Structural, functional and molecular analysis of the effects of aging in the small intestine and colon of C57BL/6J mice.

BACKGROUND: By regulating digestion and absorption of nutrients and providing a barrier against the external environment the intestine provides a crucial contribution to the maintenance of health. To what extent aging-related changes in the intestinal system contribute to the functional decline associated with aging is still under debate. METHODS: Young (4 M) and old (21 M) male C57BL/6J mice were fed a control low-fat (10E%) or a high-fat diet (45E%) for 2 weeks. During the intervention gross energy intake and energy excretion in the feces were measured. After sacrifice the small and large intestine were isolated and the small intestine was divided in three equal parts. Swiss rolls were prepared of each of the isolated segments for histological analysis and the luminal content was isolated to examine alterations in the microflora with 16S rRNA Q-PCR. Furthermore, mucosal scrapings were isolated from each segment to determine differential gene expression by microarray analysis and global DNA methylation by pyrosequencing. RESULTS: Digestible energy intake was similar between the two age groups on both the control and the high-fat diet. Microarray analysis on RNA from intestinal scrapings showed no marked changes in expression of genes involved in metabolic processes. Decreased expression of Cubilin was observed in the intestine of 21-month-old mice, which might contribute to aging-induced vitamin B12 deficiency. Furthermore, microarray data analysis revealed enhanced expression of a large number of genes involved in immune response and inflammation in the colon, but not in the small intestine of the 21-month-old mice. Aging-induced global hypomethylation was observed in the colon and the distal part of the small intestine, but not in the first two sections of the small intestine. CONCLUSION: In 21-month old mice the most pronounced effects of aging were observed in the colon, whereas very few changes were observed in the small intestine.

The role of the small intestine in the development of dietary fat-induced obesity and insulin resistance in C57BL/6J mice.

BACKGROUND: Obesity and insulin resistance are two major risk factors underlying the metabolic syndrome. The development of these metabolic disorders is frequently studied, but mainly in liver, skeletal muscle, and adipose tissue. To gain more insight in the role of the small intestine in development of obesity and insulin resistance, dietary fat-induced differential gene expression was determined along the longitudinal axis of small intestines of C57BL/6J mice. METHODS: Male C57BL/6J mice were fed a low-fat or a high-fat diet that mimicked the fatty acid composition of a Western-style human diet. After 2, 4 and 8 weeks of diet intervention small intestines were isolated and divided in three equal parts. Differential gene expression was determined in mucosal scrapings using Mouse genome 430 2.0 arrays. RESULTS: The high-fat diet significantly increased body weight and decreased oral glucose tolerance, indicating insulin resistance. Microarray analysis showed that dietary fat had the most pronounced effect on differential gene expression in the middle part of the small intestine. By overrepresentation analysis we found that the most modulated biological processes on a high-fat diet were related to lipid metabolism, cell cycle and inflammation. Our results further indicated that the nuclear receptors Ppars, Lxrs and Fxr play an important regulatory role in the response of the small intestine to the high-fat diet. Next to these more local dietary fat effects, a secretome analysis revealed differential gene expression of secreted proteins, such as Il18, Fgf15, Mif, Igfbp3 and Angptl4. Finally, we linked the fat-induced molecular changes in the small intestine to development of obesity and insulin resistance. CONCLUSION: During dietary fat-induced development of obesity and insulin resistance, we found substantial changes in gene expression in the small intestine, indicating modulations of biological processes, especially related to lipid metabolism. Moreover, we found differential expression of potential signaling molecules that can provoke systemic effects in peripheral organs by influencing their metabolic homeostasis. Many of these fat-modulated genes could be linked to obesity and/or insulin resistance. Together, our data provided various leads for a causal role of the small intestine in the etiology of obesity and/or insulin resistance.

Muscarinic M(3) receptor-dependent regulation of airway smooth muscle contractile phenotype.

1. Airway smooth muscle (ASM) cells are known to switch from a contractile to a proliferative and synthetic phenotype in culture in response to serum and growth factors. Phenotype switching in response to contractile agonists, however, is poorly characterised, despite the possible relationship between ASM phenotype and airway remodelling in asthma. 2. To investigate the effects of muscarinic receptor stimulation on ASM phenotype, we used organ-cultured bovine tracheal smooth muscle (BTSM) strips, in which contractile responsiveness, contractile protein expression and proliferation were measured after pretreatment with methacholine. 3. Long-term methacholine pretreatment (8 days) decreased maximal contraction and sensitivity to methacholine as well as to histamine and KCl. This decrease was dose-dependent (pEC(50)=5.2+/-0.1). Pretreatment with the highest concentration of methacholine applied (100 microm) could suppress maximal histamine-induced contraction to 8+/-1% of control. In addition, contractile protein expression (myosin, actin) was downregulated two-fold. No concomitant increase in proliferative capacity was observed. 4. The M(3)/M(2) muscarinic receptor antagonist DAU 5884 (0.1 microm) completely inhibited the observed decrease in contractility. In contrast, the M(2)/M(3) muscarinic receptor antagonist gallamine (10 microm) was ineffective, demonstrating that M(2) receptors were not involved. 5. Pretreatment (8 days) with 60 mm KCl could mimick the strong decreases in contractility. This was completely prevented by pretreatment with verapamil (1 microm). 6. Regulation of contractility was not affected by protein kinase C inhibition, whereas inhibitors of phosphatidyl inositol 3-kinase and p42/p44 mitogen activated protein kinase were partially effective. 7. These results show that long-term methacholine pretreatment (8 days) induces an M(3) receptor-dependent decrease in BTSM contractility without increased proliferative capacity.

Functional characterization of serum- and growth factor-induced phenotypic changes in intact bovine tracheal smooth muscle.

1. The present study aims to investigate whether phenotypic changes, reported to occur in cultured isolated airway smooth muscle (ASM) cells, are of relevance to intact ASM. Moreover, we aimed to gain insight into the signalling pathways involved. 2. Culturing of bovine tracheal smooth muscle (BTSM) strips for up to 8 days in the presence of 10% foetal bovine serum caused a time-dependent (t(1/2)=2.8 days) decrease in maximal contraction (E(max)) to methacholine compared to serum-deprived controls (E(max)=74+/-4% at day 8). A reduced E(max) was also found using insulin-like growth factor-1 (30 ng ml(-1)) and platelet-derived growth factor (30 ng ml(-1)), but not using epidermal growth factor (10 ng ml(-1)) (E(max)=83+/-3, 67+/-8, 100+/-4%, respectively). Similar serum and growth factor-induced changes in E(max) were found for KCl-induced contraction (65+/-9, 80+/-7, 64+/-11% and 107+/-2%, respectively). 3. Strong correlations were found between the growth factor-induced reductions in E(max) and their proliferative responses, assessed by [(3)H]-thymidine-incorporation, in BTSM cells. (r=0.97, P=0.002 for methacholine and r=0.93, P=0.007 for KCl). 4. The PDGF-induced reduction in E(max) was inhibited completely by combined treatment with either PD 98059 (30 micro M) or LY 294002 (10 micro M). 5. These results indicate that serum and growth factors may cause a functional shift towards a less contractile phenotype in intact BTSM, which is associated with their proliferative response and dependent on signalling pathways involving the mitogen-activated protein kinase pathway and the phosphatidylinositol-3-kinase pathway.