Functional significance of genetic variation underlying limb bone diaphyseal structure

Limb bone diaphyseal structure is frequently used to infer hominin activity levels from skeletal remains, an approach based on the well‐documented ability of bone to adjust to its loading environment during life. However, diaphyseal structure is also determined in part by genetic factors. This study investigates the possibility that genetic variation underlying diaphyseal structure is influenced by the activity levels of ancestral populations and might also have functional significance in an evolutionary context. We adopted an experimental evolution approach and tested for differences in femoral diaphyseal structure in 1‐week‐old mice from a line that had been artificially selected (45 generations) for high voluntary wheel running and non‐selected controls. As adults, selected mice are significantly more active on wheels and in home cages, and have thicker diaphyses. Structural differences at 1 week can be assumed to primarily reflect the effects of selective breeding rather than direct mechanical stimuli, given that the onset of locomotion in mice is shortly after Day 7. We hypothesized that if genetically determined diaphyseal structure reflects the activity patterns of members of a lineage, then selected animals will have relatively larger diaphyseal dimensions at 1 week compared to controls. The results provide strong support for this hypothesis and suggest that limb bone cross sections may not always only reflect the activity levels of particular fossil individuals, but also convey an evolutionary signal providing information about hominin activity in the past. Am J Phys Anthropol 143:21–30, 2010. © 2010 Wiley‐Liss, Inc.     

Quantitation of o-, m- and p-cresol and deuterated analogs in human urine by gas chromatography with electron capture detection

A gas chromatographic method for the analysis of cresol metabolites of toluene and [²H₈]toluene in urine was developed. Cresol glucuronides and sulfates in urine were hydrolyzed with β-glucuronidase and arylsulfatase. Following extraction with tert.-butyl methyl ether and solvent exchange into benzene, the cresols were derivatized with heptafluorobutyric anhydride to form the heptafluorobutyrate esters. The derivatives were analyzed by gas chromatography with electron capture detection. Chromatographic resolution was achieved between all cresol isomers and their ²H₇ analogs. Calibration ranged from 0.001 to 500 μg/ml. Recoveries were 55–97% and showed no trend with respect to analyte concentration. Within-day precision of analyses of benchmark urine samples had a coefficient of variation of less than 4%. The assay sensitivity was limited by chromatographic background but was sufficient for quantification of the unlabeled cresols in urine from men with only environmental exposure to toluene. Average levels in urine samples from 45 men were 0.023, 0.054 and 37 μg/ml for o-, m- and p-cresol, respectively.     

Effects of naphthalene metabolites on cultured cells from eye lens

Naphthalene is toxic to the eye and results in opacification of the lens. To investigate the metabolic events that may be occurring in the lens epithelial cells, a cell line of lens from a transgenic mouse was incubated with various metabolites of naphthalene. Naphthoquinone at 50 microM was toxic to most cells with a depletion of glutathione levels noted within 6 h of incubation. At 10 microM, naphthoquinone caused an increase in specific activity of the enzyme DT-diaphorase. This enzyme is thought to be a defense against quinones since semiquinone formation is thought to be lessened. Naphthalene-1,2-dihydrodiol at 50 microM also caused an increase in the specific activity of the DT-diaphorase, while at 10 microM no apparent change occurred in the cells. Although there was evidence of metabolic alterations in the cells with the metabolites of naphthalene, the protein profile by two-dimensional gel electrophoresis did not change and there was no indication of an increase in carbonyl formation in the soluble proteins of the cells. These experiments indicate that the metabolites of naphthalene can cause alteration in the metabolism of the lens cells but may not cause apparent changes in the major proteins within the lens epithelium.