Site-specific associations of muscle thickness with bone mineral density in middle-aged and older men and women.

It is unknown whether age-related site-specific muscle loss is associated with areal bone mineral density (aBMD) in older adults. To examine the relationships between aBMD and whole-body muscle thickness distribution, 97 healthy adults (46 women and 51 men) aged 50-78 years volunteered. Total and appendicular lean soft tissue mass, aBMD of the lumbar spine (LS-aBMD) and femoral neck (FN-aBMD) were determined using dual-energy X-ray absorptiometry. Muscle thickness (MT) was measured by ultrasound at nine sites of the body (forearm, upper arm, trunk, upper leg, and lower leg). Relationships of each co-variate with aBMD were tested partialling out the effect of age. aBMD was not correlated with either MT of the trunk or anterior lower leg in either sex. In men, significant and relatively strong correlations were observed between anterior and posterior upper arms, posterior lower leg, and anterior upper leg MT and LS-aBMD or FN-aBMD. In women, significant correlations were observed between anterior and posterior upper legs, posterior lower leg, and anterior upper arm MT and FN-aBMD. LS-aBMD was only correlated with forearm and posterior upper leg MT in women. In conclusion, the site-specific association of MT and aBMD differs between sexes and may be associated with the participants' daily physical activity profile.

Osteoporosis knowledge, attitudes, and behaviors of female collegiate athletes.

Female athletes often engage in harmful dietary and weight control practices that can impair bone health and hinder performance. To promote related positive health behavior practices, nutrition educators may be more effective if they understand the osteoporosis knowledge, attitudes, and behaviors among female athletes. A questionnaire including items related to osteoporosis and dietary calcium knowledge, attitudes, and behavioral practices was administered to 114 female collegiate athletes (19.6+/-1.4 years). Self-reported intakes of dairy product consumption were also obtained; subjects were asked how many times per week they drank milk and ate cheese, yogurt, and ice cream. The mean score for osteoporosis knowledge was 7.1+/-1.9 (out of 10 items). The mean score for favorable responses to attitude items was 2.1+/-0.8 (out of 3 items). Correct responses to dietary calcium knowledge items were 2.2+/-0.7 (out of 3 items). On average, subjects consumed 2.4+/-1.6 servings of dairy products per day; 31% of subjects consumed the recommended 3 or more servings per day. Osteoporosis knowledge, osteoporosis attitudes, and dietary calcium knowledge were not correlated (p > .05) with dairy product intake. Because of the importance of achieving a high peak bone mass to prevent osteoporosis, our data suggest that further research is needed regarding other factors that might influence dairy product intake among female athletes.

Association of calcium/calmodulin-dependent kinase II with developmentally regulated splice variants of the postsynaptic density protein densin-180.

In a continuing search for proteins that target calcium/calmodulin-dependent protein kinase II (CaMKII) to postsynaptic density (PSD) substrates important in synaptic plasticity, we showed that the PSD protein densin-180 binds CaMKII. Four putative splice variants (A-D) of the cytosolic tail of densin-180 are shown to be differentially expressed during brain development. Densin-180 splicing affects CaMKII phosphorylation of specific serine residues. Variants A, B, and D, but not C, bind CaMKII stoichiometrically and with high affinity, mediated by a differentially spliced domain. Densin-180 differs from the previously identified CaMKII-binding protein NR2B in that binding does not strictly require CaMKII autophosphorylation. Binding of densin-180 and NR2B to CaMKII is noncompetitive, indicating different interaction sites on CaMKII. Expression of the membrane-targeted CaMKII-binding domain of densin-180 confers membrane localization to coexpressed CaMKII without requiring calcium mobilization, suggesting that densin-180 plays a role in the constitutive association of CaMKII with PSDs.

Brain actin-associated protein phosphatase 1 holoenzymes containing spinophilin, neurabin, and selected catalytic subunit isoforms.

We previously characterized PP1bp134 and PP1bp175, two neuronal proteins that bind the protein phosphatase 1 catalytic subunit (PP1). Here we purify from rat brain actin-cytoskeletal extracts PP1(A) holoenzymes selectively enriched in PP1gamma(1) over PP1beta isoforms and also containing PP1bp134 and PP1bp175. PP1bp134 and PP1bp175 were identified as the synapse-localized F-actin-binding proteins spinophilin (Allen, P. B., Ouimet, C. C., and Greengard, P. (1997) Proc. Natl. Acad. Sci. U. S. A. 94, 9956-9561; Satoh, A., Nakanishi, H., Obaishi, H., Wada, M., Takahashi, K., Satoh, K., Hirao, K., Nishioka, H., Hata, Y., Mizoguchi, A., and Takai, Y. (1998) J. Biol. Chem. 273, 3470-3475) and neurabin (Nakanishi, H., Obaishi, H., Satoh, A., Wada, M., Mandai, K., Satoh, K., Nishioka, H. , Matsuura, Y., Mizoguchi, A., and Takai, Y. (1997) J. Cell Biol. 139, 951-961), respectively. Recombinant spinophilin and neurabin interacted with endogenous PP1 and also with each other when co-expressed in HEK293 cells. Spinophilin residues 427-470, or homologous neurabin residues 436-479, were sufficient to bind PP1 in gel overlay assays, and selectively bound PP1gamma(1) from a mixture of brain protein phosphatase catalytic subunits; additional N- and C-terminal sequences were required for potent inhibition of PP1. Immunoprecipitation of spinophilin or neurabin from crude brain extracts selectively coprecipitated PP1gamma(1) over PP1beta. Moreover, immunoprecipitation of PP1gamma(1) from brain extracts efficiently coprecipitated spinophilin and neurabin, whereas PP1beta immunoprecipitation did not. Thus, PP1(A) holoenzymes containing spinophilin and/or neurabin target specific neuronal PP1 isoforms, facilitating efficient regulation of synaptic phosphoproteins.

Association of brain protein phosphatase 1 with cytoskeletal targeting/regulatory subunits.

Protein phosphatase 1 catalytic subunit (PP1C) is highly enriched in isolated rat postsynaptic densities. Gel overlay analyses using digoxigenin (DIG)-labeled PP1C revealed four major rat brain PP1C-binding proteins (PP1bps) with molecular masses of approximately 216, 175, 134, and 75 kDa, which were (1) more abundant in brain than other rat tissues; (2) differentially expressed in microdissected brain regions; and (3) enriched in isolated cortex postsynaptic densities. PP1bp175, PP1bp134, PP1bp75, and PP1C were partially released from forebrain particulate extracts by incubation at low ionic strength, which destabilizes the actin cytoskeleton. Size-exclusion chromatography of solubilized extracts separated two main PP1 activities (approximately 600 and approximately 100 kDa). PP1bps and PP1C gamma1 were enriched in the approximately 600-kDa peak, but PP1C beta was enriched in the approximately 100-kDa peak. Furthermore, PP1bp175 and PP1bp134 exhibited lower binding of recombinant DIG-PP1C beta than recombinant DIG-PP1C gamma1 or DIG-PP1C alpha. Solubilized PP1bp175 and PP1bp134 interact with PP1C under native conditions, because they both (1) coeluted from size-exclusion and ion-exchange columns; (2) bound to microcystin-LR-Sepharose; and (3) coprecipitated using PP1C antibodies. Trypsinolysis of the approximately 600-kDa form of PP1 increased phosphorylase a phosphatase activity approximately fourfold, suggesting that interaction of PP1C with these PP1bps modulates its activity. Thus, brain PP1 activity is likely targeted to the cytoskeleton, including postsynaptic densities, by isoform-selective binding of PP1C to these targeting/regulatory subunits, contributing to the specificity of its physiological roles.

Anthropometric measurements and dietary intakes of Cherokee Indian teenagers in North Carolina.

Anthropometric measurements, rates of obesity, and food intake practices were investigated among 277 Cherokee Indian youths in North Carolina. Differences in food intake practices between lean and fat individuals were also assessed. Height, weight, and triceps skinfold measurements were taken, along with three dietary recalls. When Cherokee height data were compared with national survey data, no significant differences were found. In contrast, mean body weights and triceps skinfolds of Cherokees were significantly higher than national reference data. Obesity rates were found to be high; almost one-half of the Cherokee boys and one-third of the girls had skinfold thicknesses above the 85th percentile for Ten-State Nutrition Survey reference data. The effects of degree of Cherokee blood on height, weight, and triceps skinfolds were also analyzed. No significant differences existed for triceps skinfolds or weight and degree of Indian blood. However, there was a significant relationship (p less than .001) between height and degree of Indian blood, with a decrease in height with an increase in Indian blood. Mean energy intakes were not significantly different between the lean and fat individuals. Similarly, no differences were found in meal or snacking patterns. It does not appear that the obesity is caused by overeating. The high incidence of obesity among the youth and the prevalence of maturity-onset diabetes in the adult Cherokee population speaks to the need for management of obesity.

The cultural appropriateness of the WIC Program in Cherokee, North Carolina.

The data presented in this article illustrate the WIC program's ability to function within the Cherokee Indian culture. The respondents reported that WIC foods are accepted and widely distributed in the Cherokee WIC participant households. In addition, they stated that infant and child feeding practices are affected by the information they receive from advice givers. These factors in combination with the Cherokees' positive attitude toward the WIC program make for effective implementation of the national WIC nutrition goal: to maximize the WIC food package's effect on nutritional status considering all ethnic, cultural, and geographic preferences.

Phosphorylation and inactivation of glycogen synthase by phosphorylase kinase.

Skeletal muscle glycogen a4-synthase (EC 2.4.1.11) has been purified free of all synthase kinase and phosphatase activities by chromatography on a Glc-N-6-P-Sepharose affinity column and then on a phosphocellulose column. This preparation of glycogen synthase was tested as a substrate for purified skeletal muscle phosphorylase kinase (ATP:phosphorylase-b phosphotransferase, EC 2.7.1.38). Phosphorylase kinase (1-10 microgram/ml or 0.03-0.3 microM) catalyzes rapid phosphorylation of glycogen synthase (4.5 microM) associated with conversion of the active a form to the less active b form. In the reaction, greater than 95% of the 32P incorporation from [gamma-32P]ATP goes into the synthase subunit almost exclusively in the trypsin-insensitive region which is responsible for synthase a-to-b conversion. Synthase phosphorylation or inactivations catalyzed by phosphorylase kinase is blocked by ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid, is ATP dependent, is 10-fold more rapid at pH 8.6 than at pH 6.8, and is increased 10-fold by prior activation of the phosphorylase kinase with MgATP and cyclic AMP. With activated phosphorylase kinase at pH 8.2 the apparent Km and Vmax are approximately 70 microM and 4 mumol/min per mg with glycogen synthase and 70 microM and 9 mumol/min per mg with phosphorylase as substrate. It is concluded that glycogen synthase is a substrate in vitro for phosphorylase kinase, a Ca2+-dependent enzyme. The possible physiological significance of this reaction is discussed.