Endocrine cells are continually regulating the balance between hormone biosynthesis, secretion, and intracellular degradation to ensure that cellular hormone stores are maintained at optimal levels. In pancreatic beta-cells, intracellular insulin stores in beta-granules are mostly upheld by efficiently up-regulating proinsulin biosynthesis at the translational level to rapidly replenish the insulin lost via exocytosis. Under normal circumstances, intracellular degradation of insulin plays a relatively minor janitorial role in retiring aged beta-granules, apparently via crinophagy. However, this mechanism alone is not sufficient to maintain optimal insulin storage in beta-cells when insulin secretion is dysfunctional. Here, we show that despite an abnormal imbalance of glucose/glucagon-like peptide 1 regulated insulin production over secretion in Rab3A(-/-) mice compared with control animals, insulin storage levels were maintained due to increased intracellular beta-granule degradation. Electron microscopy analysis indicated that this was mediated by a significant 12-fold up-regulation of multigranular degradation vacuoles in Rab3A(-/-) mouse islet beta-cells (P
Considerable progress has been made in understanding variations in gene sequence and expression level associated with phenotype, yet how genetic diversity translates into complex phenotypic differences remains poorly understood. Here, we examine the relationship between genetic background and spatial patterns of gene expression across seven strains of mice, providing the most extensive cellular-resolution comparative analysis of gene expression in the mammalian brain to date. Using comprehensive brainwide anatomic coverage (more than 200 brain regions), we applied in situ hybridization to analyze the spatial expression patterns of 49 genes encoding well-known pharmaceutical drug targets. Remarkably, over 50% of the genes examined showed interstrain expression variation. In addition, the variability was nonuniformly distributed across strain and neuroanatomic region, suggesting certain organizing principles. First, the degree of expression variance among strains mirrors genealogic relationships. Second, expression pattern differences were concentrated in higher-order brain regions such as the cortex and hippocampus. Divergence in gene expression patterns across the brain could contribute significantly to variations in behavior and responses to neuroactive drugs in laboratory mouse strains and may help to explain individual differences in human responsiveness to neuroactive drugs. T here are numerous and complex mechanisms by which genetic variation within or across species contributes to phenotypic diversity (1-3). The most appreciated and easily testable of these involve sequence modifications that alter the amino acid coding regions of genes and measurably affect protein function. Quantitative differences in transcript abundance, due to gene dosage or regulatory mutations have also been associated with phenotype (4-6). However, outside the realm of developmental biology and recent studies of copy number variation (7,8), the spatial distribution of gene expression within defined tissues and cell types remains relatively unexplored as a means by which genetic differences confer phenotypic differences.To investigate the relationship between spatial gene expression patterns and genetic background, we conducted a large-scale, systematic, brainwide survey of gene expression (9)
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