Alterations to maternal cortical and trabecular bone in multiparous middle-aged mice.

OBJECTIVES: During the reproductive cycle, altered calcium homeostasis is observed due to variable demand for mineral requirements. This results in increased bone resorption during the time period leading up to parturition and subsequent lactation. During lactation, women will lose 1-3% of bone mineral density per month, which is comparable to the loss experienced on an annual basis post-menopausal. The purpose of this study was to determine the effect of parity on bone formation in middle-aged mice. METHODS: Mice were mated and grouped by number of parity and compared with age matched nulliparous controls. Measurements were taken of femoral trabecular and cortical bone. Calcium, protein and alkaline phosphatase levels were also measured. RESULTS: An increase in trabecular bone mineral density was observed when comparing mice that had undergone parity once to the nulliparous control. An overall decrease in trabecular bone mineral density was observed as parity increased from 1 to 5 pregnancies. No alteration was seen in cortical bone formation. No difference was observed when calcium, protein and alkaline phosphatase levels were assessed. CONCLUSIONS: This study demonstrates that number of parity has an impact on trabecular bone formation in middle-aged mice, with substantial changes in bone density seen among the parous groups.

A fast-degrading thiol-acrylate based hydrogel for cranial regeneration.

Successful regeneration of the cranium in patients suffering from cranial bone defects is an integral step to restore craniofacial function. However, restoration of craniofacial structure has been challenging due to its complex geometry, limited donor site availability, and poor graft integration. To address these problems, we investigated the use of a thiol-acrylate hydrogel as a cell carrier to facilitate cranial regeneration. Thiol-acrylate hydrogels were formulated with 5-15 wt% poly(ethylene glycol)-diacrylate (PEGDA) and 1-9 mm dithiothreitol (DTT). The degradation rate, swelling ratio, and shear modulus of the resulting hydrogel were first characterized. Then, pre-osteoblast-like cells (MC3T3-E1) were encapsulated in the hydrogel and cultured for up to 21 d. Our results demonstrate that compared to samples formulated from 15 wt% PEGDA, 5 wt% PEGDA samples showed lower storage modulus at day 10 (0.7 kPa versus 8.3 kPa), 62.7% higher in weight change after soaking for 10 d. While the 5 wt% PEGDA group showed an 85% weight loss between day 10 and 21, the 15 wt% PEGDA group showed a 5% weight gain in the same time period. Cell viability with 15 wt% PEGDA and 5 mm DTT hydrogel decreased by 41.3% compared to 5 wt% PEGDA and 5mM DTT gel at day 7. However, histological analysis of cells after 21 d in culture revealed that they had pericellular mineral deposition indicating that the cells were differentiating into osteoblasts lineage in all experimental groups. This study shows that thiol-acrylate hydrogels can be tailored to achieve different degradation rates, in order to enhance cell viability and differentiation. Thus, the findings of this study provide a fundamental understanding for the application of thiol-acrylate hydrogels in cranial bone regeneration.

Muscle-bone interactions during fracture healing.

Although it is generally accepted that the rate and strength of fracture healing is intimately linked to the integrity of surrounding soft tissues, the contribution of muscle has largely been viewed as a vascular supply for oxygen and nutrient exchange. However, more is becoming known about the cellular and paracrine contributions of muscle to the fracture healing process. Research has shown that muscle is capable of supplying osteoprogenitor cells in cases where the periosteum is insufficient, and the muscular osteoprogenitors possess similar osteogenic potential to those derived from the periosteum. Muscle's secrotome includes proteins capable of inhibiting or enhancing osteogenesis and myogenesis following musculoskeletal injury and can be garnered for therapeutic use in patients with traumatic musculoskeletal injuries. In this review, we will highlight the current knowledge on muscle-bone interaction in the context of fracture healing as well as concisely present the current models to study such interactions.

Activated leukocyte cell adhesion molecule (ALCAM or CD166) modulates bone phenotype and hematopoiesis.

Activated Leukocyte Cell Adhesion Molecule (ALCAM/CD166), is expressed on osteoblasts (OB) and hematopoietic stem cells (HSC) residing in the hematopoietic niche, and may have important regulatory roles in bone formation. Because HSC numbers are reduced 77% in CD166(-/-) mice, we hypothesized that changes in bone phenotype and consequently the endosteal niche may partially be responsible for this alteration. Therefore, we investigated bone phenotype and OB function in CD166(-/-) mice. Although osteoclastic measures were not affected by loss of CD166, CD166(-/-) mice exhibited a modest increase in trabecular bone fraction (42%), and increases in osteoid deposition (72%), OB number (60%), and bone formation rate (152%). Cortical bone geometry was altered in CD166(-/-) mice resulting in up to 81% and 49% increases in stiffness and ultimate force, respectively. CD166(-/-) OB displayed elevated alkaline phosphatase (ALP) activity and mineralization, and increased mRNA expression of Fra 1, ALP, and osteocalcin. Overall, CD166(-/-) mice displayed modestly elevated trabecular bone volume fraction with increased OB numbers and deposition of osteoid, and increased OB differentiation in vitro, possibly suggesting more mature OB are secreting more osteoid. This may explain the decline in HSC number in vivo because immature OB are mainly responsible for hematopoiesis enhancing activity.

Beta-galactosidase detection as an indicator of endogenous PTHrP in cartilage.

Genetically altered mice are an important tool for biomedical research. Several transgenic mice have been created in which activation of the transgene results in production of beta-galactosidase that can be detected by histological means. While preservation and subsequent visualization of enzyme activity in soft tissues can be complicated, it is particularly difficult in bone specimens, especially those that have been decalcified. For these studies, we examined the bones of parathyroid hormone-related peptide (PTHrP) knock-in mice in which expression of PTHrP resulted in beta-galactosidase production. During the past decade, several studies have demonstrated the importance of PTHrP in bone. Thus, it is important to preserve and detect beta-galactosidase enzymatic activity in bone for these studies. We demonstrate here that beta-galactosidase was visualized better in slides with bone sections taken from PTHrP knock-in mice when bones were frozen and sectioned compared to bones that were embedded in plastic and sectioned using a microtome. Importantly, we were able to visualize beta-galactosidase in plastic embedded bones when specimens were fixed, stained (X-gal), embedded in plastic, and then sectioned rather than being fixed, embedded in plastic, sectioned, then stained.

Effects of long-term fixation on histological quality of undecalcified murine bones embedded in methylmethacrylate.

While long-term fixation and storage of specimens is common and useful for many research projects, it is particularly important for space flight investigations where samples may not be returned to Earth for several months (International Space Station) or years (manned mission to Mars). We examined two critical challenges of space flight experimentation: the effect of long-term fixation on the quality of mouse bone preservation and the preservation of antigens and enzymes for both histochemical and immunohistochemical analyses, and how the animal/sample processing affects the preservation. We show that long-term fixation minimally affects standard histological staining, but that enzyme histochemistry and immunolabeling are greatly compromised. Further, we demonstrate that whole animal preservation is not as suitable as whole leg or stripped leg preservation for long-term fixation and all histological analyses. Overall, we recommend whole leg processing for long-term storage of bone specimens in fixative prior to embedding in plastic for histological examination.

Loss of the transcription factor p45 NF-E2 results in a developmental arrest of megakaryocyte differentiation and the onset of a high bone mass phenotype.

NF-E2 is a transcription factor required for megakaryocyte differentiation. The phenotype of mice deficient in p45 NF-E2 has been characterized by increased numbers of immature megakaryocytes and the absence of functional platelets. These mice also exhibited a high bone mass phenotype with up to a 6-fold increase in trabecular bone volume and a 3- to 5-fold increase in the bone formation rate. Our data indicated that both osteoblast and osteoclast numbers were increased in vivo with a 4- to 10-fold increase in osteoblast number/tissue area and approximately a 5-fold increase in osteoclast number/tissue area. Serum osteocalcin levels were also increased in NF-E2-deficient mice, corroborating the histomorphometric data and confirming that the osteoblasts were functional. Urinary cross-links levels were measured to confirm osteoclast activity. Interestingly, the increased bone was observed only in bony sites of hematopoiesis, and was not seen in flat bones such as calvariae. We showed that cells of the osteoblast lineage do not express NF-E2 mRNA. The increased bone phenotype was adoptively transferred into irradiated wild-type mice using spleen cells from NF-E2-deficient mice. These observations suggest that a megakaryocyte-osteoblast interaction occurs which is anabolic for bone.

HistoChoice as an alternative to formalin fixation of undecalcified bone specimens.

We compared histochemical and immunohistochemical staining as well as fluorochrome labeling in murine bone specimens that were fixed with 10% neutral buffered formalin to those fixed with HistoChoice. We showed that sections from undecalcified tibiae fixed for 4 h in HistoChoice resulted in enhanced toluidine blue and Von Kossa histochemical staining compared to formalin fixation. HistoChoice produced comparable or improved staining for alkaline phosphatase. Acid phosphatase localization was better in formalin fixed specimens, but osteoclasts were visualized more easily in HistoChoice fixed specimens. As expected, immunohistochemical labeling was antibody dependent; some antibodies labeled better in HistoChoice fixed specimens while others were better in formalin fixed specimens. Toluidine blue, Von Kossa, and alkaline phosphatase staining of sections fixed for 12 h produced sections that were similar to 4 h fixed sections. Fixation for 12 h preserved acid phosphatase activity better. Increasing fixation to 12 h affected immunolocalization differentially. Bone sialoprotein labeling in HistoChoice fixed specimens was comparable to formalin fixed samples. On the other hand, after 12 h formalin fixation, osteocalcin labeling was comparable to HistoChoice. For most histochemical applications, fixing murine bone specimens for 4 h with HistoChoice yielded superior staining compared to formalin fixation. If immunohistochemical localization is desired, however, individual antibodies must be tested to determine which fixation process retains antigenicity better. In addition, there was no detectable difference in the intensity of fluorochrome labeling using either fixative. Finally, fixation duration did not alter the intensity of labeling.

Inflammation and bony changes at the temporomandibular joint.

Cytokines help mediate the acute and chronic inflammation and associated destruction of connective tissue in arthritic temporomandibular joints (TMJ). The proinflammatory cytokines TNFalpha, IL-1beta, IL-6, IL-8, and IFN-gamma are associated with inflammation in synovial joints and connective tissue destruction. Therefore, the increased levels of these cytokines in the synovial fluid of temporomandibular disorder (TMD) patients would be expected. Conversely, IL-1ra and IL-10 acts as inhibitors to these proinflammatory cytokines. Thus, in TMD patients, low levels of IL-1ra and IL-10 might be expected. A review of studies from multiple investigators confirms that proinflammatory cytokine levels increase in TMD patients, IL-1ra levels are also increased, and IL-10 levels remain unchanged. Because IL-10 can inhibit TNFalpha, IL-1, IL-6, and IL-8, the lack of IL-10 in the TMJ in the face of the other studies showing increases in TNFalpha, IL-1beta, IL-6, and IL-8 could partially explain the exacerbation of the associated osteoarthritis. In addition, although IL-1ra levels are elevated in most of the TMD patients, the increases do not appear to be sufficient to inhibit the inflammation and connective tissue degradation associated with IL-1beta. Thus, it appears that treatment of TMD requires a delicate balance between proinflammatory cytokines and cytokine inhibitors such as IL-1ra and IL-10.

Control of osteoclastogenesis and bone resorption by members of the TNF family of receptors and ligands.

Skeletal mass is maintained by a balance between cells which resorb bone (osteoclasts) and cells which form bone (osteoblasts). Bone development and growth is an on-going, life-long process. Bone is formed during embryonic life, grows rapidly through childhood, and peaks around 20 years of age (formation exceeds resorption). For humans the skeleton then enters a long period, approximately 40 years, when bone mass remains relatively stable. Skeletal turnover continues but the net effect of resorption and formation on bone mass is zero. For women this ends when they enter menopause and similar bone loss occurs for men, but later in life. These opposite functions are coupled, resorption precedes formation, and osteoblasts, or their precursors, stromal cells, regulate osteoclast formation and activity. Until recently, the molecular nature of this regulation, was poorly understood. However, recent observations have identified members of the TNF family of ligands and receptors as critical regulators of osteoclastogenesis. Osteoprotegerin (OPG) a decoy receptor was first identified. Its ligand, receptor activator of nuclear factor-kappaB ligand (RANKL), was quickly found, and shown to be expressed on stromal cells and osteoblasts. Its cognate receptor, RANK, was found to be expressed in high levels on osteoclast precursors. The interaction between RANKL and RANK was shown to be required for osteoclast formation. These observations have provided a molecular understanding of the coupling between osteoclastic bone resorption and osteoblastic bone formation. Moreover, they provide a framework on which to base a clear understanding of normal (e.g. postmenopausal osteoporosis and age associated bone loss) and pathologic skeletal changes (e.g. osteopetrosis, glucocorticoid-induced osteoporosis, periodontal disease, bone metastases, Paget's disease, hyperparathyroidism, and rheumatoid arthritis).

Autolysis of Escherichia coli and Bacillus subtilis cells in low gravity.

The role of gravity in the autolysis of Bacillus subtilis and Escherichia coli was studied by growing cells on Earth and in microgravity on Space Station Mir. Autolysis analysis was completed by examining the death phase or exponential decay of cells for approximately 4 months following the stationary phase. Consistent with published findings, the stationary-phase cell population was 170% and 90% higher in flight B. subtilis and E. coli cultures, respectively, than in ground cultures. Although both flight autolysis curves began at higher cell densities than control curves, the rate of autolysis in flight cultures was identical to that of their respective ground control rates.

Bacterial growth in space flight: logistic growth curve parameters for Escherichia coli and Bacillus subtilis.

Previous investigations have reported that bacterial suspension cultures grow to higher stationary concentrations in space flight than on Earth; however, none of these investigations included extensive ground controls under varied inertial conditions. This study includes extensive controls and cell-growth data taken at several times during lag phase, log phase, and stationary phase of Escherichia coli and Bacillus subtilis. The Marquardt-Levenberg, least-squares fitting algorithm was used to calculate kinetic growth parameters from the logistic bacterial growth equations for space-flight and control growth curves. Space-flight cultures grew to higher stationary-phase concentrations and had shorter lag-phase durations. Also, evidence was found for increased exponential growth rate in space.

Gentamicin: effect on E. coli in space.

Previous investigations have shown that liquid bacterial cultures grown in space flight were not killed as effectively by antibiotic treatments as were cultures grown on Earth. However, the cause for the decreased antibiotic effectiveness remains unknown. Possible explanations include modified cell proliferation and modified antibiotic transport in the culture medium. Escherichia coli cultures were grown in space flight (STS-69 and STS-73), with and without gentamicin, on a solid agar substrate thus eliminating fluid effects and reducing the unknowns associated with space-flight bacterial cultures in suspension. This research showed that E. coli cultures grown in flight on agar for 24 to 27 hours experienced a heightened growth compared to simultaneous controls. However, addition of gentamicin to the agar killed the bacteria such that both flight and ground control E. coli samples had similar final cell concentrations. Therefore, while the reported existence of a decrease in antibiotic effectiveness in liquid cultures remains unexplained, these data suggest that gentamicin in space flight was at least as effective as, if not more effective than, on Earth, when E. coli cells were grown on agar.

Effects of space flight and mixing on bacterial growth in low volume cultures.

Previous investigations have shown that liquid suspension bacterial cultures grow to higher cell concentrations in spaceflight than on Earth. None of these studies included ground-control experiments designed to evaluate the fluid effects potentially responsible for the reported increases. Therefore, the emphasis of this research was to both confirm differences in final cell concentration between 1g and microgravity cultures, and to examine the effects of mixing as a partial explanation for this difference. Flight experiments were performed in the Fluid Processing Apparatus (FPA), aboard Space Shuttle Missions STS-63 and STS-69, with simultaneous 1g static and agitated controls. Additional static 1g, agitated, and clino-rotated controls were performed in 9-ml culture tubes. This research revealed that both E. coli and B. subtilis samples cultured in space flight grew to higher final cell densities (120-345% increase) than simultaneous static 1g controls. The final cell concentration of E. coli cells cultured under agitation was 43% higher than in static 1g cultures and was 102% higher with clino-rotation. However, for B. subtilis cultures grown while being agitated on a shaker or clino-rotated, the final cell concentrations were nearly identical to those of the simultaneous static 1g controls. Therefore, these data suggest that the unique fluid quiescence in the microgravity environment (lack of sedimentation, creating unique transfer of nutrients and waste products), was responsible for the enhanced bacterial proliferation reported in this and other studies.

Low gravity and inertial effects on the growth of E. coli and B. subtilis in semi-solid media.

BACKGROUND: Several published experimental results have shown that cultures of suspended bacteria exhibit increased growth in the spaceflight environment. HYPOTHESIS AND METHODS: To test whether these differences were due to fluid mechanics and not cellular effects, E. coli and B. subtilis were grown on agar cultures under static, agitated, and rotated conditions in the laboratory, and under low-gravity conditions on four Space Shuttle flights. Growth experiments were terminated with glutaraldehyde, and individual cells were counted after quantitative elution from the agar. RESULTS: The spaceflight results, in conjunction with static, rotation, and agitation experiments indicate that E. coli and B. subtilis cultures on agar, unlike their suspension grown counterparts, do not experience heightened final cell concentration when the inertial environment is changed. CONCLUSIONS: This finding points to fluid dynamics and extracellular transport phenomena and not cellular dynamics as the most likely cause of previously reported increases in bacterial growth in microgravity.