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Diabetes Interferes with the Bone Formation by Affecting the Expression of Transcription Factors that Regulate Osteoblast Differentiation

Department of Periodontology and Oral Biology (H.L., D.K., D.T.G.), Boston University School of Dental Medicine, and Department of Orthopaedic Surgery (L.C.G.), Boston Medical Center, Boston, Massachusetts 02118

Address all correspondence and requests for reprints to: Dr. Dana T. Graves, Boston University School of Dental Medicine, Suite W-202D, 700 Albany Street, Boston, Massachusetts 02118. E-mail: dgraves{at}bu.edu.

	Abstract

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Type 1 diabetes in humans has as one of its complications inadequate bone formation, resulting in osteopenia and delayed fracture healing. To investigate the mechanisms by which diabetes affects bone formation, experiments were performed in a marrow ablation model. Mice were made diabetic by multiple low-dose streptozotocin treatment, and controls were treated with vehicle alone. Killing occurred 0, 2, 4, 6, 10, and 16 d following marrow ablation. Histologic analysis demonstrated that the amount of immature mesenchymal tissue was equivalent in both the experimental and control groups on d 4. On d 6 a burst of bone formation occurred in the control group that was significantly reduced in the diabetic group. This deficit was evident at the molecular level as shown by diminished expression of osteocalcin, collagen types I. When transcription factors were examined, core-binding factor 1 (Cbfa1)/runt domain factor-2 (Runx-2) and human homolog of the drosophila distal-less gene (Dlx5) expression were substantially reduced in the diabetic, compared with control, groups on d 4 and 6. C-fos but not c-jun expression was also suppressed in the diabetic group but not closely linked to bone formation. Insulin treatment substantially reversed the effect of diabetes on the expression of bone matrix osteocalcin and collagen type I and transcription factors Cbfa1/Runx2 and Dlx5. These results indicate that diabetic animals produce sufficient amounts of immature mesenchymal tissue but fail to adequately express genes that regulate osteoblast differentiation, Cbfa1/Runx-2 and Dlx5, which in turn, leads to decreased bone formation.

	Introduction

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IN HUMANS, TYPE 1 DIABETES is associated with a decrease in skeletal mass and delayed healing of fractures (1, 2, 3). Diabetic patients exhibit reduced bone mineral density as measured by dual x-ray absorptiometry at the lumbar spine and proximal femur (4). In a 12-yr prospective study, bone formation was shown to be reduced in diabetic humans, suggesting that they have diminished osteoblast activity, compared with normal individuals (5).

Insight into the mechanisms of diabetes-associated delays in fracture healing comes largely from studies using animal models. Several of models of type 1 diabetes have shown reduced bone turnover impaired fracture repair as measured biomechanically by torque to failure and deficits in mineralization (6, 7, 8). In streptozotocin-induced diabetic rats, abnormal bone repair was shown to be insulin dependent because the deficient osseous healing was reversed by insulin treatment (9). This finding demonstrates a specific cause and effect relationship between inadequate insulin production and abnormal bone formation. The production of matrix proteins was also diminished as demonstrated by findings that the fracture callus in diabetic animals exhibited a 60–70% reduction in the production of type X collagen during the endochondral period of bone formation, compared with normal animals (6). A number of mechanisms have been proposed for bone abnormalities in diabetics. Diminished expression of IGF-1 or basic fibroblast growth factor may contribute to reduced production of bone matrix, and the increased brittleness of diabetic bone may be due to abnormalities in microarchitecture (10, 11, 12, 13).

Diabetes can be induced in mice by multiple low doses of streptozotocin (MLD-STZ). This is an improvement over the high-dose streptozotocin model because it more closely replicates the cellular events involved in the destruction of the insulin-producing cells in the pancreas and altered glucose transporter 2 expression (14). Although there is a component of mild toxicity of streptozotocin to pancreatic ß-cells, reports indicate that activation of the immune system plays a central role in the mechanism by which MLD-STZ treatment results in destruction of pancreatic ß-cells (15, 16). The resulting diabetes therefore has many similarities to type 1 human diabetes and is characterized by mild to moderate hyperglycemia, glucosuria, polyphagia, hypoinsulinemia, hyperlipidemia, and weight loss. Streptozotocin-induced diabetic animals also exhibit many of the complications observed in human diabetes including enhanced susceptibility to infection and cardiovascular disease, retinopathy, alterations in angiogenesis, delayed wound healing, diminished growth factor expression, and reduced bone formation (16, 17). These studies indicate that streptozotocin-induced diabetes in mice serve as a useful model to study mechanisms related to wound healing in general and osseous healing specifically. Most significantly, both MLD-STZ-induced diabetes and human type 1 diabetes develop similar features of osteopenia.

Bone formation can be investigated in a number of different model systems. Recently, the marrow ablation model has been used to investigate mechanisms by which growth factors and differentiation factors modulate intramembranous bone formation (18, 19, 20). In this model the marrow cavity of the diaphyseal portion of the tibia is disrupted by gently removing trabecular bone and marrow. Over a 10-d period, there is a predictable and synchronized series of events that include the removal of the hematoma that forms immediately after ablation; formation of immature mesenchymal tissue; differentiation of osteoblasts; and production of a bone matrix, which peaks on d 6. At 10 d and beyond, bone resorption occurs so that the marrow is reconstituted to its original form. During this later period of remodeling, coupled bone formation occurs, thus providing an excellent model system to study both nascent bone formation in response to injury and formation during a resorptive cycle. This system, unlike fracture repair, however, does not involve an endochondral component.

	Materials and Methods

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CD-1 mice (Charles River Laboratories, Inc., Wilmington, MA) were treated with streptozotocin (40 µg/1 g body weight) in 10 mM citrate buffer or 10 mM citrate buffer alone by ip injection daily for 5 d. Mice were considered to be diabetic when blood glucose levels exceeded 250 mg/dl. Marrow ablation of the tibia was performed after mice were diabetic for 12–14 d.

Insulin treatment
Additional experiments were carried out in streptozotocin-induced diabetic mice with and without insulin treatment. Insulin treatment was initiated when blood glucose levels exceeded 200 mg/dl. Mice were treated with Linbit insulin implants (LinShin Canada, Inc., Scarborough, Ontario, Canada) that release a controlled amount of insulin or identical pellets without insulin. Insulin-treated animals had blood glucose levels that were generally 100 mg/dl after insertion of insulin implants. Marrow ablation was then performed as described above when the diabetic group had glucose levels that exceeded 250 mg/dl for 2 wk. Blood glycosylated hemoglobin levels were measured at the time of death using a Glyco-Affinn GHb test (Perkin-Elmer Life Sciences, Norton, OH).

Marrow ablation of the tibia
An oblique incision was made over the patellar ligament and tibial tuberosity of the right and left leg. The tibial tuberosity through patellar ligament was punctured with a small endodontic file (Dentsply International, York, PA). The marrow and trabecular bone was gently removed by careful filing, and the marrow cavity was rinsed with sterile saline. The incision was closed with 5–0 silk sutures. At the indicated time points, mice were euthanized by CO₂ inhalation. One tibia from each animal was randomly assigned to histologic analysis and the other for mRNA analysis.

Histology
At the time of euthanasia, the tibia and distal femur were fixed in 4% paraformaldehyde in PBS at 4 C. Specimens were decalcified in Immunocal (Decal Chemical Corp., Congers, NY) and embedded in paraffin. Sagittal 5- to 6-µm sections were cut and stained with hematoxylin and eosin. Histologic analysis was carried out on sections from three to six animals per data point. Measurements were made starting approximately 1 mm from the patellar surface and included five to seven fields at magnification of x20. The percent area of each field containing mesenchymal connective tissue, bone matrix, and bone marrow was assessed. One-way ANOVA was performed to establish statistically significant differences between the experimental and control groups at the P less than 0.05 level.

RNA analysis
At the time of euthanasia, the tibial bone was harvested from the proximal metaphysis to the tibiofibular junction excluding all cartilaginous and soft tissues. Tibiae were snap frozen in liquid nitrogen, pulverized, and three to six specimens combined for each ribonuclease (RNase) protection assay. Total RNA was extracted with Trizol (Life Technologies, Inc., Rockville, MD), and the concentration and integrity of the extracted RNA was verified by denaturing agarose gel electrophoresis. Gene expression was measured by the RNase protection assay. ³²P-Labeled riboprobes were incubated with 2 µg total RNA for matrix gene expression and 12 µg for transcription factor gene expression. Samples were then subjected to RNase digestion using a kit from PharMingen (BD Biosciences, Franklin Lakes, NJ) according to the manufacturer’s instructions. Following electrophoresis on a 6% polyacrylamide gel, radiolabeled bands were visualized with a PhosphorImager (BioRad Laboratories, Hercules, CA). The OD of the protected bands was measured with Image ProPlus software (Media Cybernetics, Silver Spring, MD), which was then normalized by the value of glyceraldehyde-3-phosphate dehydrogenase (GAPDH) in the same lane. To show changes relative to baseline, the value for the zero time point was subtracted from each of the subsequent time points. Two to four separate RNase protection assays were performed for expression of each gene with similar results.

	Results

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The initial event after marrow ablation was hematoma formation, which was present throughout the area of the marrow ablation on d 2 (Fig. 1). The cells of the hematoma became necrotic or were replaced by immature mesenchymal tissue by d 4. By d 6 much of the immature mesenchymal tissue was replaced by newly formed bone. Between d 6 and d 10, the formation of marrow elements was initiated, and the area of new bone matrix was reduced. Remodeling of the bone marrow continued from d 10–16.

View larger version (103K): [in this window] [in a new window]   Figure 1. Histologic changes following marrow ablation. Marrow ablation was performed in normal mice as described in Materials and Methods. Mice were killed at the indicated time points. Paraffin-embedded sections were stained with hematoxylin and eosin. Original magnification, x100 (left panels) or x200 (right panels).

View larger version (15K): [in this window] [in a new window]   Figure 2. Histomorphometric analysis of marrow ablation specimens. Marrow ablation was performed on diabetic or control mice, and sections were prepared as described in Fig. 1. The percent of each field containing connective tissue (A), bone (B), or bone marrow (C) was assessed at magnification of x200. Each value represents the mean ± SEM. *, Values in which the control group was significantly different from the diabetic group (P < 0.05).

Osteocalcin is a bone-specific matrix protein. Its expression was strongly induced on d 4 and 6 in the control mice and to a much lesser extent in diabetic animals (Fig. 3A). Moreover, the difference between the two groups was in the level of expression rather than the time frame in which expression occurred. For collagen type 1 mRNA, high levels in the control group were detected on d 2, peaked on d 4, and were expressed at lower levels on d 6 and 10 (Fig. 3B). The largest difference between the diabetic and normal group occurred on d 4.

View larger version (26K): [in this window] [in a new window]   Figure 3. Osteocalcin and collagen type 1 expression are reduced in diabetic mice during bone formation. Marrow ablation was performed on diabetic and normal mice as described in Fig. 1. The expression of osteocalcin and collagen type 11 was assessed at each time point by RNase protection assay. The densitometric value of each band was obtained using image analysis software and normalized by the value for GAPDH in the same lane. The PhosphorImage is shown with densitometric analysis below. A, Osteocalcin; B, collagen type 1.

View larger version (23K): [in this window] [in a new window]   Figure 4. The expression of transcription factors Dlx5 and Cbfa1/Runx-2 are reduced in diabetic mice during bone formation. Marrow ablation was performed on diabetic and normal mice as described in Fig. 1. The expression of Dlx5 and Cbfa1/Runx-2 were assessed at each time point by RNase protection assay. The densitometric value of each was obtained using image analysis software and normalized by the value for GAPDH in the same lane. The PhosphorImage is shown with densitometric analysis below. A, Dlx5; B, Cbfa1/Runx-2.

View larger version (24K): [in this window] [in a new window]   Figure 5. The expression of c-fos and c-jun in diabetic and control mice during bone formation. Marrow ablation was performed on diabetic and normal mice as described in Fig. 1. The expression of c-fos and c-jun was assessed at each time point by RNase protection assay. The densitometric value of each was obtained using image analysis software and normalized by the value for GAPDH in the same lane. The PhosphorImage is shown with densitometric analysis below. A, c-fos; B, c-jun.

View larger version (18K): [in this window] [in a new window]   Figure 6. The decrease in osteocalcin and collagen type 1 expression in diabetic mice is reversed with insulin treatment during bone formation. Marrow ablation was performed on insulin-treated and nontreated diabetic mice as described in Fig. 1. The expression of osteocalcin and collagen type 11 was assessed at each time point by RNase protection assay. The densitometric value of each was obtained using image analysis software and was normalized by the value for GAPDH in the same lane. The PhosphorImage is shown with densitometric analysis below. A, Osteocalcin; B, collagen type 1.

View larger version (19K): [in this window] [in a new window]   Figure 7. The decrease in transcription factors Dlx5 and Cbfa1/Runx-2 expression in diabetic mice is reversed with insulin treatment during bone formation. Marrow ablation was performed on insulin-treated and nontreated diabetic mice as described in Fig. 1. The expression of Dlx5 and Cbfa1/Runx-2 were assessed at each time point by RNase protection assay. The densitometric value of each was obtained using image analysis software and was normalized by the value for GAPDH in the same lane. The PhosphorImage is shown with densitometric analysis below. A, Dlx5; B, Cbfa1/Runx-2.

	Discussion

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Of the matrix proteins examined, osteocalcin is specifically restricted to bone. In the control group, its expression occurred above baseline levels on d 4 and 6. Expression on d 4 represents a point at which osteoblast differentiation has occurred, but osteoid matrix has not yet accumulated. On d 6 there is abundant bone matrix present and the continued expression of osteocalcin. The difference between the expression of osteocalcin in the diabetic and control groups was striking. The levels in the diabetic group were substantially reduced, but there was no delay in the onset of osteocalcin expression.

Although diabetic mice produced less bone than their normal counterparts, they did produce a similar amount of immature mesenchymal tissue. When the expression of Dlx5 and Cbfa1/Runx-2 were examined, high levels were induced on d 4 in the control but not the diabetic group. Given the importance of Cbfa1/Runx-2 in osteoblast differentiation, its diminished expression in the diabetic group is likely to be a critical event in explaining the reduced formation of bone observed histologically. Thus, diabetic individuals may have reduced Cbfa1/Runx-2 expression that may lead to a reduction in osteoblast differentiation, which in turn may reduce the expression of bone-matrix genes and limit production of new bone. It is striking that the expression of these osteoblast-regulating transcription factors was not delayed so much as diminished in the diabetic state. At later time points (d 10 and 16), Cbfa1/Runx-2 expression was clearly detected in both the control and experimental groups, although at lower levels than those found during peak bone formation. This likely is due to bone formation associated with remodeling that occurs beyond d 6 in the ablation model.

Collagen type I is found in immature mesenchymal tissue, the stromal lining of bone and bone matrix. Collagen type 1 was expressed at relatively high levels from d 2 to 10 reflecting its expression in these various tissues. A similar temporal pattern of collagen expression has been previously reported following marrow ablation of rat tibia (18). The control and diabetic groups exhibited a substantial difference in the level of mRNA for collagen type I on the day that it peaked in the wild-type group. Thus, diabetic animals failed to exhibit the same burst of collagen type 1 gene expression. Interestingly, in a similar marrow ablation model, aged rats experienced reduced but not delayed expression of osteocalcin, collagen type 1 and IGF-1, compared with young rats (25, 26). This suggests that there are phenotypic similarities in diminished bone production associated with aging and diabetes.

In the ablation model, the proliferation of mesenchymal cells occurs between d 2 and 4, and the reconstitution of marrow elements and hematopoiesis is initiated by d 6 and continues to d 16. Both c-fos and c-jun form dimers and are members of the activator protein-1 family of transcriptional regulators. These transcription factors are expressed at high levels during proliferation of preosteoblastic cells during the early stages of osteoblast differentiation, induced by bone morphogenetic proteins, and involved in hematopoiesis (27, 28, 29). The similarity of c-jun and c-fos expression in diabetic and control mice at d 2 and 4 are consistent with the equal production of immature mesenchymal tissue containing preosteoblasts. However, on d 6, c-fos expression was considerably higher in the control than diabetic group, but this difference was not observed for c-jun. Thus, c-fos expression may be related to the production of bone matrix.

In summary, the osseous healing that takes place following marrow ablation results in a burst of cellular activity that involves the induction of transcription factors that regulate osteoblast differentiation, the expression of matrix proteins and the formation of an organized matrix. In diabetic mice the sharp up-regulation of Dlx5 and Cbfa1/Runx-2 is attenuated with the results being a deficiency in conversion of immature mesenchymal cells to mature osteoblasts. This agrees well with the histologic evidence for diminished bone formation during this period.

	Footnotes

 
This work was supported by Grant DE-07559 from the National Institute of Dental and Craniofacial Research.

Abbreviations: Cbfa1, Core-binding factor 1; Dlx5, human homolog of the drosophila distal-less gene; GAPDH, glyceraldehyde-3-phosphate dehydrogenase; MLD-STZ, multiple low doses of streptozotocin; RNase, ribonuclease; Runx-2, runt domain factor-2.

Received January 22, 2002.

Accepted for publication September 19, 2002.

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