Characterisation of dystrophin in fetuses at risk for Duchenne muscular dystrophy.

Dystrophin, the product of the Duchenne muscular dystrophy (DMD) gene, was studied in muscle from 16 human fetuses at risk for the disease. Eleven high risk (greater than 95% probability) and 5 low-risk (less than 25% probability) fetuses were studied with antibodies raised to different regions of the protein. All low-risk fetuses showed a similar pattern to that of normal fetuses of a comparable age: using Western blot analysis, a protein was detected of similar size and abundance to that of normal fetuses (i.e. smaller molecular weight than that of adult muscle); immunocytochemistry showed uniform sarcolemmal staining in fetuses older than 18 weeks gestation and differential staining of myotubes at different stages of development (distinguished by size) in younger fetuses (less than 15 weeks gestation). In contrast, Western blot analysis of high-risk fetuses detected low levels of dystrophin in 4 cases; 7 fetuses had no detectable protein. Immunocytochemistry with some dystrophin antibodies showed weak staining of the sarcolemma and around central nuclei in younger fetuses; in older fetuses there was little sarcolemmal staining with any antibody other than occasional positive fibres. These results indicate that careful study of dystrophin in fetuses at risk for DMD can be used to establish the clinical phenotype and provide additional information for future family counselling.

Polymer − surfactant vesicular complexes in aqueous medium

The introduction of ionic single-tailed surfactants to aqueous solutions of EO18BO10 [EO = poly(ethylene oxide), BO = poly(1,2-butylene oxide), subscripts denote the number of repeating units] leads to the formation of vesicles, as probed by laser scanning confocal microscopy. Dynamic light scattering showed that the dimensions of these aggregates at early stages of development do not depend on the sign of the surfactant head group charge. Small-angle X-ray scattering (SAXS) analysis indicated the coexistence of smaller micelles of different sizes and varying polymer content in solution. In strong contrast to the dramatic increase of size of dispersed particles induced by surfactants in dilute solution, the d-spacing of corresponding mesophases reduces monotonically upon increasing surfactant loading. This effect points to the suppression of vesicles as a consequence of increasing ionic strength in concentrated solutions. Maximum enhancements of storage modulus and thermal stability of hybrid gels take place at different compositions, indicating a delicate balance between the number and size of polymer-poor aggregates (population increases with surfactant loading) and the number and size of polymer−surfactant complexes (number and size decrease in high surfactant concentrations).