Ultrastructural distribution of calcium in smooth muscle cells of guinea-pig taenia coli. A correlated electron microscopic and quantitative study

Some properties of Ca-binding microsomal subfractions isolated from rabbit colon muscle

From a homogenate of rabbit colon smooth muscle a microsomal fraction was isolated, which was divided into subfractions by centrifugation on a discontinuous sucrose gradient. The Ca-binding properties of the subfractions were investigated under different conditions. In the presence of 0.35 mM ATP the Ca binding of the fractions amounted to 4--8 nmol/mg protein. The 35% fraction bound more Ca per mg protein than the 35--45% fraction. The Ca accumulation was comparatively higher both in the presence of 5 mM ATP and in the presence of 5 mM oxalate. The two fractions showed about the same sensitivity for oxalate. This substance stimulated the Ca uptake at 5 mM but not at lower concentrations. The amount and the rate of Ca binding were more dependent on variations in the exogenous ATP concentration in the 35% fraction than was the case for the 35--45% fraction. The Ca binding was completely inhibited by salyrgan when the microsomal fractions were pretreated with this agent. Sodium azide did not influence the Ca-binding capacity of the fractions. It is suggested that the microsomal subfractions of the rabbit colon muscle represent physiologically important parts of the Ca sequestering system of the muscle, since Ca binding takes place at Ca- and ATP-concentrations which are believed to be present in the myoplasm.

A comparative study of the calcium accumulation by mitochondria and microsomes isolated from the smooth muscle of the guinea-pig taenia coli

The calcium uptake by mitochondria and microsomes isolated from the guinea-pig taenia coli was studied at physiological Ca2+ concentrations, buffered by Ca-EGTA mixtures. The Ca accumulation by the mitochondria was measured from the difference between the amount of Ca taken up in the presence and in the absence of a specific mitochondrial inhibitor. The Ca uptake by the microsomes was determined in a solution containing oxalate and a mitochondrial inhibitor. It was calculated from the difference in Ca uptake measured with and without ATP. By using this procedure, the necessity of extensive purification of the isolated fractions was avoided. The (Ca2+) for half-maximal transport in the mitochondria is 7 X 10(-6) M. At (Ca2+) lower than 2 X 10(-7) M, Ca is taken up in an energy-dependent way. In the microsomes the apparent Km for Ca is 7 X 10(-7) m. accumulation is still stimulated by ATP at a (Ca2+) as low as 4 X 10(-8) M. The results show that the rate of Ca uptake by the cell organelles corresponding to the microsomal vesicles is sufficiently fast to explain the speed of relaxation of the taenia coli. The results also suggest that these cell organelles are more important than the mitochondria in regulating the cytoplasmic Ca concentration.

A study of releasable Ca fractions in smooth muscle cells of the rabbit aorta

The distribution of Ca in the cellular compartment of smooth muscle cells of the rabbit aorta has been studied by analyzing the effect of norepinephrine, caffeine, and DNP on 45Ca exchange and on the pattern of tension development. These three substances increase the release of 45Ca from the tissue, but DNP acts more slowly than norepinephrine or caffeine. Also, the effect of norepinephrine and caffeine on tension development occurs almost immediately, while that of DNP appears only after a delay of 5 min. Study of the effect of these substances on the Ca efflux has shown that norepinephrine and caffeine act probably on the same Ca compartment, while DNP seems to act on a different compartment with a slower exchange rate. The difference between these two pools could be further demonstrated by studying Ca release after loading the tissues with tracer in either K-rich solution or in a solution with reduced [Ca]o. The K depolarization results in an excessive loading of the cells with 45Ca. Exposing these cells during the efflux procedure to a solution containing DNP causes a much larger release of 45Ca than that observed after a loading procedure in normal solution. In contrast, the release of 45Ca elicited in such tissues by norepinephrine or caffeine disappears. This disappearance is due to the prolonged increase of the Ca exchangeability induced by K depolarization. During initial exposure to PSS the increased exchangeability causes an accelerated loss of tracer from the tissue compartment on which norepinephrine and caffeine act, while the DNP sensitive compartment is not affected. It is suggested that noradrenaline and caffeine act on the same calcium pool close to the membrane and that DNP acts mainly on the mitochondria.