Modeled microgravity and hindlimb unloading sensitize osteoclast precursors to RANKL-mediated osteoclastogenesis.

Mechanical forces are essential to maintain skeletal integrity, and microgravity exposure leads to bone loss. The underlying molecular mechanisms leading to the changes in osteoblasts and osteoclast differentiation and function remain to be fully elucidated. Because of the infrequency of spaceflights and payload constraints, establishing in vitro and in vivo systems that mimic microgravity conditions becomes necessary. We have established a simulated microgravity (modeled microgravity, MMG) system to study the changes induced in osteoclast precursors. We observed that MMG, on its own, was unable to induce osteoclastogenesis of osteoclast precursors; however, 24 h of MMG activates osteoclastogenesis-related signaling molecules ERK, p38, PLCγ2, and NFATc1. Receptor activator of NFkB ligand (RANKL) (with or without M-CSF) stimulation for 3-4 days in gravity of cells that had been exposed to MMG for 24 h enhanced the formation of very large tartrate-resistant acid phosphatase (TRAP)-positive multinucleated (>30 nuclei) osteoclasts accompanied by an upregulation of the osteoclast marker genes TRAP and cathepsin K. To validate the in vitro system, we studied the hindlimb unloading (HLU) system using BALB/c mice and observed a decrease in BMD of femurs and a loss of 3D microstructure of both cortical and trabecular bone as determined by micro-CT. There was a marked stimulation of osteoclastogenesis as determined by the total number of TRAP-positive multinucleated osteoclasts formed and also an increase in RANKL-stimulated osteoclastogenesis from precursors removed from the tibias of mice after 28 days of HLU. In contrast to earlier reported findings, we did not observe any histomorphometric changes in the bone formation parameters. Thus, the foregoing observations indicate that microgravity sensitizes osteoclast precursors for increased differentiation. The in vitro model system described here is potentially a valid system for testing drugs for preventing microgravity-induced bone loss by targeting the molecular events occurring in microgravity-induced enhanced osteoclastogenesis.

Replacement, Refinement, and Reduction in Animal Studies With Biohazardous Agents.

Animal models are critical to the advancement of our knowledge of infectious disease pathogenesis, diagnostics, therapeutics, and prevention strategies. The use of animal models requires thoughtful consideration for their well-being, as infections can significantly impact the general health of an animal and impair their welfare. Application of the 3Rs-replacement, refinement, and reduction-to animal models using biohazardous agents can improve the scientific merit and animal welfare. Replacement of animal models can use in vitro techniques such as cell culture systems, mathematical models, and engineered tissues or invertebrate animal hosts such as amoeba, worms, fruit flies, and cockroaches. Refinements can use a variety of techniques to more closely monitor the course of disease. These include the use of biomarkers, body temperature, behavioral observations, and clinical scoring systems. Reduction is possible using advanced technologies such as in vivo telemetry and imaging, allowing longitudinal assessment of animals during the course of disease. While there is no single method to universally replace, refine, or reduce animal models, the alternatives and techniques discussed are broadly applicable and they should be considered when infectious disease animal models are developed.

Second-hand eating? Maternal perception of the food environment affects reproductive investment in mice.

OBJECTIVE: Little information exists on how perception of the food (or "energetic") environment affects body composition and reproductive investment. The hypothesis was tested that female mice, who are themselves consuming standard chow diets but who are exposed to conspecifics eating a rich "cafeteria diet," will exhibit altered weight gain and reproductive investment. METHODS: Female C57BL/6 mice were raised on a cafeteria diet. At maturity, subjects were switched to a standard chow diet, and their cage-mates were assigned to consume either a cafeteria diet (treatment, n = 20) or standard chow (control, n = 20). Subjects were mated and pups raised to weaning. Subjects and pups were analyzed for body composition. RESULTS: Treatment had no discernable effect on dam body weight or composition but caused pups to have lower body weight (P = 0.036) and less fat mass (P = 0.041). A nearly significant treatment effect on "time to successful reproduction" (avg. 55 versus 44 days), likely due to increased failed first pregnancies, (14/19 versus 8/19, P = 0.099) was found. CONCLUSIONS: These data indicate that perceived food environment (independent of the diet actually consumed) can produce small pups with less body fat and possibly induce difficulties in pregnancy for dams. Replication and mechanistic studies should follow.