Onward Spread from Liver Metastases Is a Major Cause of Multi-Organ Metastasis in a Mouse Model of Metastatic Colon Cancer

Colorectal cancer metastasizes predominantly to the liver but also to the lungs and the peritoneum. The presence of extra-hepatic metastases limits curative (surgical) treatment options and is associated with very poor survival. The mechanisms governing multi-organ metastasis formation are incompletely understood. Here, we tested the hypothesis that the site of tumor growth influences extra-hepatic metastasis formation. To this end, we implanted murine colon cancer organoids into the primary tumor site (i.e., the caecum) and into the primary metastasis site (i.e., the liver) in immunocompetent mice. The organoid-initiated liver tumors were significantly more efficient in seeding distant metastases compared to tumors of the same origin growing in the caecum (intra-hepatic: 51 vs. 40%, p = 0.001; peritoneal cavity: 51% vs. 33%, p = 0.001; lungs: 30% vs. 7%, p = 0.017). The enhanced metastatic capacity of the liver tumors was associated with the formation of 'hotspots' of vitronectin-positive blood vessels surrounded by macrophages. RNA sequencing analysis of clinical samples showed a high expression of vitronectin in liver metastases, along with signatures reflecting hypoxia, angiogenesis, coagulation, and macrophages. We conclude that 'onward spread' from liver metastases is facilitated by liver-specific microenvironmental signals that cause the formation of macrophage-associated vascular hotspots. The therapeutic targeting of these signals may help to contain the disease within the liver and prevent onward spread.

Inhibition of RAF1 kinase activity restores apicobasal polarity and impairs tumour growth in human colorectal cancer

BACKGROUND AND AIM

Colorectal cancer (CRC) remains one of the leading causes of cancer-related death. Novel therapeutics are urgently needed, especially for tumours with activating mutations in KRAS (∼40%). Here we investigated the role of RAF1 in CRC, as a potential, novel target.

METHODS

Colonosphere cultures were established from human tumour specimens obtained from patients who underwent colon or liver resection for primary or metastatic adenocarcinoma. The role of RAF1 was tested by generating knockdowns (KDs) using three independent shRNA constructs or by using RAF1-kinase inhibitor GW5074. Clone-initiating and tumour-initiating capacities were assessed by single-cell cloning and injecting CRC cells into immune-deficient mice. Expression of tight junction (TJ) proteins, localisation of polarity proteins and activation of MEK-ERK pathway was analysed by western blot, immunohistochemistry and immunofluorescence.

RESULTS

KD or pharmacological inhibition of RAF1 significantly decreased clone-forming and tumour-forming capacity of all CRC cultures tested, including KRAS-mutants. This was not due to cytotoxicity but, at least in part, to differentiation of tumour cells into goblet-like cells. Inhibition of RAF1-kinase activity restored apicobasal polarity and the formation of TJs in vitro and in vivo, without reducing MEK-ERK phosphorylation. MEK-inhibition failed to restore polarity and TJs. Moreover, RAF1-impaired tumours were characterised by normalised tissue architecture.

CONCLUSIONS

RAF1 plays a critical role in maintaining the transformed phenotype of CRC cells, including those with mutated KRAS. The effects of RAF1 are kinase-dependent, but MEK-independent. Despite the lack of activating mutations in RAF1, its kinase domain is an attractive therapeutic target for CRC.

Maintenance of Clonogenic KIT(+) Human Colon Tumor Cells Requires Secretion of Stem Cell Factor by Differentiated Tumor Cells

BACKGROUND & AIMS

Colon tumors contain a fraction of undifferentiated stem cell-like cancer cells with high tumorigenic potential. Little is known about the signals that maintain these stem-like cells. We investigated whether differentiated tumor cells provide support.

METHODS

We established undifferentiated colonosphere cultures from human colon tumors and used them to generate stably differentiated cell lines. Antibody arrays were used to identify secreted factors. Expression of genes involved in stemness, differentiation, and the epithelial to mesenchymal transition was measured using reverse transcription quantitative polymerase chain reaction. Expression of KIT in human tumors was analyzed with gene expression arrays and by immunohistochemistry. Colonospheres were injected into the livers of CBy.Cg-Foxn1nu/J mice. After liver tumors had formed, hypoxia was induced by vascular clamping.

RESULTS

Differentiated cells from various tumors, or medium conditioned by them, increased the clonogenic capacity of colonospheres. Stem cell factor (SCF) was secreted by differentiated tumor cells and supported the clonogenic capacity of KIT(+) colonosphere cells. Differentiated tumor cells induced the epithelial to mesenchymal transition in colonosperes; this was prevented by inhibition of KIT or SCF. SCF prevented loss of clonogenic potential under differentiation-inducing conditions. Suppression of SCF or KIT signaling greatly reduced the expression of genes that regulate stemness and the epithelial to mesenchymal transition and inhibited clonogenicity and tumor initiation. Bioinformatic and immunohistochemical analyses revealed a correlation between expression of KIT- and hypoxia-related genes in colon tumors, which was highest in relapse-prone mesenchymal-type tumors. Hypoxia induced expression of KIT in cultured cells and in human colon tumor xenografts and this contributed to the clonogenic capacity of the tumor cells.

CONCLUSIONS

Paracrine signaling from SCF to KIT, between differentiated tumor cells and undifferentiated stem-like tumor cells, helps maintain the stem-like features of tumor cells, predominantly under conditions of hypoxia.

SIRT1/PGC1α-Dependent Increase in Oxidative Phosphorylation Supports Chemotherapy Resistance of Colon Cancer

PURPOSE

Chemotherapy treatment of metastatic colon cancer ultimately fails due to development of drug resistance. Identification of chemotherapy-induced changes in tumor biology may provide insight into drug resistance mechanisms.

EXPERIMENTAL DESIGN

We studied gene expression differences between groups of liver metastases that were exposed to preoperative chemotherapy or not. Multiple patient-derived colonosphere cultures were used to assess how chemotherapy alters energy metabolism by measuring mitochondrial biomass, oxygen consumption, and lactate production. Genetically manipulated colonosphere-initiated tumors were used to assess how altered energy metabolism affects chemotherapy efficacy.

RESULTS

Gene ontology and pathway enrichment analysis revealed significant upregulation of genes involved in oxidative phosphorylation (OXPHOS) and mitochondrial biogenesis in metastases that were exposed to chemotherapy. This suggested chemotherapy induces a shift in tumor metabolism from glycolysis towards OXPHOS. Indeed, chemotreatment of patient-derived colonosphere cultures resulted in an increase of mitochondrial biomass, increased expression of respiratory chain enzymes, and higher rates of oxygen consumption. This was mediated by the histone deacetylase sirtuin-1 (SIRT1) and its substrate, the transcriptional coactivator PGC1α. Knockdown of SIRT1 or PGC1α prevented chemotherapy-induced OXPHOS and significantly sensitized patient-derived colonospheres as well as tumor xenografts to chemotherapy.

CONCLUSIONS

Chemotherapy of colorectal tumors induces a SIRT1/PGC1α-dependent increase in OXPHOS that promotes tumor survival during treatment. This phenomenon is also observed in chemotherapy-exposed resected liver metastases, strongly suggesting that chemotherapy induces long-lasting changes in tumor metabolism that potentially interfere with drug efficacy. In conclusion, we propose a novel mechanism of chemotherapy resistance that may be clinically relevant and therapeutically exploitable.

Abstract 3773: Intestinal glutathione peroxidase (GPx2) promotes differentiation of colorectal cancer stem cells by modulating the rate of protein synthesis

Primary colorectal tumors and liver metastases can be established in vitro as colonosphere cultures. These 3D cultures are enriched in cancer stem cells (CSCs) and create phenocopies of the original patient tumor upon transplantation into mice. We have performed proteomics analysis of a series of colonosphere cultures and show high expression of the Wnt-target gene intestinal glutathione peroxidase (GPx2). GPx2 is a member of the GPx family of ROS scavenging enzymes but its function in colorectal cancer is not known. Excess oxidative damage in normal and cancer stem cell (SC) populations can lead to (C)SC exhaustion. Therefore, we tested whether GPx2 may play a role in colorectal CSC maintenance. We found that GPx2 is predominantly expressed by differentiated tumor cells in human colorectal tumors. A construct in which the GPx2-promoter drives GFP expression revealed that GPx2high cells express differentiation markers and proliferate rapidly, while GPx2low cells express stem cell markers (Oct4, Nanog, Sox2, OLFM4) and proliferate slowly. To study the function of GPX2 in CSC maintenance we generated GPx2 knockdown (kd) cultures. Depletion of GPX2 greatly increased the fraction of immature CSCs and inhibited cellular differentiation. GPx2-kd cells formed slowly growing tumors with high CSC content, while GPx2 overexpression resulted in the formation of rapidly proliferating well-differentiated tumors with low CSC content. Gene Set Enrichment Analysis (GSEA) using gene expression profiles of two independent series of colorectal tumors showed that GPx2 expression was inversely correlated with published gene signatures for immature cells (Nanog, Oct4 and Sox2 target genes) and for cell proliferation. Low expression of GPx2 also correlated with poor patient survival. To explore how GPX2 affects CSC maintenance we performed gene ontology analyses and found that GPx2 expression is most strongly correlated with genes governing protein synthesis. GPx2 knockdown resulted in strongly reduced ribosomal gene expression and reduced protein synthesis. Strikingly, chronic cycloheximide-mediated suppression of protein synthesis in colonosphere cultures also increased the pool of slow-cycling CSCs, similar to GPx2 knockdown. Taken together, our results identify the rate of protein synthesis as a critical new determinant of the CSC phenotype. By stimulating protein synthesis GPx2 drives the differentiation, proliferation and exhaustion of colorectal CSCs. Complete elucidation of this pathway may identify targets for differentiation-stimulating anti-cancer therapy.

Citation Format: Benjamin Emmink, Jamila Laoukili, Anna Kipp, Klaas Govaert, Szabolcs Fatrai, Andre Verheem, Regina Brigelius-Flohe, Connie Jimenez, Inne Borel Rinkes, Onno Kranenburg. Intestinal glutathione peroxidase (GPx2) promotes differentiation of colorectal cancer stem cells by modulating the rate of protein synthesis. [abstract]. In: Proceedings of the 104th Annual Meeting of the American Association for Cancer Research; 2013 Apr 6-10; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2013;73(8 Suppl):Abstract nr 3773. doi:10.1158/1538-7445.AM2013-3773

Comparative proteomics of colon cancer stem cells and differentiated tumor cells identifies BIRC6 as a potential therapeutic target

Patients with liver metastases from colon carcinoma show highly variable responses to chemotherapy and tumor recurrence is frequently observed. Therapy-resistant cancer stem cells have been implicated in drug resistance and tumor recurrence. However, the factors determining therapy resistance and tumor recurrence are poorly understood. The aim of this study was to gain insight into these mechanisms by comparing the proteomes of patient-derived cancer stem cell cultures and their differentiated isogenic offspring. We established colonosphere cultures derived from resection specimens of liver metastases in patients with colon cancer. These colonospheres, enriched for colon cancer stem cells, were used to establish isogenic cultures of stably differentiated nontumorigenic progeny. Proteomics based on one-dimensional gel electrophoresis coupled to nano liquid chromatography tandem MS was used to identify proteome differences between three of these paired cultures. The resulting data were analyzed using Ingenuity Pathway Software. Out of a total data set of 3048 identified proteins, 32 proteins were at least twofold up-regulated in the colon cancer stem cells when compared with the differentiated cells. Pathway analysis showed that "cell death " regulation is strikingly different between the two cell types. Interestingly, one of the top-up-regulated proteins was BIRC6, which belongs to the class of Inhibitor of Apoptosis Proteins. Knockdown of BIRC6 sensitized colon cancer stem cells against the chemotherapeutic drugs oxaliplatin and cisplatin. This study reveals that differentiation of colon cancer stem cells is accompanied by altered regulation of cell death pathways. We identified BIRC6 as an important mediator of cancer stem cell resistance against cisplatin and oxaliplatin. Targeting BIRC6, or other Inhibitors of Apoptosis Proteins, may help eradicating colon cancer stem cells.

Comparative proteomics of colon cancer stem cells and differentiated tumor cells identifies BIRC6 as a potential therapeutic target

Patients with liver metastases from colon carcinoma show highly variable responses to chemotherapy and tumor recurrence is frequently observed. Therapy-resistant cancer stem cells have been implicated in drug resistance and tumor recurrence. However, the factors determining therapy resistance and tumor recurrence are poorly understood. The aim of this study was to gain insight into these mechanisms by comparing the proteomes of patient-derived cancer stem cell cultures and their differentiated isogenic offspring. We established colonosphere cultures derived from resection specimens of liver metastases in patients with colon cancer. These colonospheres, enriched for colon cancer stem cells, were used to establish isogenic cultures of stably differentiated nontumorigenic progeny. Proteomics based on one-dimensional gel electrophoresis coupled to nano liquid chromatography tandem MS was used to identify proteome differences between three of these paired cultures. The resulting data were analyzed using Ingenuity Pathway Software. Out of a total data set of 3048 identified proteins, 32 proteins were at least twofold up-regulated in the colon cancer stem cells when compared with the differentiated cells. Pathway analysis showed that "cell death " regulation is strikingly different between the two cell types. Interestingly, one of the top-up-regulated proteins was BIRC6, which belongs to the class of Inhibitor of Apoptosis Proteins. Knockdown of BIRC6 sensitized colon cancer stem cells against the chemotherapeutic drugs oxaliplatin and cisplatin. This study reveals that differentiation of colon cancer stem cells is accompanied by altered regulation of cell death pathways. We identified BIRC6 as an important mediator of cancer stem cell resistance against cisplatin and oxaliplatin. Targeting BIRC6, or other Inhibitors of Apoptosis Proteins, may help eradicating colon cancer stem cells.

Differentiated human colorectal cancer cells protect tumor-initiating cells from irinotecan

BACKGROUND & AIMS

Stem cells of normal tissues have resistance mechanisms that allow them to survive genotoxic insults. The stem cell-like cells of tumors are defined by their tumor-initiating capacity and may have retained these resistance mechanisms, making them resistant to chemotherapy. We studied the relationship between resistance to the topoisomerase I inhibitor irinotecan and tumor-initiating potential in human colonosphere cultures and in mice with colorectal xenograft tumors.

METHODS

Colonosphere cultures were established from human colorectal tumor specimens obtained from patients who underwent colon or liver resection for primary or metastatic adenocarcinoma. Stem cell and differentiation markers were analyzed by immunoblotting and fluorescence-activated cell sorting. Clone- and tumor-initiating capacities were assessed by single-cell cloning and in immune-deficient mice. Sensitivity to irinotecan was assessed in vitro and in tumor-bearing mice. The relationship between drug resistance and tumor-initiating capacity was tested by fluorescence-activated cell sorting of colonosphere cells, based on expression of ABCB1 and aldehyde dehydrogenase (ALDH) activity.

RESULTS

Colonosphere cultures had a high capacity to initiate tumors in mice and were resistant to irinotecan. Inhibition of the drug-efflux pump ABCB1 by PSC-833 allowed irinotecan to eradicate tumor-initiating cells. However, ABCB1 was expressed only by a subpopulation of differentiated tumor cells that did not form clones or tumors. Conversely, tumor-initiating cells were ABCB1-negative and were identified by high ALDH activity. Tumorigenic ALDHhigh/ABCB1negative cells generated nontumorigenic ALDHlow/ABCB1positive daughter cells in vitro and in tumor xenografts. PSC-833 increased the antitumor efficacy of irinotecan in mice.

CONCLUSIONS

The resistance of colorectal tumors to irinotecan requires the cooperative action of tumor-initiating ALDHhigh/ABCB1negative cells and their differentiated, drug-expelling, ALDHlow/ABCB1positive daughter cells.

A role for CD95 signaling in ischemia/reperfusion-induced invasion and outgrowth of colorectal micrometastases in mouse liver

BACKGROUND

Ischemia/reperfusion (I/R) injury in the liver is associated with accelerated outgrowth of micrometastases. The aim of the study was to test the role of CD95 signaling in accelerated outgrowth of colorectal liver metastases following I/R.

METHODS

Mice underwent vascular clamping 5 days after induction of colorectal liver metastases. Invasion and outgrowth of micrometastases following I/R were analyzed by post-mortem confocal microscopy (36 hr post-I/R) and by morphometric assessment of tumor load (5 days post-I/R), respectively. Tumor cell CD95 was suppressed by lentiviral RNA interference. The contribution of host CD95L was assessed by using gld-mice lacking functional CD95L.

RESULTS

CD95-knockdown in tumor cells strongly reduced perinecrotic invasion (tumor diameter from ∼830 to ∼470 µm) and largely prevented outgrowth acceleration of perinecrotic liver metastases following I/R (from ∼8- to ∼4.5-fold). In gld-mice, the relative hepatic area with necrosis was markedly reduced. Perinecrotic tumor cell clusters still displayed an invasive phenotype (tumor diameter of ∼980 µm). However, I/R-induced acceleration of tumor outgrowth was reduced in gld-mice from ∼8- to ∼5-fold.

CONCLUSIONS

I/R induces invasion and accelerated outgrowth of preestablished metastases in a CD95-dependent manner. Activation of the CD95 system following I/R not only contributes to liver injury, but may also promote aggressive tumor recurrence.

Selective portal clamping to minimize hepatic ischaemia-reperfusion damage and avoid accelerated outgrowth of experimental colorectal liver metastases

BACKGROUND

Temporary vascular clamping during local ablation for colorectal liver metastases increases destruction volumes. However, it also causes ischaemia-reperfusion (IR) injury to the liver parenchyma and accelerates the outgrowth of microscopic tumour deposits. The aim of this study was to investigate the effects of selective portal clamping on hepatocellular damage and tumour growth.

METHODS

Mice carrying pre-established hepatic colorectal micrometastases underwent either simultaneous clamping of both the portal vein and the hepatic artery or selective clamping of the portal vein to the median and left liver lobes for 45 min. Sham-operated mice served as controls. Hepatic injury and tumour growth were assessed over time.

RESULTS

Standard inflow occlusion resulted in a rise in liver enzymes, a local inflammatory response and hepatocellular necrosis. The outgrowth of pre-established micrometastases was accelerated three- to fourfold in clamped compared with non-clamped liver lobes (27.4 versus 7.8 per cent, P < 0.010). Conversely, selective portal clamping induced minimal liver injury, tissue inflammation or hepatocellular necrosis, and completely stopped the accelerated outgrowth of micrometastases.

CONCLUSION

Selective portal clamping does not induce liver tissue damage or accelerate micrometastasis outgrowth and may therefore be the preferable clamping method during local ablative treatment of hepatic metastases.

Indomethacin disrupts the protective effect of phosphatidylcholine against bile salt-induced ileal mucosa injury

BACKGROUND

Indomethacin (Indo) exerts local toxic effects on small intestinal mucosa, possibly in association with hydrophobic bile salts. We investigated the potential toxic effects of Indo on ileal mucosa and the role of phosphatidylcholine (PC).

MATERIALS AND METHODS

Transmucosal resistance and Na-fluorescein permeability of ileal mucosa segments from female Wistar rats were determined in Ussing chambers during a 30-min incubation with model systems containing: control-buffer, taurodeoxycholate (TDC), Indo, TDC-Indo, TDC-PC, or TDC-PC-Indo. Decrease of resistance and increase of permeability were considered as parameters for mucosal injury. After incubation in Ussing chambers, the histopathology was examined to quantify the extent of mucosal injury. Also, in CaCo-2 cells, LDH-release was determined as a measure of cytotoxicity, after incubation with various model systems.

RESULTS

Decrease of resistance and increase of permeability were highest in systems containing TDC-Indo (P < 0.01). Phosphatidylcholine protected against the cytotoxic effects of TDC in absence of Indo only. Extent of mucosal injury by histological examination was also highest in systems containing TDC-Indo (P = 0.006). Again, PC exhibited protective effects in absence of Indo only. The LDH-release by CaCo2-cells was strongest in TDC-Indo systems (P < 0.001).

CONCLUSIONS

Indomethacin disrupts protective effects of PC against bile salt-induced ileal mucosa injury. This finding is relevant for small intestinal injury induced by non-steroidal anti-inflammatory drugs.

Interdigestive small bowel motility and duodenal bacterial overgrowth in experimental acute pancreatitis

The objective of this study is to investigate the effects of an acute necrotizing pancreatitis (ANP), without biliary obstruction, on the migrating motor complex (MMC), small bowel bacterial overgrowth (SBBO), bacterial translocation (BT) and infection of the pancreas simultaneously. Rats were divided into four groups: mild pancreatitis, control, ANP and sham operated control. Jejunal myoelectrodes were used to measure MMCs. Blood, peritoneal fluid, bile, and abdominal organs were harvested for microbial culturing 72 h after induction of pancreatitis. The splenic portion of the pancreas was taken for histology. During ANP the MMC cycle length was significantly increased from 14.1 +/- 0.2 to 22.4 +/- 1.9 min (P < 0.05). The duodenum of ANP rats was in contrast with the other groups characterized by Enterobacteriacae (> 3 log 10 CFU g-1 in seven of 12 rats, P < 0.05). A positive correlation (r = 0.78, P < 0.01) existed between duodenal Gram-negative and anaerobic flora and the MMC cycle. Correlation between MMC cycle length and BT to the pancreas was positive as well (r = 0.70, P < 0.01). A positive correlation (r = 0.85, P < 0.01) was found between the severity of pancreatitis and duodenal bacterial overgrowth. During ANP without biliary obstruction, the jejunal MMC is disturbed and consequently SBBO occurs. The correlation between the severity of pancreatitis, the disturbance of the MMC and SBBO suggests an important pathophysiological role of the proximal small bowel in the infection of pancreatic necrosis.

Bacterial overgrowth and translocation in an experimental pancreatitis model

Background

A combination of secretory hyperstimulation and transduodenal intraductal bile acid exposure results in homogeneous pancreatitis with graded severity in a rat model. The model was modified by using an exteriorized common bile duct (CBD) as ductal infusion port while keeping the integrity of the gut intact. The objective was to determine whether bacterial translocation (BT) is present and relates to small bowel bacterial overgrowth (SBBO).

Methods

Fifty rats were divided into four groups: group 1, mild pancreatitis (intravenous caerulein); group 2, control (intravenous saline); group 3, necrotic pancreatitis (intravenous caerulein, intraductal glycodeoxycholic acid); and group 4, control (intravenous and intraductal saline). During infusion the CBD was clamped just above the papilla of Vater. Three days later samples from peripheral blood, peritoneal fluid and abdominal organs were harvested for quantitative microbial culturing. The splenic portion of the pancreas was removed for histopathological analysis.

Results

Histological examination showed minimal oedema in groups 2 and 4; group 1 was characterized by acinar vacuolization and group 3 had a combination of acinar necrosis with inflammation. BT to one or more abdominal organs took place. The difference in incidence of translocation between group 1 (six of 14) and group 2 (none of eight) was significant (P &lt; 0·05). Furthermore, there was a significant difference in translocation between group 3 (six of eight) and group 4 (one of six) (P &lt; 0·05), and in duodenal total bacterial counts between groups 3 and 4 (P &lt; 0·05). Gram-negative rods and anaerobic bacterial counts were different between group 3 (mean(s.d.) 2·46(0·88)) and group 4 (0) (P &lt; 0·05). However, total bacterial growth in the ileum did not differ significantly between groups.

Conclusion

In this pancreatitis model, without biliary obstruction, bacterial overgrowth of the duodenum occurred, accompanied by BT. Colonic bacteria were predominantly involved. This model offers the possibility of studying the relationship between SBBO, BT and the pathogenesis of necrotic (infected) pancreatitis.

The effects of ABT-229 and octreotide on interdigestive small bowel motility, bacterial overgrowth and bacterial translocation in rats

BACKGROUND

Interdigestive small bowel motility has a regulatory function on the microflora of the upper small bowel. Here we investigate the effects of ABT-229 and octreotide on morphine-induced dysmotility, the accompanying bacterial overgrowth and bacterial translocation.

METHODS

Rats were fitted with jejunal myoelectrodes and a subcutaneous cannula for continuous infusion of saline or morphine. Fasting motility was measured for 6 h on four occasions: one control measurement (day 0) and three measurements on consecutive days (days 1-3) while receiving saline alone (group A), morphine alone (group B), saline + ABT-229 (group C), morphine + ABT-229 (group D), saline + octreotide (group E) or morphine + octreotide (group F). Samples from the mesenteric lymph node complex (MLN), liver, spleen, duodenum and ileum were taken for quantitative microbial culturing on day 4.

RESULTS

Neither ABT-229 nor octreotide increased the number of propagated activity fronts during saline infusion. During morphine-induced dysmotility, ABT-229 induced more propagated activity fronts in group D (13.4, 9.8 and 8.8 per 6 h) than in group B (7.0, 4.5, 3.8 per 6 h) on days 1, 2 and 3 (P < 0.05 for all days) Octreotide did not induce more propagated activity fronts. Disruption of small bowel motility by morphine led to bacterial overgrowth in the duodenum. ABT-229 and octreotide did not reduce the bacterial growth levels. The total incidence of bacterial translocation was significantly higher in the morphine-treated animals than in the saline-treated animals. Neither ABT-229 nor octreotide reduced the bacterial translocation incidence. The number of propagated activity fronts on day 3 and duodenal bacterial growth correlated significantly in groups A, E and F.

CONCLUSIONS

ABT-229, but not octreotide, reduced morphine induced dysmotility. Small bowel bacterial overgrowth and bacterial translocation were not prevented. Fasting small bowel motility has a regulatory function on the intestinal microflora of the upper small bowel.

The role of interdigestive small bowel motility in the regulation of gut microflora, bacterial overgrowth, and bacterial translocation in rats

OBJECTIVE

To clarify the role of the migrating motor complex (MMC) in the regulation of small intestinal microflora and bacterial translocation.

SUMMARY BACKGROUND DATA

The intestinal microflora may serve as a source of infectious microorganisms. Failure of regulatory mechanisms of the intestinal flora could therefore play an important role in the pathogenesis of gut-derived infections.

METHODS

Rats were fitted with small intestinal myoelectrodes. MMCs were measured on a control day and 3 consecutive days during continuous administration of morphine or placebo. Mesenteric lymph nodes, liver, spleen, peripheral blood, duodenum, and ileum samples were cultured quantitatively.

RESULTS

The mean MMC cycle length in placebo-treated animals was 15.1+/-0.5 minutes. MMCs were completely disrupted after morphine treatment. Total bacterial growth in the duodenum was 7.27+/-0.34 10log colony-forming units (CFU)/g with placebo and 8.28+/-0.27 CFU/g with morphine. In placebo-treated animals, the mean MMC cycle length the day before culturing correlated with total bacterial growth in the duodenum. Translocation incidences to the mesenteric lymph nodes, liver, spleen, and blood were 0/8, 1/8, 0/8, and 0/8 with placebo and 7/8, 6/8, 5/8, and 0/8 with morphine. The overall translocation incidence was 1/8 in placebo-treated animals and 8/8 in morphine-treated animals.

CONCLUSIONS

The MMC is an important mechanism controlling bacterial growth in the upper small bowel. Its disruption with morphine promotes duodenal bacterial overgrowth and bacterial translocation.

Disrupted bile flow affects interdigestive small bowel motility in rats

BACKGROUND

The role of bile flow in the regulation of small bowel motility and the migrating myoelectric complex (MMC) is unclear. We aimed to study the effects of biliary diversion or obstruction on the MMC in a newly developed rat model.

METHODS

In rats, myoelectrodes were implanted in the jejunum, and the proximal common bile duct (CBD) was cannulated and exteriorized at the head, enabling us to manipulate biliary flow without influencing pancreatic flow and without the need of anesthesia or additional surgery. Group A were controls without CBD cannulas. Biliary circulation was exteriorized but kept intact in group B; bile was diverted externally in group C; and the CBD was obstructed in group D. MMCs were recorded in unrestrained conditions by jejunal electromyography before and after biliary diversion or obstruction. Spontaneous recanalization of the CBD was monitored by measurement of serum bilirubin and by cholangiography.

RESULTS

Exteriorization of the CBD without interruption of bile flow did not affect MMC duration (group A, 17.3 +/- 0.3 minutes [mean +/- SEM]; group B, 16.5 +/- 0.6 minutes). MMCs disappeared temporarily after CBD obstruction but not after biliary diversion. MMCs of increased duration were seen after 1 day in rats with biliary diversion or CBD obstruction (group C, 26.1 +/- 4.4 minutes; group D, 36.3 +/- 4.8 minutes [p < 0.05]). MMCs after biliary diversion or obstruction were characterized by an increased duration of phase II-like activity and decreased duration of phase I activity.

CONCLUSIONS

We conclude that MMCs disappear temporarily early after CBD obstruction, but MMCs of increased duration are seen after 1 day of biliary diversion or obstruction. Thus disrupted bile flow affects interdigestive small bowel motility in rats.

Effect of bile salts on in vitro gallbladder motility: preliminary study

Impaired postprandial gallbladder emptying may be an important factor in cholesterol crystals precipitation and subsequent gallstone formation. We previously found strongly increased bile salt concentrations in gallbladder bile of gallstone patients with weak (< 50% fasting volume) postprandial gallbladder contraction compared to patients with strong (> 50%) postprandial contraction. Therefore, we studied potential effects of various conjugated and unconjugated bile salts with different relative hydrophobicity on in vitro contractility of gallbladder muscle strips obtained at cholecystectomy. Strips were incubated 5 min with bile salt at concentrations of 10(-8)-10(-4)M. The effect of 10(-3)M acetylcholine was measured and related to preincubation control value. Bile salts used were, in order of increasing hydrophobicity: tauroursodeoxy-, ursodeoxy-, tauro-, taurodeoxy- and deoxycholate. Ursodeoxy- and tauroursodeoxycholate did not significantly reduce gallbladder contractility. Taurocholate significantly reduced contractility at concentrations of 10(-6) M and higher, taurodeoxycholate at 10(-7) M and higher and deoxycholate at 10(-5) M and higher. Contractility induced by acetylcholine 10(-3) M at a bile salt concentration of 10(-4) M was 66.0 +/- 11.7% (taurocholate), 50.2 +/- 6.2% (deoxycholate) and 44.8 +/- 11.5% (taurodeoxycholate) of control. The effect of bile salts correlated with their relative hydrophobicity (r = -0.97; p < 0.01). Suppressing effects on gallbladder muscle strip contractility were long lasting and remained after rinsing. Results show that bile salts in the physiological dose range inhibit in vitro gallbladder contraction. If this mechanism exists in vivo, it may have important implications for gallbladder motility regulation.

Proton magnetic resonance imaging in experimental cerebral ischaemia

MRI was performed on 11 primates, 7 with a proximal and 4 with a distal MCA occlusion. Chronic implanted electrodes created only minor image disturbances. The development of oedema formation was visualised in repetitive imaging. The site of the MCA occlusion determined the infarct-size.