A Combined Free-Flow Electrophoresis and DIGE Approach to Compare Proteins in Complex Biological Samples.

Free-flow electrophoresis has been applied in numerous studies as a protein separation technique due to its multiple advantages such as fast and efficient sample recovery, high resolving power, high reproducibility and wide applicability to protein classes. As a stand-alone platform, however, its utility in comparative proteomic analysis is limited as protein samples must be run sequentially rather than simultaneously which introduces inherent variability when attempting to perform quantitative analysis. Here we describe an approach combining fluorescent CyDye technology (DIGE) with free-flow electrophoresis to simultaneously separate and identify differentially expressed proteins in a model cell system.

Identification of potential pathways involved in induction of apoptosis by butyrate and 4-benzoylbutyrate in HT29 colorectal cancer cells.

Butyrate and its analogues have long been investigated as potential chemotherapeutic agents. Our previous structure-activity relationship studies of butyrate analogues revealed that 4-benzoylbutyrate had comparable in vitro effects to butyrate when used to treat HT29 and HCT116 colorectal cancer cell lines. The aim of this study was to identify potential mechanisms associated with the antitumorigenic effects of 4-benzoylbutyrate. In this study, butyrate, 3-hydroxybutyrate and 4-benzoylbutyrate were also investigated for their effects on histone deacetylase (HDAC) activity and histone H4 acetylation in HT29 and HCT116 cells. The biological effects of these analogues on HT29 cells were further investigated using quantitative proteomics to determine the proteins potentially involved in their apoptotic and antiproliferative effects. Because 3-hydroxybutyrate had minimal to no effect on apoptosis, proliferation or HDAC activity, this analogue was used to identify differentially expressed proteins that were potentially specific to the apoptotic effects of butyrate and/or 4-benzoylbutyrate. Butyrate treatment inhibited HDAC activity and induced H4 acetylation. 4-Benzoylbutyrate inhibited HDAC activity but failed to enhance H4 acetylation. Proteomic analysis revealed 20 proteins whose levels were similarly altered by both butyrate and 4-benzoylbutyrate. Proteins that showed common patterns of differential regulation in the presence of either butyrate or 4-benzoylbutyrate included c-Myc transcriptional targets, proteins involved in ER homeostasis, signal transduction pathways and cell energy metabolism. Although an additional 23 proteins were altered by 4-benzoylbutyrate uniquely, further work is required to understand the mechanisms involved in its apoptotic effects.

A combined free flow electrophoresis and DIGE approach to compare proteins in complex biological samples.

Free flow electrophoresis (FFE) has been applied in numerous studies as a protein separation technique due to its multiple advantages such as fast and efficient sample recovery, high resolving power, high reproducibility, and wide applicability to protein classes. As a stand-alone platform however, its utility in comparative proteomic analysis is limited as protein samples must be run sequentially rather than simultaneously which introduces inherent variability when attempting to perform quantitative analysis. Here we describe an approach combining fluorescent CyDye technology (DIGE) with FFE to simultaneously separate and identify differentially expressed proteins in a model cell system.

A combined free-flow electrophoresis and DIGE approach to identify proteins regulated by butyrate in HT29 cells.

Many biologically active agents exert a pleiotropic response in cells and tissues. This presents challenges in descriptive and comparative analysis of the proteome in response to these agents. Although free-flow electrophoresis has been applied in a number of proteomic studies as a protein separation technique, the combination of free-flow electrophoresis and DIGE has not yet been investigated for comparative proteomic analysis. In this study, we have compared the effects of butyrate on HT29 colorectal cancer cells with a particular focus on apoptosis and describe the utility of a novel approach combining free-flow electrophoresis with DIGE to identify differentially expressed proteins. We verify the results obtained by the combined free-flow electrophoresis and DIGE approach with Western blot analysis of selected proteins. We also report for the first time the regulation of a number of proteins by butyrate in HT29 colorectal cells including peptidyl-prolyl cis-trans isomerase A (cyclophilin A) and profilin-1.

Structure-activity relationship of butyrate analogues on apoptosis, proliferation and histone deacetylase activity in HCT-116 human colorectal cancer cells.

1. Butyrate, a bacteria fermentative product in the colonic lumen, has been shown to produce a wide variety of biological effects in human cancer cells in vitro. However, there are pharmacological drawbacks associated with the use of butyrate therapy and there are limited published data on the structure-activity relationship of butyrate analogues in colorectal cancer cells. Previously, we determined structure-activity relationship using HT-29 human colorectal cancer cells. However, it was viewed as important to explore similar relationships in another colorectal cancer cell line. 2. Therefore, in the present study, the in vitro structure-activity relationship of butyrate analogues was examined by investigating their effects on apoptosis, cell proliferation, histone deacetylase (HDAC) activity and lactate dehydrogenase (LDH) leakage as a measure of cell toxicity in HCT-116 human colorectal cancer cells. 3. Of the 32 analogues tested, only 4-benzoylbutyrate, 3-benzo-ylpropionate, 4-(4-nitrophenyl)butyrate and 3-(4-fluorobenzoyl)propionate exhibited comparable biological effects to butyrate. The common structural properties of the compounds of interest were to lack amino or hydroxyl substitutions at the 2-, 3- and/or 4-position of the aliphatic moiety of butyrate. 4. The present study reveals a dissociation between the induction of apoptosis, inhibition of cell proliferation, HDAC activity and LDH leakage. The results indicate differential responses of butyrate analogues in HT-29 and HCT-116 colorectal cancer cells.

Efficacy of butyrate analogues in HT-29 cancer cells.

1. Butyrate is a well known product of starch fermentation by colonic bacteria and is of interest owing to its ability to induce in vitro apoptosis and cell differentiation, as well as to inhibit cell growth in colorectal and other cancer cells. Synthetic analogues of butyrate may also possess cellular activities in a variety of cultured cells. The aim of the present study was to evaluate the effects of butyrate analogues on apoptosis, proliferation and histone deacetylase (HDAC) activity in HT-29 colorectal cancer cells. In addition, the effects of these analogues on lactate dehydrogenase leakage, as a measure of non-specific cytotoxicity, were evaluated in HT-29 cells. 2. Of the 26 analogues examined, four (propionate, 4-benzoylbutyrate, 4-(4-aminophenyl)butyrate and benzyloxyacetate) exhibited comparable effects to butyrate. Interestingly, no activity was noted for compounds carrying amino, hydroxyl or methyl substitutions at the 2-, 3- or 4-position of the aliphatic moiety of butyrate. 3. In conclusion, chemical changes to the structure of butyrate can significantly modify the biological activity assayed in HT-29 colorectal cancer cells in vitro.

Proteomic analysis of butyrate effects and loss of butyrate sensitivity in HT29 colorectal cancer cells.

Butyrate, a fermentation product of the large bowel microflora, is potentially protective against the development of colorectal cancer. In vitro, butyrate has been shown to induce apoptosis and inhibit proliferation in numerous cancer cell lines, including colorectal cancer. Although these tumor suppressing properties of butyrate are well-documented in experimental systems, the mechanisms underlying the induction of these effects are not fully understood. Understanding these mechanisms in cancer cells, as well as the pathways involved in a cell's ability to overcome them and progress toward malignancy, is vital to determine therapeutic approaches for disease management. We have developed a colorectal cancer cell line (HT29-BR) that is less responsive to the apoptotic effects of butyrate through sustained exposure of HT29 cells to 5 mM butyrate and have used proteomics to investigate the mechanisms involved in the development of butyrate insensitivity. Proteomic analysis identified a number of cellular processes in HT29 and HT29-BR cells influenced by butyrate including remodeling of the actin cytoskeleton, inhibition of protein biosynthesis and dysregulation of the cell stress response. We describe novel roles for butyrate in the induction of its tumor suppressing effects and outline potential cellular pathways involved in the development of butyrate insensitivity in the HT29-BR cell population.

Reversal of morphine, methadone and heroin induced effects in mice by naloxone methiodide.

Opioid overdose, which is commonly associated with opioid induced respiratory depression, is a problem with both therapeutic and illicit opioid use. While the central mechanisms involved in the effects of opioids are well described, it has also been suggested that a peripheral component may contribute to the effects observed. This study aimed to further characterise the effects of the peripherally acting naloxone methiodide on the respiratory, analgesic and withdrawal effects produced by various opioid agonists. A comparison of the respiratory and analgesic effects of morphine, methadone and heroin in male Swiss-Albino mice was conducted and respiratory depressive ED(80) doses of each opioid determined. These doses (morphine 9 mg/kg i.p., methadone 7 mg/kg i.p., and heroin 17 mg/kg i.p.) were then used to show that both naloxone (3 mg/kg i.p.) and naloxone methiodide (30-100 mg/kg i.p.) could reverse the respiratory and analgesic effects of these opioid agonists, but only naloxone precipitated withdrawal. Further investigation in female C57BL/6J mice using barometric plethysmography found that both opioid antagonists could reverse methadone induced decreases in respiratory rate and increases in tidal volume. Its effects do not appear to be strain or sex dependent. It was concluded that naloxone methiodide can reverse the respiratory and analgesic actions of a variety of opioid agonists, without inducing opioid withdrawal.

Use of radiotelemetry to evaluate respiratory depression produced by chronic methadone administration.

Illicit and therapeutic opioid administration can result in overdose due to opioid-induced respiratory depression. Research investigating the respiratory depressant effects of opioids has been limited due to difficulties associated with acquiring long-term respiratory data. This study examined the novel use of radiotelemetry to measure respiratory rate, heart rate, locomotor activity and blood pressure in rats treated chronically with methadone. Over 4 days of treatment, respiratory rate decreased, but partial tolerance appeared to develop during active (night) periods. Decreased heart rate was observed during the night periods and tolerance appeared to develop to this effect. Activity and blood pressure did not change with treatment. The effects of naloxone hydrochloride and naloxone methiodide administration on the methadone-treated rats were also examined and both antagonists increased respiratory rate and heart rate, with only naloxone hydrochloride producing significant increases in activity. Radiotelemetry offers a means of evaluating drug effects on respiratory rate continually in ambulatory, unstressed animals.

Naloxone and its quaternary derivative, naloxone methiodide, have differing affinities for mu, delta, and kappa opioid receptors in mouse brain homogenates.

Naloxone and naloxone methiodide both act on opioid receptors but naloxone methiodide has limited access to the brain. Naloxone methiodide has been shown to have a lower affinity for opioid receptors than naloxone in the rat and guinea pig but has not been tested in the mouse. We aimed to investigate this by using [3H]DAMGO, [3H]DPDPE and [3H]U-69,593 to compare the ability of naloxone and naloxone methiodide to displace binding to mu, delta and kappa opioid receptors in mouse brain homogenates. Significant binding was observed for each receptor type and the binding affinity for naloxone versus naloxone methiodide was found to be 15:1 for mu, 6:1 for kappa and 330:1 for delta receptors. Therefore, naloxone methiodide does have a lower affinity for opioid receptors than naloxone in mouse brain tissue, which must be taken into consideration in experimental designs.

Naloxone methiodide reverses opioid-induced respiratory depression and analgesia without withdrawal.

Illicit opioid overdoses are a significant problem throughout the world, with most deaths being attributed to opioid-induced respiratory depression which may involve peripheral mechanisms. The current treatment for overdoses is naloxone hydrochloride, which is effective but induces significant withdrawal. We propose that selectively peripherally acting opioid receptor antagonists, such as naloxone methiodide, could reverse respiratory depression without inducing predominantly centrally mediated withdrawal. Acute administration of morphine (300 mg/kg, i.p.) was found to significantly depress respiratory rate and induce analgesia (P<0.0001). Both naloxone hydrochloride and naloxone methiodide were able to reverse these effects but naloxone methiodide precipitated no significant withdrawal. Naloxone methiodide was also able to reverse opioid-induced respiratory depression (P<0.001) and antinociception (P<0.01) after chronic morphine administration (300 mg/kg/day for 5 days) without inducing significant withdrawal. Therefore, peripherally selective opioid receptor antagonists should be investigated as possible treatments for opioid-induced respiratory depression which do not induce adverse effects, such as withdrawal.