuboidal OBs had differences in protein expression, especially in relation to osteopontin, bone sialoprotein, and osteocalcin expression. Double-labeling with Hoechst 33258 and osteocalcin indicated that the variation in antibody labeling intensity/protein expression appeared independent of a variation in cell cycle. To further ascertain the extent of this heterogeneity, 20 single cells were micromanipulated from colonies and subjected to poly(A)-PCR to analyze the simultaneous coexpression profiles of the same five markers analyzed by immunocytochemistry and two other markers, the OB-osteocyte transition marker E11 and the parathyroid hormone/parathyroid hormone-related protein receptor. Notably, the repertoire of genes expressed and their levels of expression varied markedly in individual OBs. The observed heterogeneity suggests that the mature OB phenotype is not a single unique phenotype but rather encompasses a flexible pattern of expression from the repertoire of OB-associated markers.