S6K1 controls pancreatic β cell size independently of intrauterine growth restriction

Type 2 diabetes mellitus (T2DM) is a worldwide heath problem that is characterized by insulin resistance and the eventual loss of β cell function. As recent studies have shown that loss of ribosomal protein (RP) S6 kinase 1 (S6K1) increases systemic insulin sensitivity, S6K1 inhibitors are being pursued as potential agents for improving insulin resistance. Here we found that S6K1 deficiency in mice also leads to decreased β cell growth, intrauterine growth restriction (IUGR), and impaired placental development. IUGR is a common complication of human pregnancy that limits the supply of oxygen and nutrients to the developing fetus, leading to diminished embryonic β cell growth and the onset of T2DM later in life. However, restoration of placental development and the rescue of IUGR by tetraploid embryo complementation did not restore β cell size or insulin levels in S6K1^–/– embryos, suggesting that loss of S6K1 leads to an intrinsic β cell lesion. Consistent with this hypothesis, reexpression of S6K1 in β cells of S6K1^–/– mice restored embryonic β cell size, insulin levels, glucose tolerance, and RPS6 phosphorylation, without rescuing IUGR. Together, these data suggest that a nutrient-mediated reduction in intrinsic β cell S6K1 signaling, rather than IUGR, during fetal development may underlie reduced β cell growth and eventual development of T2DM later in life.     

Gut Commensal Bacteria and Regional Wnt Gene Expression in the Proximal Versus Distal Colon

Regional expression of Wingless/Int (Wnt) genes plays a central role in regulating intestinal development and homeostasis. However, our knowledge of such regional Wnt proteins in the colon remains limited. To understand further the effect of Wnt signaling components in controlling intestinal epithelial homeostasis, we investigated whether the physiological heterogeneity of the proximal and distal colon can be explained by differential Wnt signaling. With the use of a Wnt signaling-specific PCR array, expression of 84 Wnt-mediated signal transduction genes was analyzed, and a differential signature of Wnt-related genes in the proximal versus distal murine colon was identified. Several Wnt agonists (Wnt5a, Wnt8b, and Wnt11), the Wnt receptor frizzled family receptor 3, and the Wnt inhibitory factor 1 were differentially expressed along the colon length. These Wnt signatures were associated with differential epithelial cell proliferation and migration in the proximal versus distal colon. Furthermore, reduced Wnt/β-catenin activity and decreased Wnt5a and Wnt11 expression were observed in mice lacking commensal bacteria, an effect that was reversed by conventionalization of germ-free mice. Interestingly, myeloid differentiation primary response gene 88 knockout mice showed decreased Wnt5a levels, indicating a role for Toll-like receptor signaling in regulating Wnt5a expression. Our results suggest that the morphological and physiological heterogeneity within the colon is in part facilitated by the differential expression of Wnt signaling components and influenced by colonization with bacteria.One of the fundamental aspects in the development of the gastrointestinal tract is the spatiotemporal expression of signaling molecules that regulate cell fate and differentiation. Previous studies have highlighted a central role of the evolutionarily conserved Wingless/Int (Wnt) signaling pathways as key regulators of embryonic development and epithelial homeostasis in the gut.^1–3 In development, local expression patterns of Wnt signaling components play an important role in organogenesis.^4,5 Wnt signals control important biological processes required for cell proliferation, differentiation, polarity, and movement, depending on the target cell and the cellular environment.Recent reports have highlighted the importance of understanding the role of Wnt signaling in the intestinal tract. The intestinal epithelium is highly dynamic and, depending on the species and location, is actively turned over in <1 week.⁶ Wnt/β-catenin signaling regulates intestinal epithelial cell (IEC) homeostasis and proliferation by increasing β-catenin stability in crypt epithelial cells, whereas IEC migration and differentiation are believed to be in part facilitated through noncanonical (Wnt) signaling pathways independent of β-catenin.^6,7 The renewal of intestinal epithelia requires a delicate balance of signaling proteins to control epithelial cell proliferation and migration that in turn is vital for maintaining mucosal homeostasis. Interestingly, regional differences in Wnt gene expression in small versus large intestine are observed in adult mice, suggesting the importance of differential local Wnt expression in regulation of intestinal mucosal homeostasis.⁷Although the entire colon exhibits considerable morphological and physiological heterogeneity along its length,^8–11 the expression pattern of Wnt signaling components in the different regions of the adult colon remains poorly understood. Embryologically, the cecum, ascending colon, and the proximal two-thirds of the transverse colon are derived from the midgut, whereas the distal colon originates from the hindgut. Such distinct origins of the colonic segment support specific biological characteristics and suggest that distinct regulatory factors are likely to control epithelial homeostasis in the proximal versus distal colon. In addition, important contributing factors that influence Wnt/β-catenin signaling and intestinal epithelial proliferation might be microbial communities that localize in the intestine in distinct regions.^6,12 Such a delicate physiological balance of Wnt signaling and intestinal epithelial homeostasis is further perturbed in mucosal inflammatory and neoplastic diseases,^3,13 which also indicate regional differences in the proximal versus distal colonic segments.^14–17In the present study, we investigate the regional heterogeneity of Wnt genes in the proximal versus distal colon. Given the importance of luminal microbiota in influencing intestinal epithelial homeostasis¹⁸ and to determine whether the Wnt signatures are influenced by microflora colonization, we examined expression of Wnt proteins in the colonic segments of mice raised under germ-free (GF) conditions.