cGMP-mediated phosphorylation of heat shock protein 20 may cause smooth muscle relaxation without myosin light chain dephosphorylation in swine carotid artery.

Nitrovasodilators such as nitroglycerine, via production of nitric oxide and an increase in [cGMP], can induce arterial smooth muscle relaxation without proportional reduction in myosin light chain (MLC) phosphorylation or myoplasmic [Ca2+]. These findings suggest that regulatory systems, other than MLC phosphorylation and Ca2+, partially mediate nitroglycerine-induced relaxation. In swine carotid artery, we found that a membrane-permeant cGMP analogue induced relaxation without MLC dephosphorylation, suggesting that cGMP mediated the relaxation. Nitroglycerine-induced relaxation was associated with a reduction in O2 consumption, suggesting that the interaction between phosphorylated myosin and the thin filament was inhibited. Nitroglycerine-induced relaxation was associated with a 10-fold increase in the phosphorylation of a protein on Ser16. We identified this protein as heat shock protein 20 (HSP20), a member of a family of proteins known to bind to thin filaments. When homogenates of nitroglycerine-relaxed tissues were centrifuged at 6000 g, phosphorylated HSP20 preferentially sedimented in the pellet, suggesting that phosphorylation of HSP20 may increase its affinity for the thin filament. We noted that a domain of HSP20 is partially homologous to the 'minimum inhibitory sequence' of skeletal troponin I. The peptide HSP20110-121, which contains this domain, bound to actin-containing filaments only in the presence of tropomyosin, a characteristic of troponin I. High concentrations of HSP20110-121 abolished Ca2+-activated force in skinned swine carotid artery. HSP20110-121 also partially decreased actin-activated myosin S1 ATPase activity. These data suggest that cGMP-mediated phosphorylation of HSP20 on Ser16 may have a role in smooth muscle relaxation without MLC dephosphorylation. HSP20 contains an actin-binding sequence at amino acid residues 110-121 that inhibited force production in skinned carotid artery. We hypothesize that phosphorylation of HSP20 regulates force independent of MLC phosphorylation via binding of HSP20 to thin filaments and inhibition of cross-bridge cycling.

Ca2+ sensitivity of stunned myocardium after skinning using retrograde infusion of detergent.

Myofilament Ca2+ desensitization contributes to the contractile dysfunction of ischemic/reperfused ("stunned") myocardium. We examined the presence of reduced Ca2+ sensitivity of isometric force in chemically skinned fibers obtained from stunned myocardium using different modes of applying the detergent Triton X-100. Langendorff-perfused rat hearts underwent 20 min ischemia/20 min reperfusion, which caused a 35 +/- 3% decrease in left ventricular developed pressure, compared to continuously perfused control hearts. Stunned and control hearts were randomly allocated to two different permeabilization protocols: In group A, trabeculae were dissected and immersed in skinning solution containing 1% Triton X-100 for 20 min. Group B hearts remained fixed to the aortic cannula and skinning solution was infused retrogradely for 6 min prior to dissection of trabeculae. Extraction of cytosolic marker proteins was more complete in group-B than in group-A preparations. Group-A preparations from stunned hearts exhibited significant Ca2+ desensitization (pCa50 = 5.07 and 5.15 in stunned and control myocardium, respectively). In group B no such difference was observed, all preparations showing higher Ca2+ sensitivity and maximum force than group-A preparations (pCa50 = 5.32 in stunned versus 5.33 in control hearts). Prolonging group-A skinning to 150 min also abolished the difference in Ca2+ sensitivity between stunned and control myocardium. In conclusion, compared to a conventional protocol, skinning by perfusion results in more complete permeabilization and better preservation of myocardial contractile function. Ischemia/reperfusion at this moderate degree of contractile dysfunction induces Ca2+ desensitization at least partially by factors that can be extracted by thorough skinning.

cGMP mediates corpus cavernosum smooth muscle relaxation with altered cross-bridge function.

We tested the prevailing paradigm that relaxation of corpus cavernosum smooth muscle (CCSM) and penile erection depends upon nitric oxide-induced elevation of myoplasmic cGMP and reduced Ca2+-dependent myosin regulatory light chain phosphorylation levels. This hypothesis invokes a reversal of normal activation pathways. Upon stimulation with 250 microM phenylephrine, phosphorylation of the 20 kD myosin regulatory light chains of rabbit or human CCSM increased approximately 4-fold coincident with contraction. Removal of the agonist was followed by a slow reduction in cross-bridge phosphorylation and force to basal levels. The NO donor, sodium nitroprusside elicited a dose-dependent increase in tissue [cGMP] associated with a rapid relaxation in the continued presence of phenylephrine, although cross-bridge phosphorylation remained significantly elevated. Thus the NO-cGMP inhibitory pathway in CCSM is not simply a reversal of excitatory signal transduction mechanisms. An unidentified mechanism contributes to relaxation by decreasing the rate of cross-bridge recruitment through phosphorylation.

Different molecular mechanisms for Rho family GTPase-dependent, Ca2+-independent contraction of smooth muscle.

Abnormal smooth muscle contraction may contribute to diseases such as asthma and hypertension. Alterations to myosin light chain kinase or phosphatase change the phosphorylation level of the 20-kDa myosin regulatory light chain (MRLC), increasing Ca2+ sensitivity and basal tone. One Rho family GTPase-dependent kinase, Rho-associated kinase (ROK or p160(ROCK)) can induce Ca2+-independent contraction of Triton-skinned smooth muscle by phosphorylating MRLC and/or myosin light chain phosphatase. We show that another Rho family GTPase-dependent kinase, p21-activated protein kinase (PAK), induces Triton-skinned smooth muscle contracts independently of calcium to 62 +/- 12% (n = 10) of the value observed in presence of calcium. Remarkably, PAK and ROK use different molecular mechanisms to achieve the Ca2+-independent contraction. Like ROK and myosin light chain kinase, PAK phosphorylates MRLC at serine 19 in vitro. However, PAK-induced contraction correlates with enhanced phosphorylation of caldesmon and desmin but not MRLC. The level of MRLC phosphorylation remains similar to that in relaxed muscle fibers (absence of GST-mPAK3 and calcium) even as the force induced by GST-mPAK3 increases from 26 to 70%. Thus, PAK uncouples force generation from MRLC phosphorylation. These data support a model of PAK-induced contraction in which myosin phosphorylation is at least complemented through regulation of thin filament proteins. Because ROK and PAK homologues are present in smooth muscle, they may work in parallel to regulate smooth muscle contraction.

Sildenafil, a type-5 CGMP phosphodiesterase inhibitor, specifically amplifies endogenous cGMP-dependent relaxation in rabbit corpus cavernosum smooth muscle in vitro.

PURPOSE: The primary mechanism for relaxation of corpus cavernosum smooth muscle (CCSM) and penile erection depends upon nitric oxide (NO)-induced elevation of myoplasmic cyclic guanosine monophosphate (cGMP). Agents that enhance the NO-cGMP signal transduction pathway may prove beneficial in treating erectile dysfunction. Sildenafil, a selective type-5 cGMP phosphodiesterase inhibitor, was investigated to determine the specific mechanism(s) involved in the therapeutic use of this compound to treat impotence. MATERIALS AND METHODS: Isolated strips of rabbit corpus cavernosum were stimulated isometrically with phenylephrine. Graded relaxations were induced using various concentrations of sodium nitroprusside (SNP) alone and in combination with sildenafil. At fixed times, the tissues were rapidly frozen and processed for myosin light chain (MLC) phosphorylation using isoelectric focusing with Western blot analysis, and cGMP content using radioimmunoassay techniques. RESULTS: Sildenafil alone reduced spontaneous tone in unstimulated CCSM, but had little effect on phenylephrine-induced isometric tension in the absence of a NO donor (SNP). Sildenafil sensitized the tissue to SNP for relaxation, but the relationship between relaxation and [cGMP] was unchanged by sildenafil. Relaxation from peak isometric force was correlated with [cGMP] but not MLC phosphorylation. CONCLUSIONS: Sildenafil relaxes CCSM by amplifying the effects of the normal, endogenous cGMP dependent relaxation mechanisms.

Heterologous desensitization of smooth muscle to K+ depolarization: retarded stimulus-[Ca2+]i coupling.

To understand the phenomenon of postreceptor heterologous desensitization, we exposed porcine carotid media to 40 mM KCl physiological saline solution both before and after intervening treatment with histamine. Increasing histamine concentration or duration of exposure or decreasing the interval between histamine exposure and KCl progressively slowed the contractile responses to K+ depolarization. A delay in initiation and a slower rate of rise of KCl-induced stress in histamine-pretreated muscle were preceded by a slower rate of rise of aequorin-estimated myoplasmic Ca2+ concentration ([Ca2+]i), myosin regulatory light chain (MRLC) phosphorylation, and tissue stiffness, with no detectable change in the Ca2+ sensitivity of MRLC phosphorylation. This heterologous desensitization was not a diminished steady-state force but instead a profound slowing of contraction rates. This slowing was a manifestation of retardation of the rate at which [Ca2+]i rises to the level appropriate for the stimulus. The lack of rapid initial [Ca2+]i and cross-bridge phosphorylation transients as a consequence of histamine pretreatment resulted in very slow cross-bridge cycling rates and rates of force development (latch).

Myosin isoforms and functional diversity in vertebrate smooth muscle.

The expression of fast and slow myosin isoforms in individual cells is associated with differences in shortening velocities and power output in fully differentiated vertebrate striated muscle. This paradigm in which shortening velocity is determined by the myosin isoform (and load) is inappropriate for smooth muscle. Smooth muscle tissues express multiple myosin heavy and light chain isoforms, and it is not currently possible to separate and identify chemically distinct native myosin hexamers (i.e., isoforms). It is not known if different isoforms are localized in subpopulations of cells or in specific cellular domains nor whether they combine preferentially to form a small number of native myosin hexamer isoforms. Potentially, thick filaments are aggregates of many different combinations of heavy and light chain isoforms that may or may not exhibit different kinetics. Shortening velocities in smooth muscle are regulated by Ca(2+)-dependent crossbridge phosphorylation of the myosin regulatory light chains. Much of the observed diversity in power output in smooth muscle may be attributed to regulatory mechanisms modulating crossbridge cycling rates rather than contractile protein isoform expression.

Recombinant troponin I substitution and calcium responsiveness in skinned cardiac muscle.

Using treatment with vanadate solutions, we extracted native cardiac troponin I and troponin C (cTnI and cTnC) from skinned fibers of porcine right ventricles. These proteins were replaced by exogenously supplied TnI and TnC isoforms, thereby restoring Ca2+-dependent regulation. Force then depended on the negative logarithm of Ca2+ concentration (pCa) in a sigmoidal manner, the pCa for 50% force development, pCa50, being about 5.5. For reconstitution we used fast-twitch rabbit skeletal muscle TnI and TnC (sTnI and sTnC), bovine cTnI and cTnC or recombinant sTnIs that were altered by site-directed mutagenesis. Incubation with TnI inhibited isometric tension in TnI-extracted fibers in the absence of Ca2+, but restoration of Ca2+ dependence required incubation with both TnI and TnC. Relaxation at low Ca2+ levels and the steepness of the force/pCa relation depended on the concentration of exogenously supplied TnI in the reconstitution solution (range 20-150 "mu"M), while Ca2+ sensitivity, i.e. the pCa50, was dependent on the isoform, and also on the concentration of TnC in the reconstitution solution. At pH 6.7, skinned fibers reconstituted with optimal concentrations of sTnC and sTnI (120 "mu"M and 150 "mu"M, respectively) were more sensitive to Ca2+ than those reconstituted with cTnC and cTnI (difference in pCa50 approx. 0.2 units). Rabbit sTnI was cloned and expressed in Escherichia coli using a high yield expression plasmid. We introduced point mutations into the TnI inhibitory region comprising the sequence of the minimal common TnC/actin binding site (-G104-K-F-K-R-P-P-L-R-R-V-R115-). The four mutants produced by substitution of T for P110, G for P110, G for L111, and G for K105 were chosen, based on previous work with synthetic peptides showing that single amino acid substitution in this region diminished the capacity of these peptides to inhibit acto-S1 ATPase or contraction of skinned fibers. Therefore, all amino acid residues of the inhibitory region are thought to contribute to biological activity of TnI. However, each of the recombinant TnIs could substitute for endogenous TnI. In combination with exogenous TnC, Ca2+ dependence could be restored when gly110sTnI, thr110sTnI or gly111sTnI was used for reconstitution. The mutant gly105sTnI, on the other hand, reduced the ability of skinned fibers to relax at low Ca2+ concentrations and it caused an increase in Ca2+ sensitivity.

The Ca2+ sensitizer EMD 53998 antagonizes the effect of 2,3-butanedione monoxime on skinned cardiac muscle fibres.

The effects of 2,3-butanedione monoxime (BDM) and 5-[1-(3,4-dimethoxybenzoyl)-1,2,3,4-tetrahydro-6-quinolyl]-6-me thy l-3,6-dihydro-2H-1,3,4-thiadiazin-2-one (EMD 53998) on cardiac muscle were studied in skinned muscle fibres from the right ventricle of the porcine heart. BDM decreases the Ca2+ sensitivity (pCa50 for 50% activation) and it exerts a dose-dependent inhibitory effect on force in troponin I (TnI)-depleted (unregulated) cardiac skinned muscle fibres (IC50 approximately 20 mM) thereby mimicking the effect of the TnI inhibitory peptide (cTnI 137-148, corresponding to the cardiac TnI inhibitory region) and that of inorganic phosphate (Pi). This inhibitory action can be antagonized by the calcium-sensitizing cardiotonic thiadiazinone derivative EMD 53998 that increases the IC50 to about 30 mM. In skinned fibres, BDM (10 mM) also increased the ratio of ATPase activity to isometric force (tension cost), whereas EMD 53998 (20 mu M) decreased it. We propose that BDM antagonizes EMD 53998 because both compounds affect the Pi release step of the crossbridge cycle in an antagonistic manner.

Ca2+ sensitizing effects of EMD 53998 after troponin replacement in skinned fibres from porcine atria and ventricles.

Skinned fibres from porcine ventricles exhibited a higher Ca2+ sensitivity (pCa50, i.e. -log10 Ca2+ concentration required for half-maximal activation, for force generation) than atrial fibres. The thiadiazinone derivative EMD 53998 increased Ca2+ sensitivity and Ca2+ efficacy in both preparations. The drug effect depended on the isoform of troponin (Tn). Using the vanadate method TnI and TnC could be partly extracted and replaced by foreign tropin or by the TnI subunit of added foreign troponins. We investigated the relationship between pCa and force development before and after replacement of TnI with foreign troponin (bovine ventricular troponin, cTn, or rabbit skeletal muscle troponin, sTn) in the presence and absence of EMD 53998. Substitution with bovine cTn increased Ca2+ sensitivity to a value characteristic of bovine ventricular skinned fibres (pCa50 = 5.4) and was further increased by EMD 53998. Substitution with sTn also increased Ca2+ sensitivity, but subsequent addition of EMD 53998 caused little further increase in Ca2+ sensitivity. Following extraction of TnI with vanadate, skinned fibres contracted in a Ca(2+)-independent manner and failed to relax at a pCa of 8. Relaxation could be induced, however, by bovine ventricular TnI and rabbit skeletal muscle recombinant TnI. This relaxation could be reversed by EMD 53998 (100 microM). The Ca(2+)-independent force of contracted fibres could also be depressed by a TnI inhibitory peptide, (cTnI 137-148) and, in addition, this effect was antagonized by EMD 53998.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of troponin-I extraction with vanadate and of the calcium sensitizer EMD 53998 on the rate of force generation in skinned cardiac muscle.

The rate of tension development following release of ATP from caged-ATP in the presence of calcium was studied in skinned cardiac fibres from swine. A low-force rigor state was obtained by using butanedione monoxime (BDM) during the induction of rigor. BDM was washed out and following release of ATP in the presence of Ca2+ (pCa 4.3), the muscles contracted with an apparent rate of about 2 s-1 at 22 degrees C. After treatment with 10 mM vanadate to extract troponins I and C the fibres contracted independently of calcium. The rate of contraction upon release of ATP was slower than prior to extraction and was independent of [Ca2+]. Since treatment with vanadate has been shown to extract about 90% of troponin-I the results suggest that the muscles under these conditions are partially activated by removal of an inhibition of cross-bridge interaction by troponin I. A partial recovery of force was obtained by prolonged incubation in DTT containing solutions possibly reflecting reconstitution with troponin I still present in the fibre bundle. Treatment with a solution containing whole troponin caused almost complete recovery of calcium sensitivity and rate of force development. The calcium sensitizer EMD 53998 increased rates of contraction in a dose dependent manner, suggesting that this compound increases force and calcium sensitivity by increasing the cross-bridge attachment rates.

The calcium sensitizer EMD 53998 antagonizes phosphate-induced increases in energy cost of isometric tension in cardiac skinned fibres.

We have investigated whether a Ca(2+)-sensitizing substance, the thiadiazinone derivative EMD 53998, can alter the ratio of ATPase activity to force, i.e. the tension cost in skinned fibres of swine cardiac trabecula in which the tension cost was increased by inorganic phosphate. In the presence of 10 mM inorganic phosphate (Pi) and thapsigargin 20 microM, EMD 53998 reduced the energy cost of isometric tension over the entire range of activating Ca2+ concentrations, resulting in a consistent change in slope (approximately 20% decrease) of the ATPase/force relation. We confirmed that in the absence of added phosphate and at maximal Ca2+ activation EMD 53998 had little if any effect on tension cost. We had previously reported that the effects of EMD 53998 and Pi on calcium sensitivity and maximum isometric tension are mutually antagonistic and our new energy data now support the proposal that EMD 53998 functionally antagonizes the effects of Pi on crossbridges. The decrease in the slope of the relation between ATPase and force caused by EMD 53998 may be interpreted to reflect either a decrease in the rate of 'detachment' (g(app)) of crossbridges or an increase in average force per crossbridge, as predicted by classical crossbridge models. Since the Pi release step of the crossbridge cycle is associated with the rate of 'attachment' (f(app)) rather than g(app), we conclude that the decrease in tension cost with EMD 53998 most likely reflects an increased force per crossbridge.(ABSTRACT TRUNCATED AT 250 WORDS)

A synthetic peptide mimics troponin I function in the calcium-dependent regulation of muscle contraction.

A new technique for treating skinned cardiac muscle fibers has been developed in which troponin I is extracted, giving rise to unregulated fibers. The effect of the 12-residue troponin I peptide on these fibers indicates that this region of troponin I is solely responsible for muscle relaxation (inhibition of force). Furthermore, troponin I peptide-troponin C reconstituted fibers are stable through several contraction-relaxation cycles indicating the peptide can switch binding sites between actin and troponin C. The troponin I peptide can substitute for the native protein as part of the calcium-sensitive molecular switch that controls muscle regulation.

Effect of myosin heavy chain peptides on contractile activation of skinned cardiac muscle fibres.

Peptides derived from the sequence of the S1 domain of the myosin heavy chain were tested for their effects on the regulation of cardiac contractility. Basal calcium responsiveness of the contractile apparatus in terms of isometric tension generation and ATPase was determined in chemically demembranated ventricular fibre bundles. Incubation with a series of peptides derived from the peptide sequence around SH thiol group (Cys 707) resulted in a measurable increase in isometric tension and ATPase activity at sub-maximal concentrations of calcium but not at saturating levels of calcium activity, thus demonstrating a "calcium-sensitizing" effect of these peptides. The effects of two of these peptides, S1 687-716 and S1 701-717, are demonstrated to mimic, but importantly were not additive with, the calcium sensitization induced by lowering ATP concentration to 10 microM from 10 mM. This suggests the possibility of a similar mechanism of action underlying both types of sensitization. Because these effects demonstrate tissue specificity, were sensitive with respect to potency to not only amino acid composition but also sequence, and could not be duplicated by a similarly charged, non-homologous peptide, we attribute the effects to be specific to the sequences of these peptides. These data provide further evidence that the sequence between residues 687 and 717 of the S1 domain of the myosin heavy chain influences the calcium responsiveness of the contractile apparatus.

The positive inotropic calcium sensitizer EMD 53998 antagonizes phosphate action on cross-bridges in cardiac skinned fibers.

The diazinone derivative EMD 53998 sensitizes skinned myocardial fibers to Ca2+ and enhances maximal calcium-activated force (pCa = 4.5) by approximately 100%; the EC50 is 10 microM in the absence and about 30 microM in the presence of added inorganic phosphate (10 mM). Although concentrations of added phosphate as low as 0.5 mM inhibit force, at high concentrations of EMD 53998 (> or = 50 microM), phosphate only inhibits at concentrations exceeding 20 mM. These data suggest that the effects of EMD 53998 and phosphate are mutually antagonistic. Importantly, both EMD 53998 and phosphate had similar effects on force generation in troponin I-depleted (Ca(2+)-independent) skinned fibers, thus demonstrating that these compounds are likely to affect cross-bridges directly and not via the Ca(2+)-regulatory system.

Troponin replacement in permeabilized cardiac muscle. Reversible extraction of troponin I by incubation with vanadate.

Calcium-dependent regulation of tension and ATPase activity in permeabilized porcine ventricular muscle was lost after incubation with 10 mM vanadate. After transfer from vanadate to a vanadate-free, low-Ca2+ solution (pCa greater than 8), the permeabilized muscle produced 84.8% +/- 20.1% (+/- S.D., n = 98) of the isometric force elicited by high Ca2+ (pCa approximately 4.5) prior to incubation with vanadate. Transfer back to a high Ca2+ solution elicited no additional force (83.2% +/- 18.7% of control force). SDS-PAGE and immunoblot analysis of fibers and solutions demonstrated substantial extraction (greater than 90%) of Troponin I (TnI). Calcium dependence was restored after incubation with solutions containing either whole cardiac troponin or a combination of TnI and troponin C subunits. This reversible extraction of troponin directly demonstrates the role of TnI in the regulation of striated muscle contractility and permits specific substitution of the native TnI with exogenously supplied protein.

Polylysine activates smooth muscle actin-myosin interaction without LC20 phosphorylation.

Phosphorylation/dephosphorylation of the 20-kDa light chain of smooth muscle myosin is a major regulator of actin-myosin interaction. Phosphatase inhibitors have thus been shown to enhance contraction in smooth muscle. The activity of type II phosphatase against phosphorylated myosin light chains is inhibited by polylysine. Thus we studied the effects of polylysine (10-13 kDa) on actin-myosin interaction in permeabilized guinea pig taenia coli fibers and in bovine aortic actomyosin. Addition of polylysine (10-20 microM) to Ca-ethylene glycol-bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid buffered solution ([Ca2+] less than 0.01 microM) elicited a contraction in fibers of 40 +/- 8% (n = 6) of maximally stimulated contractions ([Ca2+] congruent to 1.5 microM). Untreated fibers did not generate any significant force in parallel control experiments. Similarly, polylysine stimulated the ATPase activity both in fibers and actomyosin in a dose-dependent manner. This stimulation could be completely inhibited and abolished upon addition of heparin, a negatively charged heteropolysaccharide. In actomyosin previously phosphorylated with ATP gamma S, polylysine in a concentration range of 2-13 microM did not further stimulate enzyme activity. These increases in activity were not connected with significant changes in the phosphorylation of 20-kDa myosin light chain nor could any incorporation of 32P associated with polylysine stimulation be detected in both skinned fibers and actomyosin by autoradiography of SDS gels. Our data indicate that polylysine increases actin-myosin interaction in both smooth muscle model systems by directly influencing contractile proteins. As such, polylysine may be a useful probe for the mechanism of activation of smooth muscle.

Effects of myosin kinase inhibiting peptide on contractility and LC20 phosphorylation in skinned smooth muscle.

A peptide inhibitor, myosin kinase inhibitor (MKI), of myosin light chain kinase (MLCK) was tested for its effects on contractility and myosin light chain phosphorylation in Triton X-100 skinned guinea pig taenia coli. MKI is based on the amino acid sequence of the myosin light chain (residues 11-19 LC20) and is a competitive inhibitor [inhibitory constant (Ki) congruent to 10 microM] of purified MLCK with respect to myosin light chain (LC20). MKI inhibited unloaded shortening velocity (V(us)) and the calcium-sensitive ATPase activity of the skinned fibers but had no significant effect on steady-state isometric force or myosin light chain phosphorylation, as measured by IEF-polyacrylamide gel electrophoresis analysis. MKI had no significant effect on V(us) of thiophosphorylated fibers in the absence of calcium. MKI inhibited MLCK activity in protein extracts from taenia coli, as measured by radioactive phosphate incorporation into LC20. Surprisingly, MKI also inhibited the phosphatase activity of these same extracts. This peptide slowed the rate and extent of relaxation of calcium-contracted fibers and elicited a contraction in relaxed fibers. These results are consistent with the hypothesis that MKI may be a phosphatase inhibitor as well as an inhibitor of MLCK. Our data further suggest that the rate of phosphorylation-dephosphorylation turnover may be important in regulating V(us) in smooth muscle.

Effects of antibodies to myosin light chain kinase on contractility and myosin phosphorylation in chemically permeabilized smooth muscle.

We have used an immunological approach to investigate the role of myosin light chain phosphorylation (MLC-Pi) in the control of contractility in smooth muscle. Our aim was to specifically inhibit myosin light chain kinase (MLCK) in the presence of physiologically activating levels of Ca2+ so that other putative Ca2(+)-dependent regulatory systems could be unmasked. Fab fragments were prepared by papain digestion of immunoglobulin G (IgG) molecules obtained from goats immunized with turkey gizzard MLCK. Anti-MLCK Fab was then purified by chromatography on an MLCK-Sepharose 4B column. These affinity-purified Fab fragments inhibit the activity of MLCK purified from turkey gizzard smooth muscle and interact monospecifically with MLCK in various mammalian smooth muscles as demonstrated by a Western blot analysis. The effect of these Fab fragments on the contractile properties was tested in guinea pig taenia coli made permeable (skinned) using Triton X-100. Skinned fibers, approximately 100 microns in diameter and 4 mm long, were mounted for isometric measurements and immersed in calcium-EGTA buffers. Fibers preincubated with anti-MLCK Fab in relaxing solution (Ca2+ less than 1 nM) for 75 minutes developed about 25% of the isometric force of a parallel control contraction when transferred to contracting solution (Ca2+ = 0.5 microM). When added to contracting solution at the peak of a contracture, anti-MLCK Fab elicited a relaxation that was complete in about 120 minutes despite the presence of Ca2+. No significant effect on isometric force was observed when fibers were incubated with another affinity-purified mouse Fab raised against the Fc region of human IgG (control Fab).(ABSTRACT TRUNCATED AT 250 WORDS)