Upregulated Na+/H+-Exchange Protects Human Colon Cancer Tissue against Intracellular Acidification.

Increased metabolism accelerates local acid production in cancer tissue. The mechanisms eliminating acidic waste products from human colon cancer tissue represent promising therapeutic targets for pharmacological manipulation in order to improve prognosis for the increasing number of patients with colon cancer. We sampled biopsies of human colonic adenocarcinomas and matched normal colon tissue from patients undergoing colon cancer surgery. We measured steady-state intracellular pH and rates of net acid extrusion in freshly isolated human colonic crypts based on fluorescence microscopy. Net acid extrusion was almost entirely (>95%) Na+-dependent. The capacity for net acid extrusion was increased and steady-state intracellular pH elevated around 0.5 in crypts from colon cancer tissue compared with normal colon tissue irrespective of whether they were investigated in the presence or absence of CO2/HCO3 -. The accelerated net acid extrusion from the human colon cancer tissue was sensitive to the Na+/H+-exchange inhibitor cariporide. We conclude that enhanced net acid extrusion via Na+/H+-exchange elevates intracellular pH in human colon cancer tissue.

Enhanced nitric oxide signaling amplifies vasorelaxation of human colon cancer feed arteries.

Inadequate perfusion of solid cancer tissue results in low local nutrient and oxygen levels and accumulation of acidic waste products. Previous investigations have focused primarily on tumor blood vessel architecture, and we lack information concerning functional differences between arteries that deliver blood to solid cancer tissue versus normal tissue. Here, we use isometric myography to study resistance-sized arteries from human primary colon adenocarcinomas and matched normal colon tissue. Vasocontraction of colon cancer feed arteries in response to endothelin-1 and thromboxane stimulation is attenuated compared with normal colon arteries despite similar wall dimensions and comparable contractions to arginine vasopressin and K+-induced depolarization. Acetylcholine-induced vasorelaxation and endothelial NO synthase expression are increased in colon cancer feed arteries compared with normal colon arteries, whereas vasorelaxation to exogenous NO donors is unaffected. In congruence, the differences in vasorelaxant and vasocontractile function between colon cancer feed arteries and normal colon arteries decrease after NO synthase inhibition. Rhythmic oscillations in vascular tone, known as vasomotion, are of lower amplitude but similar frequency in colon cancer feed arteries compared with normal colon arteries. In conclusion, higher NO synthase expression and elevated NO signaling amplify vasorelaxation and attenuate vasocontraction of human colon cancer feed arteries. We propose that enhanced endothelial function augments tumor perfusion and represents a potential therapeutic target. NEW & NOTEWORTHY Local vascular resistance influences tumor perfusion. Arteries supplying human colonic adenocarcinomas show enhanced vasorelaxation and reduced vasocontraction mainly due to elevated nitric oxide-mediated signaling. Rhythmic oscillations in tone, known as vasomotion, are attenuated in colon cancer feed arteries.

Impaired endothelial calcium signaling is responsible for the defective dilation of mesenteric resistance arteries from db/db mice to acetylcholine.

We aimed at assessing the role of endothelial cell calcium for the endothelial dysfunction of mesenteric resistance arteries of db/db mice (a model of type 2 diabetes) and determine whether treatment with sulfaphenazole, improves endothelial calcium signaling and function. Pressure myography was used to study acetylcholine (ACh) -induced vasodilation. Intracellular calcium ([Ca(2+)]i) transients was measured by confocal laser scanning microscopy and smooth muscle membrane potential with sharp microelectrodes. The impaired dilation to ACh observed in mesenteric resistance arteries from db/db mice was improved by treatment of the mice with sulfaphenazole for 8 weeks. The impaired dilation to ACh was associated with decreased endothelial [Ca(2+)]i and smooth muscle hyperpolarization. Sulfaphenazole applied in vitro improved endothelial mediated dilation of arteries from db/db mice both in the absence and the presence of inhibitors of nitric oxide and cyclooxygenase. Sulfaphenazole also increased the percentage of endothelial cells with ACh induced increases of [Ca(2+)]i. The study shows that impaired endothelial [Ca(2+)]i control can explain the reduced endothelial function in arteries from diabetic mice and that sulfaphenazole treatment improves endothelial [Ca(2+)]i responses to ACh and consequently endothelium-dependent vasodilation. These observations provide mechanistic insight into endothelial dysfunction in diabetes.

Bestrophin is important for the rhythmic but not the tonic contraction in rat mesenteric small arteries.

AIMS: We have previously characterized a cGMP-dependent Ca(2+)-activated Cl(-) current in vascular smooth muscle cells (SMCs) and have shown its dependence on bestrophin-3 expression. We hypothesize that this current is important for synchronization of SMCs in the vascular wall. In the present study, we aimed to test this hypothesis by transfecting rat mesenteric small arteries in vivo with siRNA specifically targeting bestrophin-3. METHODS AND RESULTS: The arteries were tested 3 days after transfection in vitro for isometric force development and for intracellular Ca(2+) in SMCs. Bestrophin-3 expression was significantly reduced compared with arteries transfected with mutated siRNA. mRNA levels for bestrophin-1 and -2 were also significantly reduced by bestrophin-3 down-regulation. This is suggested to be secondary to specific bestrophin-3 down-regulation since siRNAs targeting different exons of the bestrophin-3 gene had identical effects on bestrophin-1 and -2 expression. The transfection affected neither the maximal contractile response nor the sensitivity to norepinephrine and arginine-vasopressin. The amplitude of agonist-induced vasomotion was significantly reduced in arteries down-regulated for bestrophins compared with controls, and asynchronous Ca(2+) waves appeared in the SMCs. The average frequency of vasomotion was not different. 8Br-cGMP restored vasomotion in arteries where the endothelium was removed, but oscillation amplitude was still significantly less in bestrophin-down-regulated arteries. Thus, vasomotion properties were consistent with those previously characterized for rat mesenteric small arteries. Data from our mathematical model are consistent with the experimental results. CONCLUSION: This study demonstrates the importance of bestrophins for synchronization of SMCs and strongly supports our hypothesis for generation of vasomotion.

Human thoracic duct in vitro: diameter-tension properties, spontaneous and evoked contractile activity.

The current study characterizes the mechanical properties of the human thoracic duct and demonstrates a role for adrenoceptors, thromboxane, and endothelin receptors in human lymph vessel function. With ethical permission and informed consent, portions of the thoracic duct (2-5 cm) were resected and retrieved at T(7)-T(9) during esophageal and cardia cancer surgery. Ring segments (2 mm long) were mounted in a myograph for isometric tension (N/m) measurement. The diameter-tension relationship was established using ducts from 10 individuals. Peak active tension of 6.24 +/- 0.75 N/m was observed with a corresponding passive tension of 3.11 +/- 0.67 N/m and average internal diameter of 2.21 mm. The equivalent active and passive transmural pressures by LaPlace's law were 47.3 +/- 4.7 and 20.6 +/- 3.2 mmHg, respectively. Subsequently, pharmacology was performed on rings from 15 ducts that were normalized by stretching them until an equivalent pressure of 21 mmHg was calculable from the wall tension. At low concentrations, norepinephrine, endothelin-1, and the thromboxane-A(2) analog U-46619 evoked phasic contractions (analogous to lymphatic pumping), whereas at higher contractions they induced tonic activity (maximum tension values of 4.46 +/- 0.63, 5.90 +/- 1.4, and 6.78 +/- 1.4 N/m, respectively). Spontaneous activity was observed in 44% of ducts while 51% of all the segments produced phasic contractions after agonist application. Acetylcholine and bradykinin relaxed norepinephrine preconstrictions by approximately 20% and approximately 40%, respectively. These results demonstrate that the human thoracic duct can develop wall tensions that permit contractility to be maintained across a wide range of transmural pressures and that isolated ducts contract in response to important vasoactive agents.