Ina Nordström

Stretch-Dependent Modulation of Contractility and Growth in Smooth Muscle of Rat Portal Vein

Increased intraluminal pressure of the rat portal vein in vivo causes hypertrophy and altered contractility in 1 to 7 days. We have used organ cultures to investigate mechanisms involved in this adaptation to mechanical load. Strips of rat portal vein were cultured for 3 days, either undistended or loaded by a weight. Length-force relations were shifted toward longer length in stretched cultured veins compared with freshly dissected veins, whereas the length-force relations of unstretched cultured veins were shifted in the opposite direction. This occurred after culture either with or without 10% FCS to promote growth. The wet weight of loaded veins increased by 56% in the presence of FCS, whereas that of undistended control veins increased by 24%. No weight increase was seen in serum-free culture. The dry/wet weight ratio decreased during culture with FCS but was not affected by stretch. Electron microscopy revealed increased cell cross-sectional area in stretched relative to unstretched veins, and protein contents were greater, as were [(3)H]thymidine and [(3)H]leucine incorporation rates. Growth responses were associated with the activation of stretch-sensitive extracellular signal-regulated kinases 1 and 2 and were inhibited by herbimycin A and PD 98059, inhibitors of extracellular signal-regulated kinases 1 and 2. The results demonstrate that by culture of whole vascular tissue, smooth muscle cells are maintained in the contractile phenotype and respond to stretch with a physiological adaptation involving hypertrophy/hyperplasia and remodeling of the contractile system, similar to that in vivo. Mechanical stimulation and growth factors are both required for functionally significant growth.

Long-term effects of Ca(2+) on structure and contractility of vascular smooth muscle

Culture of dispersed smooth muscle cells is known to cause rapid modulation from the contractile to the synthetic cellular phenotype. However, organ culture of smooth muscle tissue, with maintained extracellular matrix and cell-cell contacts, may facilitate maintenance of the contractile phenotype. To test the influence of culture conditions, structural, functional, and biochemical properties of rat tail arterial rings were investigated after culture. Rings were cultured for 4 days in the absence and presence of 10% FCS and then mounted for physiological experiments. Intracellular Ca2+concentration ([Ca2+]i) after stimulation with norepinephrine was similar in rings cultured with and without FCS, whereas force development after FCS was decreased by >50%. The difference persisted after permeabilization with β-escin. These effects were associated with the presence of vasoconstrictors in FCS and were dissociated from its growth-stimulatory action. FCS treatment increased lactate production but did not affect ATP, ADP, or AMP contents. The contents of actin and myosin were decreased by culture but similar for all culture conditions. There was no effect of FCS on calponin contents or myosin SM1/SM2 isoform composition, nor was there any appearance of nonmuscle myosin. FCS-stimulated rings showed evidence of cell degeneration not found after culture without FCS or with FCS + verapamil (1 μM) to lower [Ca2+]i. The decreased force-generating ability after culture with FCS is thus associated with increased [Ca2+]iduring culture and not primarily caused by growth-associated modulation of cells from the contractile to the synthetic phenotype.

Ablation of SM22α decreases contractility and actin contents of mouse vascular smooth muscle

The actin‐binding protein SM22α marks contractile differentiation in smooth muscle, but its function is unknown. We tested its role in arterial contractility and stretch‐sensitive vascular protein synthesis. Active stress in depolarised mesenteric resistance arteries and portal veins was reduced by 40% in SM22α−/− mice. Passive and active arterial circumference–force relationships were shifted leftwards, whereas α1‐adrenergic responses were increased. Actin contents were 10–25% lower in vessels from SM22α−/− mice, but protein composition was otherwise similar. Synthesis of SM22α, calponin and α‐actin, but not β‐actin, was sensitive to stretch. Ablation of SM22α did not affect stretch sensitivity of any of these proteins. Thus, SM22α plays a role in contractility, possibly by affecting actin filament organisation.

Rat arterial smooth muscle devoid of ryanodine receptor function: effects on cellular Ca2+ handling

The roles of intracellular Ca2+ stores and ryanodine (Ry) receptors for vascular Ca2+ homeostasis and viability were investigated in rat tail arterial segments kept in organ culture with Ry (10 – 100 μM) for up to 4 days. Acute exposure to Ry or the non‐deactivating ryanodine analogue C10‐Oeq glycyl ryanodine (10 μM) eliminated Ca2+ release responses to caffeine (20 mM) and noradrenaline (NA, 10 μM), whereas responses to NA, but not caffeine, gradually returned to normal within 4 days of exposure to Ry. Ry receptor protein was detected on Western blots in arteries cultured either with or without Ry. Brief Ca2+ release events (sparks) were absent after culture with Ry, whereas Ca2+ waves still occurred. The propagation velocity of waves was equal (∼19 μm s−1) in tissue cultured either with or without Ry. Inhibition of Ca2+ accumulation into the sarcoplasmic reticulum (SR) by culture with caffeine (5 mM), cyclopiazonic acid or thapsigargin (both 10 μM) decreased contractility due to Ca2+‐induced cell damage. In contrast, culture with Ry did not affect contractility. Removal of Ca2+ from the cytosol following a Ca2+ load was retarded after Ry culture. Thapsigargin reduced the rate of Ca2+ removal in control cultured rings, but had no effect after Ry culture. It is concluded that intracellular Ca2+ stores recover during chronic Ry treatment, while Ry receptors remain non‐functional. Ry receptor activity is required for Ca2+ sparks and for SR‐dependent recovery from a Ca2+ load, but not for Ca2+ waves or basal Ca2+ homeostasis.

PYK2 selectively mediates signals for growth versus differentiation in response to stretch of spontaneously active vascular smooth muscle.

Stretch of vascular smooth muscle stimulates growth and proliferation as well as contraction and expression of contractile/cytoskeletal proteins, all of which are also regulated by calcium‐dependent signals. We studied the role of the calcium‐ and integrin‐activated proline‐rich tyrosine kinase 2 (PYK2) in stretch‐induced responses of the rat portal vein loaded by a hanging weight ex vivo. PYK2 phosphorylation at Tyr‐402 was increased both by a 10‐min stretch and by organ culture with load over several days. Protein and DNA synthesis were reduced by the novel PYK2 inhibitor PF‐4594755 (0.5–1 μmol/L), while still sensitive to stretch. In 3‐day organ culture, PF‐4594755 caused maintained myogenic spontaneous activity but did not affect contraction in response to high‐K+ (60 mmol/L) or to α1‐adrenergic stimulation by cirazoline. Basal and stretch‐induced PYK2 phosphorylation in culture were inhibited by PF‐4594755, closely mimicking inhibition of non‐voltage‐dependent calcium influx by 2‐APB (30 μmol/L). In contrast, the L‐type calcium channel blocker, nifedipine (1 μmol/L) eliminated stretch‐induced but not basal PYK2 phosphorylation. Stretch‐induced Akt and ERK1/2 phosphorylation was eliminated by PF‐4594755. PYK2 inhibition had no effect on mRNA expression of several smooth muscle markers, and stretch‐sensitive SM22α synthesis was preserved. Culture of portal vein with the Ang II inhibitor losartan (1 μmol/L) eliminated stretch sensitivity of PYK2 and Akt phosphorylation, but did not affect mRNA expression of smooth muscle markers. The results suggest that PYK2 signaling functionally distinguishes effects of voltage‐ and non‐voltage‐dependent calcium influx. A small‐molecule inhibitor of PYK2 reduces growth and DNA synthesis but does not affect contractile differentiation of vascular smooth muscle.

Pyk2 inhibition promotes contractile differentiation in arterial smooth muscle

Modulation from contractile to synthetic phenotype of vascular smooth muscle cells is a central process in disorders involving compromised integrity of the vascular wall. Phenotype modulation has been shown to include transition from voltage‐dependent toward voltage‐independent regulation of the intracellular calcium level, and inhibition of non‐voltage dependent calcium influx contributes to maintenance of the contractile phenotype. One possible mediator of calcium‐dependent signaling is the FAK‐family non‐receptor protein kinase Pyk2, which is activated by a number of stimuli in a calcium‐dependent manner. We used the Pyk2 inhibitor PF‐4594755 and Pyk2 siRNA to investigate the role of Pyk2 in phenotype modulation in rat carotid artery smooth muscle cells and in cultured intact arteries. Pyk2 inhibition promoted the expression of smooth muscle markers at the mRNA and protein levels under stimulation by FBS or PDGF‐BB and counteracted phenotype shift in cultured intact carotid arteries and balloon injury ex vivo. During long‐term (24–96 hr) treatment with PF‐4594755, smooth muscle markers increased before cell proliferation was inhibited, correlating with decreased KLF4 expression and differing from effects of MEK inhibition. The Pyk2 inhibitor reduced Orai1 and preserved SERCA2a expression in carotid artery segments in organ culture, and eliminated the inhibitory effect of PDGF stimulation on L‐type calcium channel and large‐conductance calcium‐activated potassium channel expression in carotid cells. Basal intracellular calcium level, calcium wave activity, and store‐operated calcium influx were reduced after Pyk2 inhibition of growth‐stimulated cells. Pyk2 inhibition may provide an interesting approach for preserving vascular smooth muscle differentiation under pathophysiological conditions.

Injury to rat carotid arteries causes time-dependent changes in gene expression in contralateral uninjured arteries

Vascular surgery aimed at stenosis removal induces local reactions often leading to restenosis. Although extensive analysis has been focused on pathways activated in injured arteries, little attention has been devoted to associated systemic vascular reactions. The aim of the present study was to analyse changes occurring in contralateral uninjured rat carotid arteries in the acute phase following unilateral injury. WKY (Wistar-Kyoto) rats were subjected to unilateral carotid arteriotomy. Contralateral uninjured carotid arteries were harvested from 4 h to 7 days after injury. Carotid arteries were also harvested from sham-operated rats and uninjured rats. Carotid morphology and morphometry were examined. Affymetrix microarrays were used for differential analysis of gene expression. A subset of data was validated by real-time RT-PCR (reverse transcription-PCR) and verified at the protein level by Western blotting. A total of 1011 genes were differentially regulated in contralateral uninjured carotid arteries from 4 h to 7 days after arteriotomy (P<0.0001; fold change, >or=2) and were classified into 19 gene ontology functional categories. To a lesser extent, mRNA variations also occurred in carotid arteries of sham-operated rats. Among the changes, up-regulation of members of the RAS (renin-angiotensin system) was detected, with possible implications for vasocompensative mechanisms induced by arteriotomy. In particular, a selective increase in the 69 kDa isoform of the N-domain of ACE (angiotensin-converting enzyme), and not the classical somatic 195 kDa isoform, was observed in contralateral uninjured carotid arteries, suggesting that this 69 kDa isoenzyme could influence local AngII (angiotensin II) production. In conclusion, systemic reactions to injury occur in the vasculature, with potential clinical relevance, and suggest that caution is needed in the choice of controls during experimental design in vivo.