Molecular cloning and expression of murine smooth muscle myosin heavy chains

Pkd2+/- vascular smooth muscles develop exaggerated vasocontraction in response to phenylephrine stimulation

Vascular complications are the leading cause of morbidity and mortality in autosomal dominant polycystic kidney disease. Although evidence suggests an abnormal vascular reactivity, contractile function in Pkd mutant vessels has not been studied previously. Contractile response to phenylephrine (PE; 10(-10) to 10(-4)M), an alpha1-adrenergic receptor agonist, was examined. De-endothelialized Pkd2(+/-) aortic rings generated a higher maximum force (F(max)) than that in wild-type (wt; 5.78 +/- 0.73 versus 2.69 +/- 0.43 mN; P < 0.001) and a significant left shift in PE dosage-response curve. On simultaneous recordings, Pkd2(+/-) aortic helical strips also responded to PE with a greater F(max) but a lesser [Ca(2+)](i) rise, resulting in a greatly enhanced Deltaforce/DeltaCa(2+) ratio than that in wt. At F(max), a higher elevation in the phosphorylated regulatory myosin light chain was observed in Pkd2(+/-) strips. Ca(2+)-dependent calmodulin/myosin light-chain kinase-mediated contraction was examined by direct Ca(2+) (pCa8-5) stimulation to beta-escin permeabilized aortic strips; the pCa-force curve in Pkd2(+/-) strips was not shifted, thereby indicating that PE induced dosage-response alteration that resulted from Ca(2+)-independent mechanisms. Quantitative analyses of contractile proteins demonstrated elevated expressions in smooth muscle alpha-actin and myosin heavy chain in Pkd2(+/-) arteries, changes that likely contribute to the higher F(max). Similar to those in aortas, de-endothelialized Pkd2(+/-) resistance (fourth-order mesenteric) arteries responded to PE with a stronger contraction but a lesser [Ca(2+)](i) rise than in wt. Taken together, the arterial vasculature in Pkd2(+/-) mice exhibits an exaggerated contractile response and increased sensitivity to PE. An enhanced Ca(2+)-independent force generation and elevated contractile protein expression likely contribute to these abnormalities.

Regulation of the guanylyl cyclase-B receptor by alternative splicing

Guanylyl cyclase-B (GC-B) is a single transmembrane receptor that binds C-type natriuretic peptide (CNP). The ligand/receptor appears critical in the regulation of cell proliferation and differentiation where it acts as an adversary of mitogenic signaling pathways. We have isolated three guanylyl cyclase-B isoforms generated from a single gene by alternative splicing and termed them GC-B1, GC-B2, and GC-B3. GC-B1 is full-length and responds maximally to CNP, GC-B2 contains a 25-amino acid deletion in the protein kinase homology domain, and GC-B3 only retains a part of the extracellular ligand-binding domain. GC-B2 binds CNP, but the ligand fails to activate the cyclase, while GC-B3 fails to bind ligand. When GC-B2 or GC-B3 is expressed coincident with GC-B1, they act as dominant negative isoforms by virtue of blocking formation of active GC-B1 homodimers. Relative expression levels of GC-B1, GC-B2, and GC-B3 vary across tissues and as a function of in vitro culture; the relative amount of GC-B2 to GC-B1 is repressed in cultured smooth muscle cells relative to endogenous ratios in the medial layer cells of the aorta. Thus, GC-B isoform levels can be independently regulated. Given that the splice variants serve as dominant negative forms, these will serve as regulators of the full-length GC-B.