n to provide protection against M. catarrhalis colonization in a mouse pulmonary model. The results confirm that further evaluation of these proteins as vaccine candidates in additional functional studies and in clinically relevant Moraxella otitis media models is warranted. Acknowledgments We thank Eva Ban for provision of human sera, Ingrid Andersson, Martin Norman, Jenny Fernebro, Corne de Vogel, Barbara Albiger, Birgit Noiges, Stefan Seidel, and Christina Satke for excellent technical assistance, and Martin Oleksiewicz and Petra Schlick for scientific discussions on the project. Skeletal muscle is the most abundant tissue in the human body, and there are major differences between women and men in energy metabolism, fiber type composition, and contractile speed; however, the mechanisms behind these differences are unknown. A number of groups have reported differences in exercise related substrate metabolism between men and women, specifically that women oxidize more lipid and less carbohydrate than men. Similar studies in rats have also found gender differences in lipid metabolism, specifically that female rats have greater lipid oxidation and muscle lipoprotein lipase activity, as compared with male rats. Furthermore, when female rats are oophorectomized, lipid oxidation is lower during endurance exercise. The exact mechanisms behind such observations are unclear; however, sex differences in mRNA content and protein expression appear to be directionally consistent with the observed metabolic differences present during exercise. Specifically, women compared to age and fitness matched men have higher mRNA content for LPL, membrane fatty acid transport protein 1 , FAT/CD36 transporter and plasma membrane fatty acid binding protein , citrate synthase, b-hydroxyacyl-CoA dehydrogenase , and hormone sensitive lipase. On the whole 6296388 body level, women show greater lipolysis, and greater uptake of plasma free fatty acids, and use more intramuscular triacylglycerol than men. Futhermore, a sex difference in muscle fiber composition has been 20830712 found in different skeletal muscles, such as, erector spinae, internal and external intercostal, latissimus dorsi, biceps brachii, vastus medialis, and vastus lateralis. Although studies concerning sex differences in skeletal muscle fiber type have shown inconsistent results, women generally have a greater relative type I fiber area, a smaller relative area of type II fibers and a greater percentage area of type I fibers. The potential molecular mechanisms behind these sex differences have not been evaluated for the mRNA NVP-AUY 922 species of the genes involved in muscle development, or fiber-type determination and differentiation. The molecular mechanisms for the observed differences in substrate oxidation and fiber type between men and women are Sex Difference in mRNA Content unknown. In this study we used a targeted approach to evaluate mRNA species of the genes involved in muscle development, fiber-type determination and differentiation, and a microarray comparison to evaluate the many more potential mRNA species that are required for lipid metabolism and fiber type in human skeletal muscle, which may yield important data for understanding potential novel mechanisms. Gene array technology has provided a rapid and efficient way to screen a large number of mRNAs in order to identify potential targets and pathways for further research. Recently, several groups have used gene arrays to identify novel transcriptional prog