Complex RNA processing of TDRKH, a novel gene encoding the putative RNA-binding tudor and KH domains.

The sequence from a human EST (IMAGE:259322) with homology to the nucleotide-sensitive chloride conductance regulator (ICln) was used to screen a human aortic cDNA library. The probe sequence was from a region of the EST lacking homology to ICln, and the goal was to isolate an ICln-like gene. A 2843bp cDNA clone with an open reading frame coding for a 561 amino acid protein was isolated. This clone had no homology to ICln. PROSITE analysis of the putative protein sequence reveals one tudor and two K homology (KH) domains. The gene has therefore been named TDRKH. Both KH and tudor motifs are involved in binding to RNA or single-strand DNA. PCR analysis demonstrated that TDRKH is alternatively spliced in several ways and alternatively polyadenylated at multiple sites. Northern analysis confirmed the presence of messages of multiple lengths with predominant bands at 2.8 and 4.0 kb and also demonstrated that TDRKH is widely expressed in human tissues. Within an intron of TDRKH, there is a region with 90% homology to ICln. This sequence, which is incorporated into the alternatively spliced message represented by IMAGE:259322, contains a 2 bp deletion that disrupts the ICln reading frame and therefore represents an ICln pseudogene. The TDRKH gene was mapped to the Epidermal Differentiation Complex (EDC) at chromosome 1q21 by radiation hybrid mapping and STS content of genomic clones from that region. The EDC contains a large cluster of related genes involved in terminal differentiation of the epidermis. It remains to be determined whether TDRKH has a specific role in epithelial function.

Cyclic GMP-independent mechanisms of nitric oxide-induced vasodilation.

1. The aim of the present study was to test in vitro if NO acts through a cyclic GMP-independent mechanism to activate Ca2+-dependent potassium channels (K+(Ca)), leading to membrane hyperpolarization and vasodilation in rat tail artery. 2. Acetylcholine and sodium nitroprusside stimulated a significant increase in cyclic GMP (190+/-23 and 180+/-15 pmol/g, respectively) compared with agonist-free conditions (132+/-15 and 130+/-15 pmol/g, respectively); these agonist-mediated increases in cyclic GMP were completely abolished by treatment with the guanylate cyclase inhibitor methylene blue (122+/-10 and 60+/-8 pmol/g, respectively). 3. In contrast, relaxation to acetylcholine (10(-7) mol/l; 61+/-3%) and sodium nitroprusside (10(-8) mol/l; 97+/-1%) were significantly, but not completely, attenuated by methylene blue (30+/-5 and 79+/-3%, respectively); maximum relaxation to sodium nitroprusside (10(-7) mol/l) was unaffected by methylene blue. 4. Depolarization-induced contraction of vessels with KCl inhibited relaxation to both acetylcholine (10(-7) mol/l; 18+/-4%) and sodium nitroprusside (10(-8) mol/l; 57+/-7%). Furthermore, the specific K+(Ca) antagonist charybdotoxin significantly inhibited relaxation to sodium nitroprusside (10(-8) mol/l; 52+/-7%). 5. An additive inhibitory effect on relaxation to sodium nitroprusside (10(-8) mol/l) was observed with a combination of methylene blue and KCl (26+/-6%) or charybdotoxin (34+/-3%). 6. These data suggest that NO stimulates membrane hyperpolarization via K+(Ca) activation, in addition to guanylate cyclase, to cause relaxation in rat tail artery.

Synergistic actions of insulin and troglitazone on contractility in endothelium-denuded rat aortic rings.

Insulin attenuates vascular contraction via inhibition of voltage-operated Ca2+ channels and by enhancement of endothelium-dependent vasodilation. Thus it has been suggested that hypertension-associated insulin resistance results from an insensitivity to the hormone's effects on vascular reactivity. This hypothesis has been strengthened by reports that thiazolidinediones, a class of insulin-sensitizing agents, lower blood pressure and improve insulin responsiveness in hypertensive, insulin-resistant animal models. We tested the hypothesis that troglitazone enhances the vasodilating effect of insulin via inhibition of voltage-operated Ca2+ channels in vascular smooth muscle cells. Rat thoracic aortic rings (no endothelium) were suspended in tissue baths for isometric force measurement. Rings were incubated with 0.1 DMSO vehicle (control), troglitazone (10(-5) M), insulin (10(-7) U/l), or both troglitazone and insulin (1 h) and then contracted with phenylephrine (PE), KCl, or BAY K 8644. Troglitazone increased the EC50 values for PE and KCl. Contractions to BAY K 8644 in troglitazone-treated rings were virtually abolished. Insulin alone had no effect on contraction. However, when insulin was combined with troglitazone, the EC50 values for PE and KCl were further increased. Additionally, the maximum contractions to both PE (14 +/- 4% of control) and KCl (12 +/- 2% of control) were reduced. Measurement of Ca2+ concentration ([Ca2+]) with fura 2-AM in dispersed vascular smooth muscle cells indicated that neither insulin nor troglitazone alone altered PE-induced increases in intracellular [Ca2+]. However, troglitazone and insulin together caused a significant reduction in PE-induced increases in intracellular [Ca2+] (expressed as percentage of preincubation stimulation to PE: 47 +/- 10%, treated; 102 +/- 13%, vehicle). These results demonstrate that troglitazone inhibits Ca2+ influx and that it acts synergistically with insulin to attenuate further vascular contraction via inhibition of voltage-operated Ca2+ channels.

Quinapril prevents hypertension and enhanced vascular reactivity in nitroarginine-treated rats.

Long-term inhibition of nitric oxide synthase (NOS) by substituted arginine analogues has previously been shown to induce systemic hypertension in several animal species; however, the precise mechanisms for the elevated blood pressure remain unclear. We hypothesized that a portion of the hypertensive response to arginine analogues was due to direct inhibition of endothelial NOS and resultant functional alterations in the vasculature that contribute to elevated systemic resistance. Adult Sprague-Dawley rats were treated for 2 weeks with an arginine analogue, N omega Nitro-L-arginine (L-NNA), alone or in combination with the angiotensin converting enzyme (ACE) inhibitor quinapril. Next, thoracic aortas were removed, cut into rings and suspended in isolated tissue baths for measurement of contractile force in response to vasoactive drugs. Our results showed that oral L-NNA treatment significantly elevated systolic blood pressure in rats that was completely prevented by quinapril. Furthermore, L-NNA treatment increased endothelium-dependent and -independent contractility and attenuated endothelium-dependent vasodilation in the thoracic aorta. These functional alterations were also attenuated by quinapril treatment. Therefore, long-term L-NNA-induced hypertension in rats is associated with enhanced vascular reactivity due both to direct inhibition of endothelial NOS and to stimulation of the renin-angiotensin system.

Photorelaxation is not attenuated by inhibition of the nitric oxide-cGMP pathway.

Photorelaxation of arteries by ultraviolet (UV) light is hypothesized to result from nitric oxide (NO) released from photoactivable stores. Recently, a study reported enhanced photorelaxation of aortic tissue from rats administered the NO synthase (NOS) inhibitor N omega-nitro-L-arginine (L-NNA). Presumably, the potentiated photorelaxation was due to NO generated from UV-light-induced decomposition of the NO2 moiety of L-NNA. However, we hypothesized that photorelaxation is: (1) not the result of NO synthesis and subsequent activation of guanylate cyclase and (2) not due to hyperpolarization induced by NO or any other factor. Endothelium-denuded rat aortic rings were suspended in isolated baths for isometric force measurement. Rings were exposed to UV light (366 nm) before addition of phenylephrine or KCI, and then at each agonist concentration during a cumulative concentration response curve. NOS inhibition by L-NNA and L-thiocitrulline, which lacks an NO2 group, enhanced photorelaxation of basal myogenic tone and contraction to phenylephrine (EC70). Furthermore, relaxation of a maximum phenylephrine-induced contraction to the NO donor S-nitroso-N-acetyl-D,L-penicillamine during UV light exposure was not altered by incubation of rings with L-NNA or tissues from animals fed L-NNA. These data demonstrate that NO is not produced endogenously or from the breakdown of L-NNA to result in photo-relaxation. Methylene blue (MB) did not alter photorelaxation, suggesting that cGMP is not essential to the response. MB and L-NNA together potentiated photorelaxation of basal myogenic tone and phenylephrine-induced contraction. Photorelaxation of KCl-induced contraction was unaltered, indicating that hyperpolarization does not contribute to the relaxation. Photorelaxation of basal myogenic tone and KCl-induced contraction excludes the possibility that UV light is interfering with agonist-receptor binding. Collectively, these results refute the hypotheses that photorelaxation results from activation of the NO-cGMP pathway, release of a hyperpolarization factor, or inhibition of drug-receptor interaction. Interestingly, photorelaxation may be inhibited by NO-cGMP pathway activation, uncovering a novel effect of this messenger system on vascular reactivity.