Deoxycholic Acid-Derived Tetraoxane Antimalarials and Antiproliferatives

The synthesis of deoxycholic acid (DCA)- and cholic acid (CA)-derived mixed tetraoxanes revealed that N-(2-dimethylamino)ethyl derivatives are potent antimalarials in vitro and in vivo. The tetraoxanes presented in this paper are dual inhibitors: besides curing mice in vivo without observed toxic effects, they kill cancer cell lines at very low concentrations. For example, DCA and CA derivatives 16 and 25 cured 3/5 (160 mg/kg/day) and 2/5 (40 mg/kg/day, MTD >960 mg/kg), respectively, and they were extremely active against melanoma LOX IMVI cancer, LC50 = 22 nM and 69 nM, respectively.

The use of High Performance Thin-Layer Chromatography to determine the role of membrane lipid composition in bile salt-induced kidney cell damage

INTRODUCTION

In obstructive liver disease bile salts are known to accumulate in and damage specific kidney cells. High Performance Thin-Layer Chromatography (HPTLC) was used to determine the membrane lipid composition of a range of kidney cells.

METHODS

Kidney cells were exposed to three hydrophobic bile salts (lithocholic, deoxycholic and chenodeoxycholic acids) and cytotoxicity was determined. In addition membrane lipids from the cells were extracted in a chloroform:methanol (2:1, v/v) solution and quantified by HPTLC.

RESULTS

The results reveal a differential toxicity to the bile acids with IC(50) values ranging from 79+/-5 microM to 394+/-13 microM. When the lipid composition of the most and least susceptible cells were assayed, the least susceptible cells had a much higher lipid composition (46.6+/-3.7 microg/mg protein compared to 28.1+/-5.2 microg/mg protein for the least susceptible cells).

DISCUSSION

These results suggest that HPTLC may be a useful technique when determining the mechanisms of toxicity of compounds which cause the disruption of the cell membrane.

Tissue engineering of heart valves: biomechanical and morphological properties of decellularized heart valves

BACKGROUND AND AIM OF THE STUDY

Biological scaffolds are widely used in the process of cardiac valve tissue engineering. Scaffold characteristics are decisive for valve durability. Herein, the influence of three different decellularization protocols on the morphological and biomechanical properties of porcine pulmonary valve conduits was evaluated.

METHODS

Pulmonary valve conduits were decellularized with 1% sodium deoxycholate (SD), 1% sodium dodecylsulfate (SDS), or 0.05% trypsin/0.02% EDTA. The degree of decellularization and morphological integrity of the treated pulmonary valve cusp, wall and myocardial cuff were analyzed with hematoxylin and eosin staining, Movat-Pentachrome staining, electron microscopy, and DNA assay. The conservation of extracellular matrix (ECM) proteins was evaluated by immunohistochemical staining against collagens I and IV, and laminin. The biomechanical properties of the obtained scaffolds were evaluated using uniaxial tension tests. Native grafts served as controls.

RESULTS

All treatments resulted in complete decellularization of the cusp, whereas only SD and SDS treatments were able to remove completely all cells from the pulmonary valve wall and subvalvular myocardial cuff. The morphological integrity and preservation of ECM proteins was clearly superior in both detergent-treated groups. Enzyme treatment resulted in destruction of the basement membrane. Wall longitudinal tension parameters (stiffness, elasticity modulus, ultimate force; stress and strain) were significantly inferior in the trypsin/EDTA group (p < 0.05). No significant differences were observed between detergent-treated and native samples. The results of transversal tension parameters were comparable in all groups.

CONCLUSION

Both, SD and SDS treatment of the pulmonary valve may better preserve the morphological and biomechanical properties of the scaffold than the chosen enzymatic treatment. In the authors' opinion, detergent-based decellularization should be used in preference to enzyme treatment in the tissue engineering of heart valves.

Novel cytotoxic agents from an unexpected source: bile acids and ovarian tumor apoptosis

OBJECTIVE

Unique biologic activities have been identified for the 4 different bile acids: cholic acid (CA, chenodeoxycholic acid (CDCA), deoxycholic acid (DCA), and ursodeoxycholic acid (UDCA). The aim of this study was to examine and compare the effects of these 4 bile acids on the human ovarian cancer cell lines A2780 and A2780-CP-R(cisplatin-resistant) and to evaluate mechanisms of action.

METHODS

Antiproliferative effects were determined by the cytotoxic MTT assay. Cells undergoing apoptosis were identified by morphologic analysis of cells stained using Diff-Quick and nuclear staining with DAPI and by quantitative nucleosome ELISA assay. Cells were lysed in buffer after 24 h of exposure to three different concentrations of bile acid (50 mM, 200 mM, and 400 mM) and protein concentrations were determined. Cell extracts containing 25 mg of protein were assayed for protein kinase C (PKC) enzyme activity.

RESULTS

None of the bile acids stimulated proliferation of ovarian cancer cells. CA and UDCA had only minimal cytotoxic effect even at maximum concentrations. In contrast, DCA and CDCA administration resulted in statistically significant dose-dependent cytotoxicity in both platinum sensitive and platinum-resistant cell lines (p<0.05). Cells incubated with DCA and CDCA exhibited morphologic features characteristic of apoptosis. The quantitative nucleosome ELISA assay demonstrated over 10 times increased nucleosome levels after cells were treated for 24 h by DCA and CDCA at 200 mM and 400 mM as compared to CA or UDCA treatment and to untreated controls (p<0.01). All 4 bile acids reduced PKC activity at concentrations of 200 and 400 mM (p<0.01).

CONCLUSIONS

CDCA and DCA have significant cytotoxic activity in ovarian cancer cells via induction of apoptosis. The mechanism of apoptosis appears to be mediated by alternative kinases distinct from PKC. CDCA and DCA may have clinical utility in the treatment of ovarian cancer pending in vivo confirmation of activity especially in cisplatin-resistant disease.

Prevention of deoxycholate-induced gastric apoptosis by aspirin: roles of NF-kappaB and PKC signaling

BACKGROUND

Apoptosis is a major mechanism of gastric cell death induced by deoxycholate (DC) and aspirin (ASA), and the caspase cascade and protein kinase C (PKC) signaling play key roles in this process. The transcription factor kappa B (NF-kappaB) has been shown to modulate apoptosis by regulating the transcription of numerous pro- and anti-apoptotic genes. The aim of this study was to investigate the effect of DC and ASA on NF-kappaB signaling, and determine its role in programmed cell death in a human gastric carcinoma cell line.

METHODS

Cells were incubated with DC in the presence or absence of ASA or proteasome inhibitors (PI- I, lactacystin, and MG-132). Cell lysates were evaluated by Western blotting. NF-kappaB (p65) was measured in the cytosol and nuclear fractions.

RESULTS

DC induced a translocation of NF-kappaB into the nuclear compartment that was completely blocked by proteasome inhibitors. Although, ASA itself had no effect on the NF-kappaB pathway, nor did it reduce DC-induced NF-kappaB translocation, it did prevent DC-induced caspase-3, -6 and -9 activation, poly (ADP-ribose) polymerase and lamin A processing, DNA degradation, and PKC signaling, all indices of apoptosis. In contrast, proteasome inhibitors had no effect on DC-induced apoptosis.

CONCLUSIONS

Deoxycholate activates NF-kappaB at the same time that it induces apoptosis in gastric epithelial cells. Prevention of NF-kappaB activation does not alter DC-induced apoptosis, indicating that in our experimental conditions, NF-kappaB is not essential for apoptosis to proceed. In contrast, the ability of aspirin to restore the alterations in PKC isoforms induced by DC and at the same time prevent caspase cascade activation suggests the importance of the PKC signaling system in this process.

Novel localization of Rab3D in rat intestinal goblet cells and Brunner's gland acinar cells suggests a role in early Golgi trafficking

Rab3D is a small GTP-binding protein that associates with secretory granules of endocrine and exocrine cells. The physiological role of Rab3D remains unclear. While it has initially been implicated in the control of regulated exocytosis, recent deletion-mutation studies have suggested that Rab3D is involved in the biogenesis of secretory granules. Here, we report the unexpected finding that Rab3D also associates with early Golgi compartments in intestinal goblet cells and in Brunner's gland acinar cells. Expression of Rab3D in the intestine was demonstrated by SDS-PAGE and Western blot analysis of homogenates prepared from the rat duodenum and colon. Confocal laser scanning microscopy revealed Rab3D immunofluorescence in the Golgi area of goblet cells of the duodenum and colon and in Brunner's gland acinar cells. There was no colocalization between Rab3D and a trans-Golgi network marker, TGN-38. In contrast, Rab3D colocalized partially with a cis-Golgi marker, GM-130, and with a marker of cis-Golgi and coat protein complex I vesicles, beta-COP. Strong colocalization was observed between Rab3D and the lectins Griffonia simplicifolia agglutinin II and soybean agglutinin, which have been described as markers of the medial and cis-Golgi, respectively. Rabphilin, a putative effector of Rab3D, displayed an identical pattern of Golgi localization. Incubation of colon tissue with carbamylcholine or deoxycholate to stimulate exocytosis by goblet cells caused a partial redistribution of Rab3D to the cytoplasm and mucous granule field and a concomitant transformation of the Golgi architecture. Taken together, the present data suggest that Rab3D and rabphilin may regulate the secretory pathway at a much earlier stage than what has hitherto been assumed.

Downregulation of p63 upon exposure to bile salts and acid in normal and cancer esophageal cells in culture

p63 is a member of the p53 protein family that regulates differentiation and morphogenesis in epithelial tissues and is required for the formation of squamous epithelia. Barrett's mucosa is a glandular metaplasia of the squamous epithelium that develops in the lower esophagus in the context of chronic, gastroesophageal reflux and is considered as a precursor for adenocarcinoma. Normal or squamous cancer esophageal cells were exposed to deoxycholic acid (DCA, 50, 100, or 200 microM) and chenodeoxycholic and taurochenodeoxycholic acid at pH 5. p63 and cyclooxygenase-2 (COX-2) expressions were studied by Western blot and RT-PCR. DCA exposure at pH 5 led to a spectacular decrease in the levels of all isoforms of the p63 proteins. This decrease was observed within minutes of exposure, with a synergistic effect between DCA and acid. Within the same time frame, levels of p63 mRNA were relatively unaffected, whereas levels of COX-2, a marker of stress responses often induced in Barrett's mucosa, were increased. Similar results were obtained with chenodeoxycholic acid but not its taurine conjugate at pH 5. Proteasome inhibition by lactacystin or MG-132 partially blocked the decrease in p63, suggesting a posttranslational degradation mechanism. These results show that combined exposure to bile salt and acid downregulates a critical regulator of squamous differentiation, providing a mechanism to explain the replacement of squamous epithelium by a glandular metaplasia upon exposure of the lower esophagus to gastric reflux.

Conjugated bile acids regulate hepatocyte glycogen synthase activity in vitro and in vivo via Galphai signaling

The regulation of glycogen synthase activity by bile acids in primary hepatocytes and in the intact liver was investigated. Bile acids (deoxycholic acid, DCA; taurocholic acid, TCA) activated AKT and glycogen synthase (GS) in primary rat hepatocytes. Incubation with a phosphatidyl inositol-3 kinase inhibitor or expression of dominant-negative AKT in primary rat hepatocytes abolished activation of AKT and GS by DCA and TCA. TCA, but not DCA, activated Galpha(i) proteins in primary rat hepatocytes. Treatment of cells with pertussis toxin or expression of dominant-negative Galpha(i) blocked TCA-induced activation of AKT and of GS but did not alter AKT or GS activation caused by DCA. TCA caused activation of AKT and GS in intact rat liver. Expression of dominant-negative Galpha(i) reduced TCA-induced activation of AKT and of GS in intact rat liver. Together, our findings demonstrate that bile acids are physiological regulators of glycogen synthase in rat liver and that conjugated bile acids use a Galpha(i)-coupled G protein-coupled receptor to regulate GS activity in vitro and in vivo.

Characterization of Minaçu virus (Reoviridae: Orbivirus) and pathological changes in experimentally infected newborn mice

Minaçu virus was isolated from Ochlerotatus scapularis (Diptera: Culicidae) in Minaçu, Goiás State, Brazil, in 1996. In attempting characterization of virus serological (hemagluttination inhibition, HI; indirect immunofluorescence assay, IFA), physicochemical [test for deoxycholate acid (DCA) sensitivity; polyacrylamide gel electrophoresis (PAGE)] tests and ultrastructural studies were made. Virus was also assayed in suckling mice after intracerebral inoculation of 0.02 ml and in VERO and C6/36 cells with 0.1 ml of viral suspension containing 10(5) LD50/ml. Inoculated and control systems were observed daily. Every 24 h, one control and two inoculated animals were killed for tissue testing, including histopathological changes by haematoxylin and eosin (HE)-stained sections, which were semi-quantified. Research into viral antigen in the tissues of mice [central nervous system (CNS), liver, heart, lungs, spleen and kidneys] was carried out by the immunohistochemical technique using the peroxidase system. The virus only replicated in VERO cells, with antigen positive by IFA. Positive complement fixation tests were only obtained using antiserum of Minaçu virus. Minaçu virus is DCA resistant; haemagglutinating activity was negative. By electronic microscopy non-enveloped virus particles were 75 nm in diameter. PAGE analysis showed Minaçu virus genome profile with 10 RNA segments. Infected, non-killed animals died 7 days after inoculation. Tissue lesions were observed in all organs, except the lungs. Intense lesions were observed in the CNS and the heart, where neurone and cardiocyte necroses, respectively, were noted. The liver, spleen and kidneys had moderate tissue changes. Viral antigens were more abundant in the CNS and the heart, and absent in the lungs. In conclusion, Minaçu virus belongs to the family Reoviridae, genus Orbivirus.

Action of sodium deoxycholate on subcutaneous human tissue: local and systemic effects

BACKGROUND

Phosphatidylcholine injections have been used as a nonsurgical alternative to the surgical removal of undesired fat. Studies in cell culture suggest that sodium deoxycholate (SD) has a detergent action in fat reduction.

OBJECTIVE

The objective was to study SD in subcutaneous human tissue.

METHODS AND MATERIALS

Thirty volunteers underwent four sessions of subcutaneous abdominal injections of diluted 2.5 or 1% SD stock solutions or placebo. Clinical, hematologic, and ultrasonographic evaluations were performed for 3 months and histology at 3 and 6 months.

RESULTS

Both concentrations of SD induced an inflammatory response at the injection site, with dose-dependent adipocyte lysis. Patients reported mild, localized heat, erythema, swelling, and intense pain. Microscopic evaluation revealed necrosis of adipose tissue with adipocyte lysis, fat dissolution, acute lymphomononuclear inflammatory reaction, and intense phagocytosis of fat cells by macrophages. Fibrosis was observed only at the 6-month biopsy. Nodules at the injection sites, compatible with areas of inflammation, were detected by ultrasonography 2 weeks after the first injection. Placebo injections induced no histologic changes.

CONCLUSIONS

SD induces an inflammatory reaction in subcutaneous human fat and dose-dependent adipocyte lysis with acute pain and fibrosis. No systemic effects were detected. Further studies will establish the best dose-result ratio, frequency of application, and long-term safety.

Cloning, purification, and identification of the liver canalicular ecto-ATPase as NTPDase8

Extracellular nucleotides regulate critical liver functions via the activation of specific transmembrane receptors. The hepatic levels of extracellular nucleotides, and therefore the related downstream signaling cascades, are modulated by cell-surface enzymes called ectonucleotidases, including nucleoside triphosphate diphosphohydrolase-1 (NTPDase1/CD39), NTPDase2/CD39L1, and ecto-5'-nucleotidase/CD73. The goal of this study was to determine the molecular identity of the canalicular ecto-ATPase/ATPDase that we hypothesized to correspond to the recently cloned NTPDase8. Human and rat NTPDase8 cDNAs were cloned, and the genes were located on chromosome loci 9q34 and 3p13, respectively. The recombinant proteins, expressed in COS-7 and HEK293T cells, were biochemically characterized. NTPDase8 was also purified from rat liver by Triton X-100 solubilization, followed by DEAE, Affigel Blue, and concanavalin A chromatographies. Importantly, NTPDase8 was responsible for the major ectonucleotidase activity in liver. The ion requirement, apparent K(m) values, nucleotide hydrolysis profile, and preference as well as the resistance to azide were similar for recombinant NTPDase8s and both purified rat NTPDase8 and porcine canalicular ecto-ATPase/ATPDase. The partial NH(2)-terminal amino acid sequences of all NTPDase8s share high identity with the purified liver canalicular ecto-ATPase/ATPDase. Histochemical analysis showed high ectonucleotidase activities in bile canaliculi and large blood vessels of rat liver, in agreement with the immunolocalization of NTPDase1, 2, and 8 with antibodies developed for this study. No NTPDase3 expression could be detected in liver. In conclusion, NTPDase8 is the canalicular ecto-ATPase/ATPDase and is responsible for the main hepatic NTPDase activity. The canalicular localization of this enzyme suggests its involvement in the regulation of bile secretion and/or nucleoside salvage.

Adaptive response to increased bile acids: induction of MDR1 gene expression and P-glycoprotein activity in renal epithelial cells

Cholestatic liver disease and increased serum bile acid concentrations are known to trigger various adaptive responses including the induction of hepatic, intestinal and renal bile acid transport proteins, but renal P-glycoprotein (Pgp, multidrug resistance protein 1, MDR1) remained uninvestigated in this context. We show that treatment of Madin Darby canine kidney (MDCK) cells with pathophysiologically relevant concentrations of chenodeoxycholic acid (CDCA; 100 microM) for 12 h induces MDR1 transcript levels in vitro more than twofold. CDCA and deoxycholic acid pre-treatment for 24-96 h (100 microM) also increased Pgp activity measured as rhodamine efflux, while cholic acid and taurocholic acid were not effective in concentrations up to 600 microM. CDCA pre-treatment (100 microM, 72 h) also resulted in a doubling of rhodamine123 secretion across an epithelium-like monolayer grown on Transwell filters and decreased the sensitivity towards the kidney toxic drugs cyclosporine A and paclitaxel. These findings predict physiologically as well as pharmacologically relevant consequences of liver disease for Pgp substrate transport and toxicity in the kidneys.

Icodextrin Peritoneal Transport In Vitro: Effect of Sodium Deoxycholate, Glucose, and Methylglyoxal

The aim of the in vitro studies was to examine the effect of sodium deoxycholate, glucose, and methylglyoxal on icodextrin peritoneal transfer. The rabbit peritoneum in a modified Ussing chamber was an experimental model. Transport and morphometric analyses were performed. In the first of them, the icodextrin (7.5 g/dL) diffusion from the mesothelial to the interstitial side of the membrane, expressed as a diffusive permeability coefficient (P), was evaluated in the control stage, after chemical modification of the membrane using sodium deoxycholate (104 mg/dL), after the addition of glucose (1.8 g/dL) and methylglyoxal (1 mg/dL), in the separate experimental series. In the second morphometric studies, the thickness and transverse cross-section surface area of native tissue, in 75 min of experiment and after application of sodium deoxycholate, were investigated. In the control conditions, the rate of glucose polymer passage remained constant. A mean value of P +/- SD was 0.194 +/- 0.126 (x10(-4), cm/s) during 120 min of the study. The transfer of icodextrin was enhanced by 224% after 3 min of incubation of the peritoneum with sodium deoxycholate. The introduction of glucose into the circulating medium with icodextrin caused the increase of P values for glucose polymer by 94% during 60 min. In the same conditions, the usage of methylglyoxal did not change transport parameters. Both thickness and transverse cross-section surface area of the native tissue in 75 min of the study did not differ. It was 4.87 microm and 12.50 x 10(2) microm(2) for the mesothelial layer, and 63.83 microm and 208.10 x 10(2) microm(2) for the whole peritoneal membrane. The application of sodium deoxycholate caused the decrease of mesothelium thickness by 20% but the increase of thickness and transverse cross-section surface area of the peritoneum by 37% in comparison with 75 min of experiment. In conclusion, sodium deoxycholate and glucose, but not methylglyoxal, intensify peritoneal transport of icodextrin in vitro. These modifications are probably connected with the exfoliation of the mesothelium and looseness of the interstitium caused by sodium deoxycholate as well as the physical and metabolic influence of glucose on the peritoneum.

Bile acid-induced secretion in polarized monolayers of T84 colonic epithelial cells: Structure-activity relationships

Bile acid epimers and side-chain homologues are present in the human colon. To test whether such bile acids possess secretory activity, cultured T84 colonic epithelial cells were used to quantify the secretory properties of synthetic epimers and homologues of deoxycholic acid (DCA) and chenodeoxycholic acid (CDCA). In our study, chloride secretion was measured as changes in short-circuit current (DeltaI(sc), in microA/cm2) with the use of voltage-clamped monolayers of T84 cells mounted in Ussing chambers. Bile acids were added at 0.5 mM, a concentration that did not alter transepithelial resistance. Data were expressed as peak DeltaI(sc) (means +/- SD). When added bilaterally, DCA stimulated a DeltaI(sc) response of 15.7 +/- 12.5 microA/cm2. The 12beta-OH epimer of DCA was less potent (DeltaI(sc) = 8.0 +/- 1.7 microA/cm2), whereas its 3beta-OH epimer had no effect. CDCA stimulated secretion (DeltaI(sc) = 8.2 +/- 5.5 microA/cm2), whereas both its 7beta-OH and 3beta-OH epimers were inactive, as was lithocholic acid. HomoDCA (1 additional side-chain carbon) was active (DeltaI(sc) = 7.8 +/- 4.8 microA/cm2), whereas norDCA (1 fewer carbon) and dinorDCA (2 fewer carbons) were not. Taurine conjugates of DCA and CDCA stimulated secretion (DeltaI(sc) = 12.3 +/- 7.5 and 8.8 +/- 4.8 microA/cm2, respectively) from the basolateral side but not the apical side. Uptake of taurine conjugates from the basolateral but not the apical side was shown by mass spectrometry. These studies indicate marked structural specificity for bile acid-induced chloride secretion and show that modification of bile acid structure by colonic bacteria modulates the secretory properties of these endogenous secretagogues.

Factors affecting icodextrin peritoneal transport in vitro

We undertook in vitro experiments to examine the importance of mesothelium and interstitium in icodextrin (7.5 g/dL) transport and the change in that transport caused by gentamicin and methylglyoxal. Rabbit peritoneum, a modified Ussing chamber and a mathematical model of mass transport were used. Transfer from the interstitial to mesothelial side of the membrane (I-->M) and in the opposite direction (M-->I), expressed as a diffusive permeability coefficient P, was determined in control series, after chemical modification of the peritoneum by sodium deoxycholate, and after introduction of gentamicin and methylglyoxal. We also investigated the thickness of native tissue 75 minutes into the study and after use of sodium deoxycholate. In the control series, icodextrin I-->M transport increased by 50%, but M-->I transport remained stable [15-60 min vs. 75-120 min. I-->M P, 0.32 +/- 0.04 x 10(-4) cm x s(-1) (standard error of the mean); M-->I P, 0.19 +/- 0.03 x 10(-4) cm x s(-1)]. After application of sodium deoxycholate, I-->M transport was observed to increase by 21% and M-->I by 192% as compared with the 2nd hour of the control series. Gentamicin caused a rise of M-->I transport by 21% without a change of I-->M. We observed no difference in p values (I-->M and M-->I) after application of methylglyoxal. Mean thickness before and 75 minutes into the study was 4.96 +/- 0.28 microm for mesothelium and 62.09 +/- 2.40 microm for the whole peritoneum. Sodium deoxycholate reduced the mesothelium thickness by 20% and increased the peritoneum thickness by 37%. The present study confirms that, in vitro, icodextrin I-->M peritoneal transport changes with time, but M-->I is constant. Asymmetry of glucose polymer diffusion is observed. I-->M predominates over M-->I. Chemical modification of the peritoneum by sodium deoxycholate (I-->M and M-->I directions) and by gentamicin (M-->I direction only), but not by methylglyoxal, intensifies icodextrin transport. Sodium deoxycholate causes exfoliation of the mesothelium and looseness of the interstitium.

Fibronectin matrix assembly requires distinct contributions from Rho kinases I and -II

Extracellular matrix is integral to tissue architecture and regulates many aspects of cell behavior. Fibronectin matrix assembly involves the actin cytoskeleton and the small GTPase RhoA, but downstream signaling is not understood. Here, down-regulation of either rho kinase isoform (ROCK I or -II) by small interfering RNA treatment blocked fibronectin matrix assembly, although the phenotypes were distinct and despite persistence of the alternate kinase. Remnant fibronectin on ROCK-deficient fibroblasts was mostly punctate and more deoxycholate soluble compared with controls. Fibronectin matrix assembly defects in ROCK-deficient cells did not result from decreased synthesis/secretion, altered fibronectin mRNA splicing, metalloproteinase activity, or alpha5beta1 integrin dysfunction. Rescue could be effected by ROCK protein restoration or phosphomimetic myosin light chain expression. However, the effect of ROCK I deficiency on fibronectin matrix assembly was secondary to altered cell surface morphology, rich in filopodia, resulting from high GTP-Cdc42 levels. Total internal reflection microscopy revealed that a submembranous pool of myosin light chain in control cells was missing in ROCK II-deficient cells and replaced by stress fibers. Together, two rho kinases contribute to fibronectin matrix assembly in a different manner and cortical myosin II-driven contractility, but not stress fibers, may be critical in this activity.

[Effects of absorption enhancers on intestinal absorption of lumbrokinase]

AIM

To explore the intestinal absorption characteristics of lumbrokinase (YJM-I) in the absence or presence of various absorption enhancers and to find the optimum intestinal site for YJM-I absorption.

METHODS

The absorption kinetics and absorption intestinal sites for YJM-I absorption were investigated with the method of diffusion cell in vitro, duodenum bolus injection, recirculating perfusion and in situ duodenum perfusion in vivo.

RESULTS

YJM-I could be transported into blood and kept its biological activity across intestinal endothelial membrane after administration via duodenum site, whereas with lower bioavailability. Some of the absorption enhancers were shown good enhancement effects on intestinal absorption of YJM-I in vitro and in situ experiments. The order of enhanced efficiencies of various enhancers on duodenum, ileum and jejunum in vitro permeation experiments were shown as follows: 1% chitosan > 1% SDCh > 1% Na2EDTA > 1% SDS > 1% sodium caprylate > 1% poloxamer > 1% HP-beta-CD. The order of enhanced efficiencies of various enhancers on duodenum absorption of YJM-I in vivo were as follows: 2.5% SDCh > 2.5% Na2EDTA > 2.0% chitosan > 2.5% SDS > 2.5% sodium caprylate > 2.5% Poloxamer > 2.5% HP-beta-CD.

CONCLUSION

The results indicated that the absorption of YJM-I could be enhanced by various enhancers, and duodenum was the optimum absorption site of YJM-I. Furthermore, bio-adhesive chitosan might be a potential enhancer of intestinal YJM-I absorption.

Resistance to ursodeoxycholic acid-induced growth arrest can also result in resistance to deoxycholic acid-induced apoptosis and increased tumorgenicity

BACKGROUND

There is a large body of evidence which suggests that bile acids increase the risk of colon cancer and act as tumor promoters, however, the mechanism(s) of bile acids mediated tumorigenesis is not clear. Previously we showed that deoxycholic acid (DCA), a tumorogenic bile acid, and ursodeoxycholic acid (UDCA), a putative chemopreventive agent, exhibited distinct biological effects, yet appeared to act on some of the same signaling molecules. The present study was carried out to determine whether there is overlap in signaling pathways activated by tumorogenic bile acid DCA and chemopreventive bile acid UDCA.

METHODS

To determine whether there was an overlap in activation of signaling pathways by DCA and UDCA, we mutagenized HCT116 cells and then isolated cell lines resistant to UDCA induced growth arrest. These lines were then tested for their response to DCA induced apoptosis.

RESULTS

We found that a majority of the cell lines resistant to UDCA-induced growth arrest were also resistant to DCA-induced apoptosis, implying an overlap in DCA and UDCA mediated signaling. Moreover, the cell lines which were the most resistant to DCA-induced apoptosis also exhibited a greater capacity for anchorage independent growth.

CONCLUSION

We conclude that UDCA and DCA have overlapping signaling activities and that disregulation of these pathways can lead to a more advanced neoplastic phenotype.

Evaluation of Caspofungin and Amphotericin B Deoxycholate againstCandida albicansBiofilms in an Experimental Intravascular Catheter Infection Model

Candida albicans biofilms complicate the treatment of infected implanted intravascular devices because of decreased antifungal susceptibility. In our investigation, 48 rabbits with experimental central venous catheter C. albicans infection were equally allocated to a control arm or to receive amphotericin B deoxycholate or caspofungin treatment while undergoing systemic and intraluminal lock therapy for 7 days. C. albicans was cultured from catheters from all control rabbits, from 3 that received amphotericin B, and from 0 that received caspofungin. Differences in colony counts were detected between the control and amphotericin (P<.001) and control and caspofungin (P<.001) arms. Caspofungin may be useful in the treatment of C. albicans biofilm-associated intravascular catheter infections, which warrants further study.

Deoxycholate induces mitochondrial oxidative stress and activates NF-kappaB through multiple mechanisms in HCT-116 colon epithelial cells

Nuclear factor kappa B (NF-kappaB) is a redox-associated transcription factor that is involved in the activation of survival pathways. We have previously shown that deoxycholate (DOC) activates NF-kappaB in hepatocytes and colon epithelial cells and that persistent exposure of HCT-116 cells to increasing concentrations of DOC results in the constitutive activation of NF-kappaB, which is associated with the development of apoptosis resistance. The mechanisms by which DOC activates NF-kappaB in colon epithelial cells, and whether natural antioxidants can reduce DOC-induced NF-kappaB activation, however, are not known. Also, it is not known if DOC can generate reactive oxygen species within mitochondria as a possible pathway of stress-related NF-kappaB activation. Since we have previously shown that DOC activates the NF-kappaB stress-response pathway in HCT-116 cells, we used this cell line to further explore the mechanisms of NF-kappaB activation. We found that DOC induces mitochondrial oxidative stress and activates NF-kappaB in HCT-116 cells through multiple mechanisms involving NAD(P)H oxidase, Na+/K+-ATPase, cytochrome P450, Ca++ and the terminal mitochondrial respiratory complex IV. DOC-induced NF-kappaB activation was significantly (P < 0.05) inhibited by pre-treatment of cells with CAPE, EGCG, TMS, DPI, NaN3, EGTA, Ouabain and RuR. The NF-kappaB-activating pathways, induced by the dietary-related endogenous detergent DOC, provide mechanisms for promotion of colon cancer and identify possible new targets for chemoprevention.

Prevention effect of orally active heparin derivative on deep vein thrombosis

The use of heparin as the most potent anticoagulant for the prevention of deep vein thrombosis and pulmonary embolism is nevertheless limited, because it is available to patients only by parenteral administration. Toward overcoming this limitation in the use of heparin, we have previously developed an orally active heparin-deoxycholic acid conjugate (LMWH-DOCA) in 10% DMSO formulation. The present study evaluates the anti-thrombogenic effect of this orally active LMWH-DOCA using a venous thrombosis animal model with Sprague-Dawley rats. When 5 mg/kg of LMWH-DOCA was orally administered in rats, the maximum anti-FXa activity in plasma was 0.35 +/- 0.02, and anti-FXa activity in plasma was maintained above 0.1 IU/ml [the minimum effective anti-FXa activity for the prevention of deep venous thrombosis (DVT) and pulmonary embolism (PE)] for five hours. LMWH-DOCA (5 mg/kg, 430 IU/kg) that was orally administered reduced the thrombus formation by 56.3 +/- 19.8%;on the other hand, subcutaneously administered enoxaparin (100 IU/kg) reduced the thrombus formation by 36.4 +/- 14.5%. Also, LMWH-DOCA was effectively neutralized by protamine that was used as an antidote. Therefore, orally active LMWH-DOCA could be proposed as a new drug that is effective for the longterm prevention of DVT and PE.

Eupatilin attenuates bile acid-induced hepatocyte apoptosis

BACKGROUND

In cases of cholestasis, bile acids induce hepatocyte apoptosis by activating death receptor-mediated apoptotic signaling cascades. Eupatilin (5,7-dihydroxy-3,4,6-trimethoxyflavone) is a pharmacologically active ingredient found in Artemisia asiatica and exhibits cytoprotective effects against experimentally induced gastrointestinal, pancreatic, and hepatic damage. This study was undertaken to examine if eupatilin modulates bile acid-induced hepatocyte apoptosis.

METHODS

Huh-BAT cells, a human hepatocellular carcinoma cell line stably transfected with a bile acid transporter, were used in this study. Apoptosis was quantified using 4',6-diamidino-2-phenylindole dihydrochloride staining, and its signaling cascades were explored by immunoblot analysis. Kinase signaling was evaluated by immunoblotting and by using selective inhibitors. Eupatilin's in vivo effect on bile acid-induced hepatocyte apoptosis was explored in bile duct-ligated rats.

RESULTS

Eupatilin significantly reduced bile acid-mediated hepatocyte apoptosis by attenuating bile acid-induced caspase 8 cleavage. Eupatilin diminished the bile acid-induced activation of mitogen-activated protein kinases, including p38 mitogen-activated protein kinase and c-Jun N-terminal kinase. In particular, the eupatilin-mediated inhibition of bile acid-induced c-Jun N-terminal kinase activation was found to be responsible for attenuating caspase 8 cleavage. Moreover, eupatilin diminished hepatocyte apoptosis in bile duct-ligated rats.

CONCLUSIONS

Eupatilin attenuates bile acid-induced hepatocyte apoptosis by suppressing bile acid-induced kinase activation. Therefore, eupatilin might be therapeutically efficacious in a variety of human liver diseases associated with cholestasis.

Absorption enhancement study of astragaloside IV based on its transport mechanism in caco-2 cells

The purpose of this study was to investigate the transport characteristics and mechanisms for discovering the possible causes of the low bioavailability of astragaloside IV and to develop an absorption enhancement strategy. Caco-2 cells used as the in vitro model. Results showed a low permeability coefficient (3.7 x 10(-8)cm/s for transport from the AP to BL direction), which remained unchanged throughout the concentration range studied, indicating that the transport of astragaloside IV was predominantly via a passive route. The AP to BL transport of astragaloside IV was found to be highly sensitive to the extracellular Ca2+ concentration, which suggested that its transport may be via a paracellular route. Both chitosan and sodium deoxycholate can increase the permeation efficiency of astragaloside IV. This study indicated that astragaloside IV having a low fraction dose absorbed in humans mainly due to its poor intestinal permeability, high molecular weight, low lipophilicity as well as its paracelluar transport may directly result in the low permeability through its passive transport. Meanwhile, chitosan and sodium deoxycholate can be used as absorption enhancers based on its transport mechanism.

[Modulation of colon cancer cell invasiveness induced by deoxycholic acid]

BACKGROUND/AIMS

Deoxycholic acid (DCA), a secondary bile acid, has been implicated to promote colon cancer growth and progression. However, its molecular mechanisms are largely unknown. In this study, we investigated the effects of DCA on proliferation, migration, and invasiveness of colon cancer cells (HT-29).

METHODS

HT-29 cells were incubated with either medium (control) only or DCA for 24-48 hours. Time courses of RT-PCR for vascular endothelial growth factor (VEGF) and hypoxia-inducible factor (HIF)-1alpha mRNA expression, Western blotting for VEGF and matrix metalloproteinase (MMP)-9, zymography for MMP-9 activation, and wound-migration assay were determined after various concentrations of DCA (0-80 microM) treatment. Moreover, these experiments were reassessed after pretreatments (2-6 hours) with specific inhibitors of various signal pathways.

RESULTS

DCA enhanced HIF-1alpha mRNA expression, VEGF mRNA and VEGF protein expression, MMP-9 protein expression/activation, and cell migration ability in a dose-related manner. DCA-induced VEGF protein expression was inhibited by pretreatment with NS-398 (COX-2 inhibitor), PDTC (NF-kappaB inhibitor), or tauroursodeoxycholic acid (TUDC). DCA-induced cell migration ability was inhibited by pretreatment of GF109203X, a protein kinase C inhibitor. DCA-induced MMP-9 protein expression/activation was inhibited by pretreatment with SB203580, U0126, or PDTC.

CONCLUSIONS

DCA significantly upregulates invasive and angiogenic potentials of human colon cancer cells through multiple signal transduction pathways.

Effects of chenodeoxycholic acid and deoxycholic acid on cholesterol absorption and metabolism in humans

Quantitative and qualitative differences in intralumenal bile acids may affect cholesterol absorption and metabolism. To test this hypothesis, 2 cross-over outpatient studies were conducted in adults with apo-A IV 1/1 or apo-E 3/3 genotypes. Study 1 included 11 subjects 24 to 37 years of age, taking 15 mg/kg/day chenodeoxycholic acid (CDCA) or no bile acid for 20 days while being fed a controlled diet. Study 2 included 9 adults 25 to 38 years of age, taking 15 mg/kg/day deoxycholic acid (DCA) or no bile acid, following the same experimental design and procedures as study 1. CDCA had no effect on plasma lipid concentrations, whereas DCA decreased (P < 0.05) plasma high-density lipoprotein (HDL)-cholesterol and tended to decrease (P = 0.15) low-density lipoprotein (LDL)-cholesterol. CDCA treatment enriched (P < 0.0001) bile with CDCA and increased cholesterol concentration in micelles, whereas meal-stimulated bile acid concentrations were decreased. DCA treatment enriched (P < 0.0001) bile with DCA and tended to increase intralumenal cholesterol solubilized in micelles (P = 0.06). No changes were found in cholesterol absorption, free cholesterol fractional synthetic rate (FSR), or 3-hydroxy-3 methylglutaryl (HMG) CoA reductase and LDL receptor messenger ribonucleic acid (mRNA) levels after CDCA treatment. DCA supplementation tended to decrease cholesterol absorption and reciprocally increase FSR and HMG CoA reductase and LDL receptor mRNA levels. Results of these 2 studies suggest that the solubilization of cholesterol in the intestinal micelles is not a rate-limiting step for its absorption.