Shen-Ling Xia

Sarcomere Mechanics in Capillary Endothelial Cells

Tension generation in endothelial cells of the aorta, spleen, and eye occurs in actin stress fibers, and is necessary for normal cell function. Sarcomeres are the tension-generating units of actin stress fibers in endothelial cells. How sarcomeres generate and maintain tension in stress fibers is not well understood. Using femtosecond laser ablation, we severed living stress fibers and measured sarcomere contraction under zero tension. The length of the sarcomere decreased in two phases: an instantaneous initial response, followed by a slower change in length attributed to myosin activity. The latter phase ceased abruptly after a minimum sarcomere length was reached, suggesting a rigid resistance that prevents further contraction. Furthermore, severed, contracted stress fibers did not relax when treated with myosin inhibitors, indicating that contracted stress fibers do not store elastic potential energy. These novel measurements combined with modeling suggest that myosin-generated forces in adjacent sarcomeres are directly in balance, and argue against sarcomere models with springlike elements in parallel with myosin contractile elements. We propose a new model for tension generation in the sarcomere, which provides a mechanistic interpretation for our observations and previous observations of inhomogeneous sarcomere contraction and apparent stress fiber viscoelastic behavior.

Peptides modified by myristoylation activate eNOS in endothelial cells through Akt phosphorylation

1 Myristoylated pseudosubstrate of PKCζ (mPS) – a synthetic myristoylated peptide with a sequence (13 amino acids) mimicking the endogenous PKCζ pseudosubstrate region – is considered a selective cell‐permeable inhibitor of PKCζ. We present strong evidence that in endothelial cells the action of mPS is not limited to inhibition of PKC activity and that myristoylation of certain peptides can activate eNOS (endothelial nitric oxide synthase) through Akt phosphorylation. 2 mPS at micromolar concentrations (1–10 μM) induced profound phosphorylation of eNOS, Akt, ERK 1/2, and p38 MAPK in cultured pulmonary artery endothelial cells (PAEC). The same changes were observed after treatment of PAEC with a myristoylated scrambled version of mPS (mScr), whereas a cell‐permeable version of PKCζ pseudosubstrate fused to the HIV‐TAT membrane‐translocating peptide did not induce analogous changes, suggesting that myristoylation confers new properties on the peptides consisting of activation of different signaling pathways in endothelial cells. 3 In addition to mPS and mScr, a number of other myristoylated peptides induced phosphorylation of eNOS suggesting that myristoylation of peptides can activate eNOS by mechanisms unrelated to inhibition of PKC. All active myristoylated peptides contained basic amino acids motif and were longer than six amino acids. 4 Activation of eNOS by myristoylated peptides was dependent on the PI3K/Akt pathway and the rise of intracellular calcium and was associated with an elevation of cGMP levels in PAEC and with relaxation of precontracted isolated pulmonary artery segments. 5 Myristoylated peptides can be considered a new class of activators of NO production in endothelial cells and that using mPS as a specific inhibitor of PKCζ should be done with caution, especially in endothelial cells.

Heterogeneity of H-K-ATPase-mediated acid secretion along the mouse collecting duct

In the collecting duct (CD), H-K-ATPases function in cation reabsorption and H secretion. This study evaluated H-K-ATPase-mediated H secretion along the mouse CD, measured as EIPA- and luminal bafilomycin A(1)-insensitive intracellular pH (pH(i)) recovery from acute H loading (NH(4)) using BCECF. pH(i) recovery was measured in 1) microperfused cortical, outer medullary, and inner medullary CDs (CCD, OMCD, and IMCD) from C57BL/6J mice fed a normal diet and 2) common murine CD cell lines. H-K-ATPase activity along the native, microperfused CD was greatest in the CCD, less in the OMCD, and least in the IMCD (0.10 +/- 0.02, 0.04 +/- 0.01, and 0.01 +/- 0.002 U/min, respectively). H-K-ATPase activity was 0.30 +/- 0.03 and 0.26 +/- 0.03 in A- and B-type ICs, respectively, and was sensitive to Sch-28080 or ouabain. pH(i) recovery was greatest in the OMCD(1) cell line (0.25 +/- 0.01) and less in mpkCCD(c14) (0.17 +/- 0.01), mIMCD-K2 (0.12 +/- 0.01), and mIMCD-3 (0.05 +/- 0.01) cells. EIPA inhibited the majority of pH(i) recovery in these cells (100%, 64%, 75%, and 80% in mpkCCD(c14), OMCD(1), mIMCD-K2, and mIMCD-3, respectively). In OMCD(1) cells, where EIPA-insensitive pH(i) recovery was greatest, H-K-ATPase activity was 0.10 +/- 0.01 and was significantly inhibited (80%) by Sch-28080. We conclude that 1) H-K-ATPase-mediated H secretion in the native mouse CD is greatest in the ICs of the CCD, 2) A- and B-type ICs possess HKalpha(1) and HKalpha(2) H-K-ATPase activity, and 3) the OMCD(1) cell line best exhibits H-K-ATPase.

Substance P Increases Cell-Surface Expression of CD74 (Receptor for Macrophage Migration Inhibitory Factor): In Vivo Biotinylation of Urothelial Cell-Surface Proteins

Macrophage migration inhibitory factor (MIF), an inflammatory cytokine, and its receptor CD74 are upregulated by bladder inflammation. MIF-mediated signal transduction involves binding to cell-surface CD74, this study documents, in vivo, MIF-CD74 interactions at the urothelial cell surface. N-hydroxysulfosuccinimide biotin ester-labeled surface urothelial proteins in rats treated either with saline or substance P (SP, 40 μg/kg). The bladder was examined by histology and confocal microscopy. Biotinylated proteins were purified by avidin agarose, immunoprecipitated with anti-MIF or anti-CD74 antibodies, and detected with strepavidin-HRP. Only superficial urothelial cells were biotinylated. These cells contained a biotinylated MIF/CD74 cell-surface complex that was increased in SP-treated animals. SP treatment increased MIF and CD74 mRNA in urothelial cells. Our data indicate that intraluminal MIF, released from urothelial cells as a consequence of SP treatment, interacts with urothelial cell-surface CD74. These results document that our previously described MIF-CD74 interaction occurs at the urothelial cell surface.

Pharmacological profiles of the murine gastric and colonic H,K-ATPases.

BACKGROUND The H,K-ATPase, consisting of α and ß subunits, belongs to the P-type ATPase family. There are two isoforms of the α subunit, HKα₁ and HKα₂ encoded by different genes. The ouabain-resistant gastric HKα₁-H,K-ATPase is Sch28080-sensitive. However, the colonic HKα₂-H,K-ATPase from different species shows poor primary structure conservation of the HKα₂ subunit between species and diverse pharmacological sensitivity to ouabain and Sch28080. This study sought to determine the contribution of each gene to functional activity and its pharmacological profile using mouse models with targeted disruption of HKα₁, HKα₂, or HKbeta genes. METHODS Membrane vesicles from gastric mucosa and distal colon in wild-type (WT), HKα₁, HKα₂, or HKß knockout (KO) mice were extracted. K-ATPase activity and pharmacological profiles were examined. RESULTS The colonic H,K-ATPase demonstrated slightly greater affinity for K(+) than the gastric H,K-ATPase. This K-ATPase activity was not detected in the colon of HKα₂ KO but was observed in HKß KO with properties indistinguishable from WT. Neither ouabain nor Sch28080 had a significant effect on the WT colonic K-ATPase activity, but orthovanadate abolished this activity. Amiloride and its analogs benzamil and 5-N-ethyl-N-isopropylamiloride inhibited K-ATPase activity of HKα₁-containing H,K-ATPase; the dose dependence of inhibition was similar for all three inhibitors. In contrast, the colonic HKα₂-H,K-ATPase was not inhibited by these compounds. CONCLUSIONS These data demonstrate that the mouse colonic H,K-ATPase exhibits a ouabain- and Sch28080-insensitive, orthovanadate-sensitive K-ATPase activity. Interestingly, pharmacological studies suggested that the mouse gastric H,K-ATPase is sensitive to amiloride. GENERAL SIGNIFICANCE Characterization of the pharmacological profiles of the H,K-ATPases is important for understanding the relevant knockout animals and for considering the specificity of the inhibitors.

Sodium Transport Mechanisms in the Mammalian Nephron

Na transport is highly coordinated and regulated along the length of the renal nephron. The proximal tubule reabsorbs the majority of filtered Na. The majority of Na transport is transcellular, through the action of Na-antiporters and Na-coupled cotransporters. The proximal tubule is responsible for the majority of Na reabsorption by the renal nephron. In the thick ascending limb of Henle, Na is cotransported with other ions. This nephron segment is critical for urine concentration. The distal tubule and collecting duct make the smallest contribution to renal Na reabsorption. However, Na transport in these segments is subject to stringent regulation and is critical for external Na balance under normal physiological conditions. The basic structure and function of the renal Na transporters are evaluated. Hormonal and signaling pathways that regulate Na transport in the nephron and collecting duct are also discussed.