Although the linkage of polyglutamine (poly-Q) repeat expansion in the androgen receptor (AR) to Kennedy's disease (X-linked spinal and bulbar muscular atrophy) was a major step forward, the detailed molecular mechanism of how the change in poly-Q length contributes to the disease remains unclear. Here we report the identification of a nuclear G-protein, Ras-related nuclear protein/ARA24, as the first AR coactivator that can bind differentially with different lengths of poly-Q within AR. In the yeast and mammalian reciprocal interacting assays, our data suggested the interaction of AR N-terminal domain with ARA24 diminishes as the poly-Q length increases. The coactivation of ARA24 also diminishes with the poly-Q expansion within AR. Deletion of the acidic hexapeptide (DEDDDL) at the C terminus of ARA24 further enhances its AR coactivation. Together, our data suggest that poor interaction and weaker coactivation of ARA24 to the longer poly-Q AR in the Xlinked spinal and bulbar muscular atrophied AR could contribute to the weaker transactivation of AR. The consequence of poor interaction and weak coactivation may eventually lead to the partial androgen insensitivity during the development of Kennedy's disease.
The elucidation of early mineralization of bone is of great interest to the medical world. A clearer understanding of the initial bone formation processes can lead to information regarding the treatment and prevention of bone disorders and fractures and the manufacture of prosthetics. We exploited the mineralizing capabilities of bone cell cultures (osteoblast cultures) to monitor the earliest composition changes during mineral formation using Raman spectroscopy. We observed the first mineralization in 8-day-old osteoblasts and identified the mineral species as one that is very similar to that found in fetal bone tissue, a lightly carbonated apatite. Raman spectra show that carbonation, an indicator of bone maturity, appears at the first detectable stage of mineralization in osteoblasts, and increases over time. We also isolated single osteoblasts by growing them on fused-silica microscope slides. Not only did these cells exhibit abnormal growth patterns, but they also expressed a mineral composition different to a carbonated apatite. Raman spectra of this mineral species have spectral characteristics comparable to those of b-tricalcium phosphate.
Hexokinase II (HKII) is the predominant isozyme expressed in peripheral insulin-responsive tissues. To explore the role of HKII in muscle glucose metabolism, two lines of transgenic mice were generated where overexpression was restricted to striated muscle; HKII protein levels and activity were increased by 3-8-fold. Oral glucose tolerance, intravenous insulin tolerance, and insulin and lactate levels were unaffected in transgenic mice. There was a trend toward increased levels of muscle glycogen; however, glucose-6-phosphate levels were increased by 43% in transgenic skeletal muscle following in vivo glucose and insulin administration. Using 2-[3H]deoxyglucose as a tracer, in vitro basal and insulin-stimulated glucose uptake were determined in extensor digitorum longus, soleus, and epitrochlearis muscles. Maximal insulin-stimulated glucose uptake was increased by 17% (extensor digitorum longus), 34% (soleus), and 90% (epitrochlearis) in transgenic muscles; basal and submaximal glucose uptake was also modestly increased in soleus and epitrochlearis. These data suggest that increased muscle HKII (corresponding to the upper end of the physiologic range) may not be sufficient to augment net in vivo glucose homeostasis. However, glucose phosphorylation can represent a rate-limiting step for skeletal muscle glucose utilization since muscle glucose-6-phosphate levels are increased during in vivo hyperinsulinemia and hyperglycemia; furthermore, basal and insulin-mediated muscle glucose uptake can be increased by a selective increase in HKII expression.
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