Hyperglycemia Increases Interstitial Cells of Cajal via MAPK1 and MAPK3 Signaling to ETV1 and KIT, Leading to Rapid Gastric Emptying.

BACKGROUND & AIMS: Depletion of interstitial cells of Cajal (ICCs) is common in diabetic gastroparesis. However, in approximately 20% of patients with diabetes, gastric emptying (GE) is accelerated. GE also occurs faster in obese individuals, and is associated with increased blood levels of glucose in patients with type 2 diabetes. To understand the fate of ICCs in hyperinsulinemic, hyperglycemic states characterized by rapid GE, we studied mice with mutation of the leptin receptor (Leprdb/db), which in our colony had accelerated GE. We also investigated hyperglycemia-induced signaling in the ICC lineage and ICC dependence on glucose oxidative metabolism in mice with disruption of the succinate dehydrogenase complex, subunit C gene (Sdhc). METHODS: Mice were given breath tests to analyze GE of solids. ICCs were studied by flow cytometry, intracellular electrophysiology, isometric contractility measurement, reverse-transcription polymerase chain reaction, immunoblot, immunohistochemistry, enzyme-linked immunosorbent assays, and metabolite assays; cells and tissues were manipulated pharmacologically and by RNA interference. Viable cell counts, proliferation, and apoptosis were determined by methyltetrazolium, Ki-67, proliferating cell nuclear antigen, bromodeoxyuridine, and caspase-Glo 3/7 assays. Sdhc was disrupted in 2 different strains of mice via cre recombinase. RESULTS: In obese, hyperglycemic, hyperinsulinemic female Leprdb/db mice, GE was accelerated and gastric ICC and phasic cholinergic responses were increased. Female KitK641E/+ mice, which have genetically induced hyperplasia of ICCs, also had accelerated GE. In isolated cells of the ICC lineage and gastric organotypic cultures, hyperglycemia stimulated proliferation by mitogen-activated protein kinase 1 (MAPK1)- and MAPK3-dependent stabilization of ets variant 1-a master transcription factor for ICCs-and consequent up-regulation of v-kit Hardy-Zuckerman 4 feline sarcoma viral oncogene homolog (KIT) receptor tyrosine kinase. Opposite changes occurred in mice with disruption of Sdhc. CONCLUSIONS: Hyperglycemia increases ICCs via oxidative metabolism-dependent, MAPK1- and MAPK3-mediated stabilization of ets variant 1 and increased expression of KIT, causing rapid GE. Increases in ICCs might contribute to the acceleration in GE observed in some patients with diabetes.

Endoscopic full-thickness biopsy of the gastric wall with defect closure by using an endoscopic suturing device: survival porcine study.

BACKGROUND: The pathogenesis of several common gastric motility diseases and functional GI disorders remains essentially unexplained. Gastric wall biopsies that include the muscularis propria to evaluate the enteric nervous system, interstitial cells of Cajal, and immune cells can provide important insights for our understanding of the etiology of these disorders. OBJECTIVES: To determine the technical feasibility, reproducibility, and safety of performing a full-thickness gastric biopsy (FTGB) by using a submucosal endoscopy with mucosal flap (SEMF) technique; the technical feasibility, reproducibility, and safety of tissue closure by using an endoscopic suturing device; the ability to identify myenteric ganglia in resected specimens; and the long-term safety. DESIGN: Single center, preclinical survival study. SETTING: Animal research laboratory, developmental endoscopy unit. SUBJECTS: Twelve domestic pigs. INTERVENTIONS: Animals underwent an SEMF procedure with gastric muscularis propria resection. The resultant offset mucosal entry site was closed by using an endoscopic suturing device. Animals were kept alive for 2 weeks. MAIN OUTCOME MEASUREMENTS: The technical feasibility, reproducibility, and safety of the procedure; the clinical course of the animals; the histological and immunochemical evaluation of the resected specimen to determine whether myenteric ganglia were present in the sample. RESULTS: FTGB was performed by using the SEMF technique in all 12 animals. The offset mucosal entry site was successfully closed by using the suturing device in all animals. The mean resected tissue specimen size was 11 mm. Mean total procedure time was 61 minutes with 2 to 4 interrupted sutures placed per animal. Histology showed muscularis propria and serosa, confirming full-thickness resections in all animals. Myenteric ganglia were visualized in 11 of 12 animals. The clinical course was uneventful. Repeat endoscopy and necropsy at 2 weeks showed absence of ulceration at both the mucosal entry sites and overlying the more distal muscularis propria resection sites. There was complete healing of the serosa in all animals with minimal single-band adhesions in 5 of 12 animals. Retained sutures were present in 10 of 12 animals. LIMITATIONS: Animal experiment. CONCLUSIONS: FTGB by using the SEMF technique and an endoscopic suturing device is technically feasible, reproducible, and safe. Larger tissue specimens will allow improved analysis of multiple cell types.

CD206-positive M2 macrophages that express heme oxygenase-1 protect against diabetic gastroparesis in mice.

BACKGROUND & AIMS: Gastroparesis is a well-recognized complication of diabetes. In diabetics, up-regulation of heme oxygenase-1 (HO1) in gastric macrophages protects against oxidative stress-induced damage. Loss of up-regulation of HO1, the subsequent increase in oxidative stress, and loss of Kit delays gastric emptying; this effect is reversed by induction of HO1. Macrophages have pro- and anti-inflammatory activities, depending on their phenotype. We investigated the number and phenotype of gastric macrophages in NOD/ShiLtJ (nonobese diabetic [NOD]) mice after onset of diabetes, when delayed gastric emptying develops, and after induction of HO1 to reverse delay. METHODS: Four groups of NOD and db/db mice were studied: nondiabetic, diabetic with normal emptying, diabetic with delayed gastric emptying, and diabetic with delayed gastric emptying reversed by the HO1 inducer hemin. Whole mount samples from stomach were labeled in triplicate with antisera against F4/80, HO1, and CD206, and macrophages were quantified in stacked confocal images. Markers for macrophage subtypes were measured by quantitative polymerase chain reaction. RESULTS: Development of diabetes was associated with an increased number of macrophages and up-regulation of HO1 in CD206(+) M2 macrophages. Onset of delayed gastric emptying did not alter the total number of macrophages, but there was a selective loss of CD206(+)/HO1(+) M2 macrophages. Normalization of gastric emptying was associated with repopulation of CD206(+)/HO1(+) M2 macrophages. CONCLUSIONS: CD206(+) M2 macrophages that express HO1 appear to be required for prevention of diabetes-induced delayed gastric emptying. Induction of HO1 in macrophages might be a therapeutic option for patients with diabetic gastroparesis.

Production of the gaseous signal molecule hydrogen sulfide in mouse tissues.

The gaseous molecule hydrogen sulfide (H(2)S) has been proposed as an endogenous signal molecule and neuromodulator in mammals. Using a newly developed method, we report here for the first time the ability of intact and living brain and colonic tissue in the mouse to generate and release H(2)S. This production occurs through the activity of two enzymes, cystathionine-gamma-lyase and cystathionine-beta-synthase. The quantitative expression of messenger RNA and protein localization for both enzymes are described in the liver, brain, and colon. Expression levels of the enzymes vary between tissues and are differentially distributed. The observation that, tissues that respond to exogenously applied H(2)S can endogenously generate the gas, strongly supports its role as an endogenous signal molecule.

Endoscopic "no hole" full-thickness biopsy of the stomach to detect myenteric ganglia.

BACKGROUND: The etiology of several common gastric motility diseases remains largely unknown. Gastric wall biopsy specimens that include the muscularis propria to evaluate the enteric nervous system, interstitial cells of Cajal, and related cells are essential to promote our understanding of the pathophysiologic mechanisms. On the basis of our previous work, a double EMR technique provided sufficient tissue to identify myenteric ganglia. A serious limitation to the technique was the resultant gastric wall perforation after tissue resection. The optimal procedure would seal the gastric wall defect before tissue resection, eliminating the risk of peritonitis. OBJECTIVES: The aims of this study were to (1) determine the technical feasibility and reproducibility of a full-thickness gastric biopsy by use of a novel double EMR technique without creating a perforation ("no hole") and to (2) determine safety of the procedure. DESIGN AND INTERVENTIONS: Preclinical study of 6 pigs. Each animal underwent a "no hole" double EMR survival procedure. To prevent perforation, detachable endoloops and prototype T-tag tissue anchors were placed before resection. At 2 weeks repeat endoscopy was performed followed by necropsy. MAIN OUTCOME MEASUREMENTS: Hematoxylin-eosin staining was used to determine which muscle layers were included in the resected specimen, and an antibody to neuronal nitric oxide synthase was used to visualize myenteric ganglia in the sample. Technical feasibility, reproducibility, and safety of the procedure were evaluated. RESULTS: Full-thickness gastric biopsy specimens were obtained from all animals without overt perforation. There were no procedural complications. Histologic examination showed muscularis propria with all layers of muscle present, and immunochemical studies demonstrated myenteric ganglia in all tissue samples. Four animals had an uneventful clinical course, and repeat endoscopy at week 2 showed ulceration with stellate fibrosis. Necropsy showed mild localized adhesions. Two animals were killed at days 3 and 6, respectively, because of suspected peritonitis. At necropsy, delayed perforations at the resection sites were noted with displaced endoloops and tissue anchors. CONCLUSION: This study explored the concept of obtaining deep muscle wall biopsy specimens with use of a unique approach of resection without perforation. The novel "no hole" double EMR technique was technically feasible and reproducible with sufficient tissue obtained to identify myenteric ganglia. However, there was a high delayed perforation rate associated with displaced endoloops and tissue anchors. On the basis of this early experience, improved safety data may be anticipated with future studies using improved tissue closure devices.

Evaluation of endoscopic approaches for deep gastric-muscle-wall biopsies: what works?

BACKGROUND: A major barrier to furthering our understanding of the pathophysiology of neuromuscular GI diseases, including functional GI disorders, is the inability to obtain deep gastric-wall biopsy specimens that include both layers of the muscularis propria, which allows evaluation of specific cell types, including myenteric ganglia. OBJECTIVES: The aims of this preclinical study were to (1) evaluate different endoscopic approaches for obtaining deep gastric-muscle-wall biopsy specimens and (2) determine if myenteric ganglia were present in the tissue samples. DESIGN AND INTERVENTIONS: This was a preclinical acute study by using a pig model. Multiple samples were obtained from 4 pigs. The endoscopic techniques evaluated were (1) EUS-guided tru-cut biopsy of the gastric wall, (2) jumbo biopsy of the post-EMR site, (3) jumbo biopsy of the gastrotomy margin, (4) serosal-side biopsy through a gastrotomy, and (5) double-EMR resection. MAIN OUTCOME MEASUREMENTS: Resected tissue was submitted for histology to determine which wall layers were included in the resected specimen. Hematoxylin and eosin staining was used to determine which muscle layers were biopsied, and an antibody to protein gene product 9.5 was used to determine if myenteric ganglia were present in the sample. RESULTS: Seventy-two tissue samples were obtained: EUS-guided tru-cut biopsy (n=16), jumbo biopsy of the post-EMR site (n=16), jumbo biopsy of the gastrotomy (n=16), serosal-side biopsy (n=16), and double-EMR resection (n=8). Only the double-EMR resection tissues showed the presence of longitudinal muscle, indicating the presence of both muscle layers and the myenteric plexus. Immunofluorescence studies demonstrated the presence of myenteric ganglia only in the double-EMR tissues and in none of the other gastric samples. No adjacent organs were included in the resection. CONCLUSIONS: The double-EMR technique was the only studied technique that resulted in a deep gastric-wall sample and provided sufficient tissue to evaluate both muscle layers and the intermuscular layer that contain myenteric ganglia. Further studies are needed to verify the efficacy and to assess the safety of this approach.