Tmem100-BAC-EGFP mice to selectively mark and purify embryonic endothelial cells of large caliber arteries in mid-gestational vascular formation.

Embryonic vascular development is achieved through the complex arrays of differentiation, proliferation, migration and mutual interaction of different cell types, and visualization as well as purification of unique cell populations are fundamental in studying its detailed mechanisms using in vivo experimental models. We previously demonstrated that Tmem100 was a novel endothelial gene encoding a small transmembrane protein, and that Tmem100 null mice showed embryonic lethality due to severe impairment of vascular formation. In the present study, we generated an EGFP reporter mouse line using a 216 kb genomic region containing mouse Tmem100 gene. A novel line designated as Tmem100-BAC-EGFP mice precisely recapitulated the Tmem100 expression profile at the mid-gestational stage, which was highly enriched in endothelial cells of large caliber arteries in mouse embryos. FACS experiments demonstrated that Tmem100-BAC-EGFP mice served to selectively purify a specific population of arterial endothelial cells, indicating their usefulness not only for the research concerning Tmem100 expression and function but also for comparative analysis of multiple endothelial cell subgroups in embryonic vascular development.

Serum/glucocorticoid-regulated kinase 1 as a novel transcriptional target of bone morphogenetic protein-ALK1 receptor signaling in vascular endothelial cells.

Bone morphogenetic protein 9 (BMP9)/BMP10-ALK1 receptor signaling is essential for endothelial differentiation and vascular morphogenesis. Mutations in ALK1/ACVRL1 and other signal-related genes are implicated in human vascular diseases, and the Alk1/Acvrl1 deletion in mice causes severe impairment of vascular formation and embryonic lethality. In the microarray screen to search for novel downstream genes of ALK1 signaling, we found that the mRNA and protein expression of serum/glucocorticoid-regulated kinase 1 (SGK1) was rapidly up-regulated by the BMP9 stimulation of cultured human endothelial cells. The increase in SGK1 mRNA was completely blocked by the transcriptional inhibitor actinomycin D and significantly suppressed by the siRNA treatment against the co-SMAD transcription factor SMAD4. Upon the BMP9 treatment of endothelial cells, phosphorylated SMAD1/5/9 bound to a consensus site upstream of the SGK1 gene, which was necessary for BMP9-dependent increment of the luciferase reporter activity driven by the SGK1 proximal enhancer. The Sgk1 mRNA expression in mouse embryos was enriched in vascular endothelial cells at embryonic day 9.0-9.5, at which Sgk1 null mice showed embryonic lethality due to abnormal vascular formation, and its mRNA as well as protein expression was clearly reduced in Alk1/Acvrl1 null embryos. These results indicate that SGK1 is a novel target gene of BMP9/BMP10-ALK1 signaling in endothelial cells and further suggest a possibility that down-regulation of the Sgk1 expression may be involved in the mechanisms of vascular defects by the ALK1 signaling deficiency.

Na+/H+ exchanger 1 is regulated via its lipid-interacting domain, which functions as a molecular switch: a pharmacological approach using indolocarbazole compounds.

The plasma membrane Na(+)/H(+) exchanger 1 (NHE1) is rapidly activated in response to various stimuli. The membrane-proximal cytoplasmic region (∼60 residues), termed the lipid-interacting domain (LID), is an important regulatory domain of NHE1. Here, we used a pharmacological approach to further characterize the role of LID in the regulation of NHE1. Pharmacological analysis using staurosporine-like indolocarbazole and bisindolylmaleimide compounds suggested that the phorbol ester- and receptor agonist-induced activation of NHE1 occurs through a protein kinase C-independent mechanism. In particular, only indolocarbazole compounds that inhibited NHE1 activation were able to interact with the LID, suggesting that the inhibition of NHE1 activation is achieved through the direct action of these compounds on the LID. Furthermore, in addition to phorbol esters and a receptor agonist, okadaic acid and hyperosmotic stress, which are known to activate NHE1 through unknown mechanisms, were found to promote membrane association of the LID concomitant with NHE1 activation; these effects were inhibited by staurosporine, as well as by a mutation in the LID. Binding experiments using the fluorescent ATP analog trinitrophenyl ATP revealed that ATP and the NHE1 activator phosphatidylinositol 4,5-bisphosphate bind competitively to the LID. These findings suggest that modulation of NHE1 activity by various activators and inhibitors occurs through the direct binding of these molecules to the LID, which alters the association of the LID with the plasma membrane.

Regulation of the cardiac Na⁺/H⁺ exchanger in health and disease.

The Na(+) gradient produced across the cardiac sarcolemma by the ATP-dependent Na(+)-pump is a constant source of energy for Na(+)-dependent transporters. The plasma membrane Na(+)/H(+) exchanger (NHE) is one such secondary active transporter, regulating intracellular pH, Na(+) concentration, and cell volume. NHE1, the major isoform found in the heart, is activated in response to a variety of stimuli such as hormones and mechanical stress. This important characteristic of NHE1 is intimately linked to heart diseases, including maladaptive cardiac hypertrophy and subsequent heart failure, as well as acute ischemic-reperfusion injury. NHE1 activation results in elevation of pH and intracellular Na(+) concentration, which potentially enhance downstream signaling cascades in the myocardium. Therefore, in addition to determining the mechanism underlying regulation of NHE1 activity, it is important to understand how the ionic signal produced by NHE1 is transmitted to the downstream targets. Extensive studies have identified many accessory factors that interact with NHE1. Here, we have summarized the recent progress on understanding the molecular mechanism underlying NHE1 regulation and have shown a possible signaling pathway leading to cardiac remodeling, which is initiated from NHE1. This article is part of a Special Issue entitled "Na(+) Regulation in Cardiac Myocytes".

Novel phorbol ester-binding motif mediates hormonal activation of Na+/H+ exchanger.

Protein kinase C (PKC) is considered crucial for hormonal Na(+)/H(+) exchanger (NHE1) activation because phorbol esters (PEs) strongly activate NHE1. However, here we report that rather than PKC, direct binding of PEs/diacylglycerol to the NHE1 lipid-interacting domain (LID) and the subsequent tighter association of LID with the plasma membrane mainly underlies NHE1 activation. We show that (i) PEs directly interact with the LID of NHE1 in vitro, (ii) like PKC, green fluorescent protein (GFP)-labeled LID translocates to the plasma membrane in response to PEs and receptor agonists, (iii) LID mutations markedly inhibit these interactions and PE/receptor agonist-induced NHE1 activation, and (iv) PKC inhibitors ineffectively block NHE1 activation, except staurosporin, which itself inhibits NHE1 via LID. Thus, we propose a PKC-independent mechanism of NHE1 regulation via a PE-binding motif previously unrecognized.

Maternal administration of tadalafil improves fetal ventricular systolic function in a Hey2 knockout mouse model of fetal heart failure.

BACKGROUND: There is no established transplacental treatment for heart failure (HF) in utero, and no animal models or experimental systems of fetal HF have been established. This study aimed to investigate the effect of maternal tadalafil administration on fetal cardiovascular function and uteroplacental circulation in a murine model of fetal HF. METHODS AND RESULTS: We first used an ultra-high-frequency ultrasound imaging system in utero and demonstrated that Hey2-/- embryos had worsening right ventricular hypoplasia and marked left ventricular (LV) dilatation as gestation progressed. In both ventricles, fractional shortening (FS) and the E/A ratio were significantly lower in Hey2-/- embryos than in wild-type embryos, indicating that the embryos can be used as a murine model of fetal HF. Subsequently, we evaluated the effect of tadalafil treatment (0.04 or 0.08 mg/ml; T0.04 or T0.08 groups, respectively) on fetoplacental circulation in Hey2-/- embryos. LV FS was significantly higher in the T0.04 group than in control (P < 0.01), whereas LV dilation, mitral E/A ratio, and umbilical artery resistance index were not significantly different among all groups. The thinness of the LV compacted layer did not differ between the T0.04 and vehicle-treated Hey2-/- embryos. CONCLUSIONS: A phenotype comprising marked dilatation and reduced FS of the left ventricles was identified in Hey2-/- embryos, suggesting these embryos as a murine model of fetal HF. In addition, maternal administration of tadalafil improved LV systolic function without altering LV morphological abnormalities in Hey2-/- embryos. Our findings suggest that tadalafil is a potential agent to treat impaired fetal ventricular systolic function.

Functional importance of charged residues within the putative intracellular loops in pH regulation by Na+/ H+ exchanger NHE1.

The plasma membrane Na+/H+ exchanger 1 is activated in response to various extrinsic factors, and this process is regulated by an intracellular pH-sensing mechanism. To identify the candidate residues responsible for intracellular pH regulation, we analyzed the functional properties of engineered Na+/H+ exchanger 1 mutants with charge-reversal mutations of charged residues located in the intracellular loops. Na+/H+ exchanger 1 mutants with mutations at 11 positions were well expressed in the plasma membrane, but that with E247R was not, suggesting that Glu247 is important for the functional expression of Na+/H+ exchanger 1. Charge-reversal mutations of Glu131 (E131R, E131K) and Arg327 (R327E) resulted in a shift in the intracellular pH dependence of the exchange activity measured by 22Na+ uptake to the acidic side, and it abolished the response to growth factors and a hyperosmotic medium; however, mutations of Asp448 (D448R) and Arg500 (R500E) slightly shifted it to the alkaline side. In E131R, in addition to the change in intracellular pH dependence, the affinities for extracellular Na+, Li+ and the inhibitor 5-(N-ethyl-N-isopropyl)amiloride significantly increased. Furthermore, charge-conserved mutation of E131 (E131D) was found to have no effect, whereas charge neutralization (E131Q) resulted in a slight acidic shift of exchange. These results support the view that the multiple charged residues identified in this study, along with several basic residues reported previously, participate in the regulation of the intracellular pH sensing of Na+/H+ exchanger 1. In addition, Glu131 may also be important for cation transport.

Evidence that Na+/H+ exchanger 1 is an ATP-binding protein.

Na(+)/H(+) exchanger (NHE) 1 is a member of the solute carrier superfamily, which regulates intracellular ionic homeostasis. NHE1 is known to require cellular ATP for its activity, despite there being no requirement for energy input from ATP hydrolysis. In this study, we investigated whether NHE1 is an ATP-binding protein. We designed a baculovirus vector carrying both epitope-tagged NHE1 and its cytosolic subunit CHP1, and expressed the functional NHE1-CHP1 complex on the surface of Sf9 insect cells. Using the purified complex protein consisting of NHE1 and CHP1 from Sf9 cells, we examined a photoaffinity labeling reaction with 8-azido-ATP-biotin. UV irradiation promoted the incorporation of 8-azido-ATP into NHE1, but not into CHP1, with an apparent Kd of 29.1 µM in the presence of Mg(2+). The nonlabeled nucleotides ATP, GTP, TTP and CTP all inhibited this crosslinking. However, ATP had the strongest inhibitory effect, with an apparent inhibition constant (IC50) for ATP of 2.2 mM, close to the ATP concentration giving the half-maximal activation of NHE1 activity. Importantly, crosslinking was more strongly inhibited by ATP than by ADP, suggesting that ATP is dissociated from NHE1 upon ATP hydrolysis. Limited proteolysis with thrombin and deletion mutant analysis revealed that the 8-azido-ATP-binding site is within the C-terminal cytoplasmic domain of NHE1. Equilibrium dialysis with NHE1-derived peptides provided evidence that ATP directly binds to the proximal cytoplasmic region (Gly542-Pro598), which is critical for ATP-dependent regulation of NHE1. These findings suggest that NHE1 is an ATP-binding transporter. Thus, ATP may serve as a direct activator of NHE1.

Na(+)/H(+) exchanger 1 directly binds to calcineurin A and activates downstream NFAT signaling, leading to cardiomyocyte hypertrophy.

The calcineurin A (CaNA) subunit was identified as a novel binding partner of plasma membrane Na(+)/H(+) exchanger 1 (NHE1). CaN is a Ca(2+)-dependent phosphatase involved in many cellular functions, including cardiac hypertrophy. Direct binding of CaN to the (715)PVITID(720) sequence of NHE1, which resembles the consensus CaN-binding motif (PXIXIT), was observed. Overexpression of NHE1 promoted serum-induced CaN/nuclear factor of activated T cells (NFAT) signaling in fibroblasts, as indicated by enhancement of NFAT promoter activity and nuclear translocation, which was attenuated by NHE1 inhibitor. In neonatal rat cardiomyocytes, NHE1 stimulated hypertrophic gene expression and the NFAT pathway, which were inhibited by a CaN inhibitor, FK506. Importantly, CaN activity was strongly enhanced with increasing pH, so NHE1 may promote CaN/NFAT signaling via increased intracellular pH. Indeed, Na(+)/H(+) exchange activity was required for NHE1-dependent NFAT signaling. Moreover, interaction of CaN with NHE1 and clustering of NHE1 to lipid rafts were also required for this response. Based on these results, we propose that NHE1 activity may generate a localized membrane microdomain with higher pH, thereby sensitizing CaN to activation and promoting NFAT signaling. In cardiomyocytes, such signaling can be a pathway of NHE1-dependent hypertrophy.

Enhanced Na+/H+ exchange activity contributes to the pathogenesis of muscular dystrophy via involvement of P2 receptors.

A subset of muscular dystrophy is caused by genetic defects in dystrophin-associated glycoprotein complex. Using two animal models (BIO14.6 hamsters and mdx mice), we found that Na(+)/H(+) exchanger (NHE) inhibitors prevented muscle degeneration. NHE activity was constitutively enhanced in BIO myotubes, as evidenced by the elevated intracellular pH and enhanced (22)Na(+) influx, with activation of putative upstream kinases ERK42/44. NHE inhibitor significantly reduced the increases in baseline intracellular Ca(2+) as well as Na(+) concentration and stretch-induced damage, suggesting that Na(+)(i)-dependent Ca(2+)overload via the Na(+)/Ca(2+) exchanger may cause muscle damage. Furthermore, ATP was found to be released continuously from BIO myotubes in a manner further stimulated by stretching and that the P2 receptor antagonists reduce the enhanced NHE activity and dystrophic muscle damage. These observations suggest that autocrine ATP release may be primarily involved in genesis of abnormal ionic homeostasis in dystrophic muscles and that Na(+)-dependent ion exchangers play a critical pathological role in muscular dystrophy.

Dimerization is crucial for the function of the Na+/H+ exchanger NHE1.

The Na(+)/H(+) exchanger 1 (NHE1) exists as a homo-dimer in the plasma membranes. In the present study, we have investigated the functional significance of the dimerization, using two nonfunctional NHE1 mutants, surface-expression-deficient G309V and transport-deficient E262I. Biochemical and immunocytochemical experiments revealed that these NHE1 mutants are capable of interacting with the wild-type NHE1 and, thus, forming a heterodimer. Expression of G309V retained the wild-type NHE1 to the ER membranes, suggesting that NHE1 would first form a dimer in the ER. On the other hand, expression of E262I markedly reduced the exchange activity of the wild-type NHE1 through an acidic shift in the intracellular pH (pH(i)) dependence, suggesting that dimerization is required for exchange activity in the physiological pH(i) range. However, a dominant-negative effect of E262I was not detected when exchange activity was measured at acidic pH(i), implying that one active subunit is sufficient to catalyze ion transport when the intracellular H(+) concentration is sufficiently high. Furthermore, intermolecular cysteine cross-linking at extracellular position Ser(375) with a bifunctional sulfhydryl reagent dramatically inhibited exchange activity mainly by inducing the acidic shift of pH(i) dependence and abolished extracellular stimuli-induced activation of NHE1 without causing a large change in the affinities for extracellular Na(+) or an inhibitor EIPA. Because monofunctional sulfhydryl regents had no effect, it is likely that cross-linking inhibited the activity of NHE1 by restricting a coupled motion between the two subunits during transport. Taken together, these data support the view that dimerization of two active subunits are required for NHE1 to possess the exchange activity in the neutral pH(i) range, although each subunit is capable of catalyzing transport in the acidic pH(i) range.

Crystal structure of CHP2 complexed with NHE1-cytosolic region and an implication for pH regulation.

The plasma membrane Na+/H+ exchangers (NHE) require calcineurin B homologous protein (CHP) as an obligatory binding partner for ion transport. Here, we report the first crystal structure of CHP (CHP2 isoform) in complex with its binding domain in NHE1. We show that the cytoplasmic alpha-helix of NHE1 is inserted into the hydrophobic cleft formed by N- and C-lobes of CHP2 and that the size and shape of this crevice together with hydrogen bond formation at multiple positions assure a high degree of specificity for interaction with NHE members. Structure-based mutagenesis revealed the importance of hydrophobic interactions between CHP/NHE1 for the function of NHE1. Furthermore, the crystal structure shows the existence of a protruding CHP-unique region, and deletion of this region in CHP2 inhibited the NHE1 activity by inducing the acidic shift of intracellular pH dependence, while preserving interaction with NHE1. These findings suggest that CHP serves as an obligatory subunit that is required both for supporting the basic activity and regulating the pH-sensing of NHE1 via interactions between distinct parts of these proteins.

Mutations of Arg440 and Gly455/Gly456 oppositely change pH sensing of Na+/H+ exchanger 1.

To identify important amino acid residues involved in intracellular pH (pH(i)) sensing of Na(+)/H(+) exchanger 1, we produced single-residue substitution mutants in the region of the exchanger encompassing the putative 11th transmembrane segment (TM11) and its adjacent intracellular (intracellular loop (IL) 5) and extracellular loops (extracellular loop 6). Substitution of Arg(440) in IL5 with other residues except positively charged Lys caused a large shift in pH(i) dependence of (22)Na(+) uptake to an acidic side, whereas substitution of Gly(455) or Gly(456) within the highly conserved glycine-rich sequence of TM11 shifted pH(i) dependence to an alkaline side. The observed alkaline shift was larger with substitution of Gly(455) with residues with increasing sizes, suggesting the involvement of the steric effect. Interestingly, mutation of Arg(440) (R440D) abolished the ATP depletion-induced acidic shift in pH(i) dependence of (22)Na(+) uptake as well as the cytoplasmic alkalinization induced by various extracellular stimuli, whereas with that of Gly(455) (G455Q) these functions were preserved. These mutant exchangers did not alter apparent affinities for extracellular transport substrates Na(+) and H(+) and the inhibitor 5-(N-ethyl-N-isopropyl)amiloride. These results suggest that positive charge at Arg(440) is required for normal pH(i) sensing, whereas mutation-induced perturbation of the TM11 structure may be involved in the effects of Gly mutations. Thus, both Arg(440) in IL5 and Gly residues in the conserved segment of TM11 appear to constitute important elements for proper functioning of the putative "pH(i) sensor" of Na(+)/H(+) exchanger 1.

Dimeric interaction between the cytoplasmic domains of the Na+/H+ exchanger NHE1 revealed by symmetrical intermolecular cross-linking and selective co-immunoprecipitation.

To investigate the oligomeric structure of Na(+)/H(+) exchanger 1 (NHE1), permeabilized cells and membranes from cells expressing NHE1 variants were treated with the oxidizing agent Cu(2+)/o-phenanthroline or the bifunctional sulfhydryl reagent methanethiosulfonate. These treatments resulted in symmetrical intermolecular cross-linking at intrinsic (Cys(794) and Cys(561)) or 15 exogenous cysteine residues introduced into the distal carboxyl- (C-) terminal cytoplasmic domain (after aa 600) but not at intrinsic Cys(538) because of masking by its tight association with calcineurin B-homologous protein. Cross-linking was abolished in membranes solubilized with sodium dodecyl sulfate, which dissociates oligomeric NHE1, while it was preserved in those treated with Triton X-100. In addition, treatment with cross-linkers did not produce the tetrameric forms of NHE1 mutants with two cysteine residues. Thus, cross-linking presumably occurs between adjacent C-termini of the NHE1 dimer but not by a stochastic process via random collision of NHE1 molecules. The observations suggest that at least the distal C-termini of the NHE1 dimer are flexible or mobile and are thereby capable of easily making contact with each other over the large cytoplasmic portion of the molecule. Furthermore, co-immunoprecipitation experiments showed that the proximal C-termini (aa 503-580) have a strong propensity to interact directly with each other in parallel. Deletion of aa 562-579 resulted in disruption of disulfide cross-linking between the C-termini and markedly reduced the intracellular pH sensitivity of Na(+)/H(+) exchange, suggesting that the dimeric interaction in this region may control the pH-dependent regulation of NHE1.

Kinetic dissection of two distinct proton binding sites in Na+/H+ exchangers by measurement of reverse mode reaction.

We examined the effect of intracellular acidification on the reverse mode of Na+/H+ exchange by measuring 22Na+ efflux from 22Na+-loaded PS120 cells expressing the Na+/H+ exchanger (NHE) isoforms NHE1, NHE2, and NHE3. The 5-(N-ethyl-N-isopropyl)amiloride (EIPA)- or amiloride-sensitive fraction of 22Na+ efflux was dramatically accelerated by cytosolic acidification as opposed to thermodynamic prediction, supporting the concept that these NHE isoforms are activated by protonation of an internal binding site(s) distinct from the H+ transport site. Intracellular pH (pHi) dependence of 22 Na+ efflux roughly exhibited a bell-shaped profile; mild acidification from pHi 7.5 to 7 dramatically accelerated 22Na+ efflux, whereas acidification from pHi 6.6 gradually decreased it. Alkalinization above pHi 7.5 completely suppressed EIPA-sensitive 22Na+ efflux. Cell ATP depletion and mutation of NHE1 at Arg440 (R440D) caused a large acidic shift of the pHi profile for 22Na+ efflux, whereas mutation at Gly455 (G455Q) caused a significant alkaline shift. Because these mutations and ATP depletion cause correspondingly similar effects on the forward mode of Na+/H+ exchange, it is most likely that they alter exchange activity by modulating affinity of the internal modifier site for protons. The data provide substantial evidence that a proton modifier site(s) distinct from the transport site controls activities of at least three NHE isoforms through cooperative interaction with multiple protons.

Role of calcineurin B homologous protein in pH regulation by the Na+/H+ exchanger 1: tightly bound Ca2+ ions as important structural elements.

We studied the role of the interaction of calcineurin homologous protein 1 (CHP1) with the Na(+)/H(+) exchanger 1 (NHE1), particularly its EF-hand Ca(2+) binding motifs, in the intracellular pH (pH(i))-dependent regulation of NHE1. We found that (45)Ca(2+) binds to two EF-hand motifs (EF3 and 4) of the recombinant CHP1 proteins with high affinity (apparent K(d) = approximately 90 nM). Complex formation between CHP1 and the CHP1 binding domain of NHE1 resulted in a marked increase in the Ca(2+) binding affinity (K(d) = approximately 2 nM) by promoting a conformational change of the EF-hands toward the tightly Ca(2+)-bound form. This suggests that CHP1 always contains two Ca(2+) ions when associated with NHE1 in cells. Interestingly, overexpression of GFP-tagged CHP1 with mutations in EF3 or EF4 significantly reduced the exchange activity in the neutral pH(i) range and partly impaired the activation of NHE1 in response to various stimuli, such as growth factors and osmotic stress. Furthermore, we found that, in addition to reducing the activity (V(max)), a CHP1 binding-defective NHE1 mutant had a marked reduction in pH(i) sensitivity ( approximately 0.7 pH unit acidic shift), which consequently abolished various regulatory responses of NHE1. These observations suggest that the association of NHE1 with CHP1 is crucial for maintenance of the pH(i) sensitivity of NHE1 and that tightly bound Ca(2+) ions may serve as important structural elements in the "pH(i) sensor" of NHE1.