The submicrosomal site for the conversion of prothrombin precursor to biologically active prothrombin in rat liver

The submicrosomal site for the conversion of prothrombin precursor to prothrombin in rat lever has been investigated by subcellular fractionation techniques.Prothrombin precursor activity could be detected in the luminal as well as the membrane fraction of the rough microsomes. The corresponding fractions from smooth microsomes did not exhibit any activity. After warfarin treatment of the rats, the concentration of prothrombin precursor in rough microsomes increased rapidly from approx. 2 to 6–8 h, when a plateau was reached. In smooth microsomes, prothrombin precursor activity appeared 1 h after injection of warfarin, and increased to a plateau reached after about 4 h. The total activity of prothrombin precursor at the plateau obtained after warfarin treatment was 4–5 times higher in the rough luminal fraction than in the corresponding smooth fraction.The vitamin K-dependent carboxylase activity was localized to the rough microsomes. The enzyme system was associated with the membrane, mainly at the luminal side, whereas the substrate appeared to be localized in both the luminal and membrane fraction.The results indicate that the conversion of prothrombin precursor to biologically active prothrombin occurs at a late stage in the rough endoplasmic reticulum or at a transition between rough and smooth endoplasmic reticulum.     

Vitamin K-dependent carboxylation of glutamic acid residues to γ-carboxyglutamic acid in lung microsomes

Vitamin K-dependent carboxylation of glutamic acid residues to γ-carboxyglutamic acid was demonstrated in proteins of lung microsomes. The carboxylation was 12% of that in liver microsomes per milligram of mierosomal protein. Carboxylation was very low with microsomes of untreated rats but increased with time up to 42 h after warfarin administration. Carboxylation was highest with microsomes from rats fed a vitamin K-deficient diet. This suggests that a protein(s) accumulates which can be carboxylated in vitro/J. Lung microsomes also catalyzed the vitamin K-dependent carboxylation of the peptide Phe-Leu-Glu-Glu-Leu. The peptide carboxylase activity was 9% of that obtained with liver microsomes. Vitamin K-dependent protein carboxylation required NADH or dithioerythritol, suggesting that vitamin K had to be reduced to the hydroquinone. Accordingly, vitamin K₁ hydroquinone had carboxylating activity without added reducing agents. Menaquinone-3 was considerably more active than phylloquinone. The temperature optimum for carboxylation was around 27 °C.     

The in vivo effects of acenocoumarol, phenprocoumon and warfarin on vitamin K epoxide reductase and vitamin K-dependent carboxylase in various tissues of the rat

In rats the in vivo effects of a chronic low-dose treatment (+/- 60 micrograms/rat per day) with different coumarins (acenocoumarol, phenprocoumon and warfarin) on hepatic and non-hepatic vitamin K-dependent enzyme systems were compared. The plasma concentrations of the three coumarins differed largely but these differences were not reflected in the microsomal coumarin contents. The non-hepatic microsomes contained less than 20% of the coumarins found in liver microsomes. No substantial differences were observed between the following effects of the three anticoagulant treatments. The blood coagulation factor activities were about 10% of normal. The hepatic microsomal vitamin K epoxide reductase activity was diminished to about 35% of control values. The vitamin K epoxide reductase activities present in kidney, lung, spleen, testis and brain microsomes were less influenced by the coumarin treatments; activities ranged between 45 and 65% of normal. In the liver microsomes a 15-fold accumulation of non-carboxylated precursor proteins was found; in the non-hepatic microsomes this effect was less pronounced but still present. The hepatic vitamin K-dependent carboxylase activity was enhanced but the corresponding non-hepatic enzyme activities were slightly or not affected. In addition, the effects of a chronic low-dose warfarin treatment were compared with those after an acute high dose of the drug.     

Calciferol 25-hydroxylase activity in smooth and rough endoplasmic reticulum of rat liver.

Calciferol 25-hydroxylase activity of vitamin D-deficient rats was measured in both liver microsomes and submicrosomal fractions. The smooth and rough-surfaced microsomes were prepared by a density gradient centrifugation technique in the presence of cesium chloride. Purity of the isolated microsomal membranes was ascertained by electron microscopy, RNA determination, measurement of enzyme markers, and by labeling of the cytoplasmic RNA with [5-³H]orotic acid. Calciferol 25-hydroxylase activity was present in both smooth and rough-surfaced microsomes. The specific activity of the enzyme was greater in the rough fraction. There was a linear relation between enzymic activity and the concentration of enzyme for both total and submicrosomal fractions. These data show the presence of calciferol 25-hydroxylase activity in both smooth and rough-surfaced microsomes isolated from livers of vitamin D-deficient rats.     

Propeptide recognition by the vitamin K-dependent carboxylase in early processing of prothrombin and factor X.

Precursors of vitamin K-dependent proteins are synthesized with a propeptide that is believed to target these proteins for gamma-carboxylation by the vitamin K-dependent carboxylase. In this study synthetic propeptides were used to investigate gamma-carboxylation of the prothrombin and factor X precursors in rat liver microsomes. The extent of prothrombin processing by the carboxylase was also investigated. Antisera raised against the human prothrombin and factor X propeptides only recognized precursors with the respective propeptide regions. The data demonstrate structural differences in the propeptide region of the prothrombin and the factor X carboxylase substrates which raises questions about the hypothesis of a common propeptide binding site on the carboxylase for all precursors of vitamin K-dependent proteins. The hypothesis of separate binding sites is supported by data which demonstrate differences in binding of the prothrombin and factor X precursors to membrane fragments from rough and smooth microsomes. gamma-Carboxylation of the prothrombin precursors in vitro was investigated with conformational specific antibodies raised against a portion of the Gla (gamma-carboxyglutamic acid) region extending from residue 15 to 24. The synthetic peptide used as antigen contains three of the ten potential Gla sites in prothrombin. It is shown that these antibodies do not recognize mature prothrombin but recognize the decarboxylated protein. It is also demonstrated that the epitope is Ca2(+)-dependent. The antibodies were used to assess gamma-carboxylation of the prothrombin precursor in membrane fragments from microsomal membranes. The results suggest that microsomal gamma-carboxylation does not involve Glu residues 16, 19 and 20 of the Gla region.     

Identification of vitamin K-dependent carboxylase activity in lung type II cells but not in lung macrophages.

Fluorography of 14C-labelled glutamic acid residues in vitamin K-dependent protein precursors in lung microsomes (microsomal fractions) shows that the lung has several substrates that are not found in the liver. These precursor proteins unique to the lung have apparent molecular masses of 65, 53, 50, 36, 31 and 13 kDa. Type II epithelial cells appear to synthesize most of the vitamin K-dependent proteins in the lung. The 36 and the 31 kDa precursors also found in Type-II-cell microsomes have a similar molecular mass to those of surfactant-associated proteins, and we have previously shown [Rannels, Gallaher, Wallin & Rannels (1987) Proc. Natl. Acad. Sci. U.S.A. 84, 5952-5956] that the 36 kDa protein is one of the precursors for these proteins. Immunoblotting of membrane fragments of Type-II-cell microsomes with plasma prothrombin antibodies identified two prothrombin-like antigens of apparent molecular masses 68 and 65 kDa. This raises the question as to whether Type II cells are also a potential site for synthesis of prothrombin and possibly other vitamin K-dependent clotting factors. Pulmonary macrophages appear to be devoid of vitamin K-dependent carboxylase activity. However, Type II epithelial cells have significant activity, and this activity was unaltered when these cells were maintained in primary culture for 3 days, suggesting that carboxylase activity is expressed in lung alveolar epithelium independently of culture-induced changes in cellular differentiation. Carboxylase activity in Type II cells was enhanced 2-fold when cells were cultured for 24 h in the presence of 50 microM-warfarin. Type II cells, therefore, resemble hepatocytes with regard to their response to coumarin anticoagulant drugs.     

The vitamin K-dependent carboxylation system in human osteosarcoma U2-OS cells. Antidotal effect of vitamin K1 and a novel mechanism for the action of warfarin.

An osteoblast-like human osteosarcoma cell line (U2-OS) has been shown to possess a vitamin K-dependent carboxylation system which is similar to the system in human HepG2 cells and in liver and lung from the rat. In an 'in vitro' system prepared from these cells, vitamin K1 was shown to overcome warfarin inhibition of gamma-carboxylation carried out by the vitamin K-dependent carboxylase. The data suggest that osteoblasts, the cells involved in synthesis of vitamin K-dependent proteins in bone, can use vitamin K1 as an antidote to warfarin poisoning if enough vitamin K1 can accumulate in the tissue. Five precursors of vitamin K-dependent proteins were identified in osteosarcoma and HepG2 cells respectively. In microsomes (microsomal fractions) from the osteosarcoma cells these precursors revealed apparent molecular masses of 85, 78, 56, 35 and 31 kDa. When osteosarcoma cells were cultured in the presence of warfarin, vitamin K-dependent 14C-labelling of the 78 kDa precursor was enhanced. Selective 14C-labelling of one precursor was also demonstrated in microsomes from HepG2 cells and from rat lung after warfarin treatment. In HepG2 cells this precursor was identified as the precursor of (clotting) Factor X. This unique 14C-labelling pattern of precursors of vitamin K-dependent proteins in microsomes from different cells and tissues reflects a new mechanism underlying the action of warfarin.     

Modification of the vitamin K-dependent carboxylase assay

Methods are presented that describe alternative protocols for the isolation of rat liver microsomes containing the vitamin K-dependent carboxylase and the procedure in which the solubilized enzyme is assayed. The method for determining the rate of 14CO2 incorporation into low molecular weight, acid soluble substrates by the rat liver microsomal vitamin K-dependent carboxylase has been modified in order to optimize safety, accuracy and simplicity. For these studies the rat liver microsomes containing the vitamin K-dependent carboxylase were isolated by CaCl2 precipitation. These Triton X-100 solubilized microsomes were found to be equivalent to the microsomes obtained by high speed ultracentrifugation with regard to protein concentration, pentapeptide carboxylase activity, carboxylase activity, preprothrombin concentration and total carboxylatable endogenous protein substrate. This modified assay procedure requires fewer steps and pipetting transfers and is quantitatively equivalent to previously employed protocols. The described technique can be adapted for any assay where 14CO2 or H14CO3- is incorporated into non-volatile products. This newly developed assay procedure was employed to assess conditions necessary for optimal vitamin K-dependent carboxylation of the less expensive substrate, N-t-Boc-L-glutamic acid alpha-benzyl ester. The optimal conditions for the carboxylation of N-t-Boc-L-glutamic acid alpha-benzyl ester by the carboxylase were found to be 10 mM N-t-Boc-L-glutamic acid alpha-benzyl ester, 10 mM MgCl2 at 15-18 degrees C. The rate of N-t-Boc-L-glutamic acid alpha-benzyl ester carboxylation under these optimized conditions was found to be higher (1.5-fold) than the rate of carboxylation of 1 mM Phe-Leu-Glu-Glu-Ile in the presence of the cation activator, MgCl2.     

Vitamin K-dependent gamma-glutamyl carboxylase activity in the chick embryonic chorioallantoic membrane.

During embryonic development of the chick, the onset of calcium transport by the chorioallantoic membrane (CAM) is concomitant with the appearance of a calcium-binding protein (CaBP). The development-specific expression of the CaBP in the CAM is inhibited by vitamin K antagonism in ovo with the anticoagulant, warfarin. However, the CaBP remains immunologically detectable in the CAM of warfarin-treated embryos, suggesting the presence of a precursor form of the CaBP. Previously, we have demonstrated that CaBP expression in CAM organ cultures is inducible by vitamin K. Furthermore, the CaBP contains several residues of the modified amino acid, gamma-carboxyglutamic acid (gamma-CGlu), which has been shown to be formed by vitamin K-dependent carboxylation of glutamic acid in several plasma clotting proteins. This study reports the presence of a post-translational, vitamin K-dependent gamma-glutamyl carboxylase activity in the CAM. Our results show that explants of CAM incorporate H14CO3 in an age-specific and vitamin K-dependent manner. Incorporation of H14CO3 by the CAM is further potentiated by warfarin treatment of the embryos, presumably owing to an elevation of the amount of endogenous uncarboxylated protein precursor(s). Among the subcellular (nuclear, mitochondrial, microsomal, and soluble) fractions of the CAM, only microsomes exhibit specific incorporation of of H14CO3 into gamma-CGlu. The CAM microsomal carboxylation activity is post-translational, vitamin K-dependent, specific for prenylated homologs of vitamin K, sensitive to warfarin, and appears to be unrelated to the activities of biotin-dependent carboxylases or phosphoenolpyruvate carboxykinase. Optimal carboxylation activity occurs after incubation of the microsomes with H14CO3 for 60 min at 37 degrees C in the presence of over 100 microgram of vitamin K1/ml.     

Characteristics of the vitamin K-dependent carboxylating system in human placenta.

Gamma-carboxyglutamic acid, formed during the post-translational vitamin K-dependent carboxylation of glutamic acid residues in polypeptides has been identified not only in coagulation factors II (prothrombin),, VII, IX and X [1--4], but also in several other plasma proteins [3,5,6] and in protein of bone [7,8] and kidney [9]. In rat liver, carboxylation is mediated through an enzyme system located in the microsomal membrane [10]. The enzyme system requires CO2, O2 and the reduced (hydroquinone) form of the vitamin, as well as a suitable substrate [10,11]. Rat liver microsomes also convert vitamin K1 (phylloquinone) to its stable 2,3-epoxide [12]. Several studies suggest a link between carboxylation and the formation of the epoxide [12--14]. In one of these [14], a survey of rat tissues for vitamin K1 epoxidation revealed that, in addition to liver, this activity was also possessed by kidney, bone, spleen and placenta. In preliminary experiments, vitamin K-dependent carboxylating systems have been found in rat and chick kidney [9], in chick bone [15] and in rat spleen and placenta (unpublished observations). In this communication, we describe some of the basic characteristics of the vitamin K-dependent carboxylating system as found in human placental microsomes.     

STUDIES ON THE BIOGENESIS OF SMOOTH ENDOPLASMIC RETICULUM MEMBRANES IN HEPATOCYTES OF PHENOBARBITAL-TREATED RATS : II. The Site of Phospholipid Synthesis in the Initial Phase of Membrane Proliferation

The specific activity of the acyltransferases of smooth microsomes of rat liver rose threefold by 12 h after injection of phenobarbital, while the activity of the acyltransferases of the rough microsomes rose slightly to peak at 3–4 h, and subsequently fell. The latter rise was abolished by treatment of the animal with actinomycin D or puromycin, while that of the smooth microsomes was unaffected. Incorporation of [¹⁴C]glycerol into phospholipid of smooth microsomes was elevated 100% by phenobarbital, while that of the rough microsomes was elevated 15%, and this could be accounted for by exchange between the microsomal phospholipids. The phospholipid/protein ratio of the smooth microsomes rose 1.5 times 3–4 h after injection of phenobarbital, while that of the rough microsomes fell slightly. The specific activity of NADPH cytochrome c reductase and NADPH diaphorase rose first in the rough microsomes, and subsequently in the smooth microsomes at a time coinciding with the return of the phospholipid/protein ratio to the control level. The rise in phospholipid/protein ratio was unaffected by actinomycin D or puromycin. These results indicate that the proliferating smooth membranes are the site of phospholipid synthesis, and that the phospholipid/protein ratio of these membranes may change independently.     

Vitamin K-dependent carboxylase: requirements for carboxylation of soluble peptide and substrate specificity.

Rat liver microsomes contain a triton X-100 solubilizable vitamin K-dependent carboxylase activity that converts specific glutamyl residues of precursor proteins to γ-carboxyglutamyl residues. This activity has been studied utilizing synthetic peptides as substrates for the enzyme. When compared to the carboxylation of the endogenous microsomal precursors, the peptide carboxylase activity is more sensitive to the action of various inhibitors, and requires a higher concentration of vitamin K for maximal activity. The apparent K_m for the peptide Phe-Leu-Glu-Glu-Leu was found to be 4 mM. Substrate specificity depends on residues adjacent to the carboxylated Glu residues and macromolecular recognition sites.     

Vitamin K-dependent carboxylase: Evidence for cofractionation of carboxylase and epoxidase activities,and for carboxylation of a high-molecular-weight microsomal protein

The vitamin K-dependent carboxylase from rat liver microsomes has been fractionated by submitting a crude preparation of this activity to chromatography on different column supports. A constant ratio of vitamin K epoxidation and vitamin K-dependent carboxylation was observed in all column fractions with good carboxylase activity, supporting the hypothesis that these two activities are carried out by the same enzyme complex. The preparation obtained (Complex B) is stable for several days when left on ice and has the same general properties as those observed in Triton X-100-solubilized microsomes. When antiserum raised against Complex B was incubated with Complex B, a twofold increase in carboxylase activity was observed. Benzidine staining showed that an appreciable pool of the antibody population was directed against hemeprotein(s). These data and spectral analyses indicated that a major contaminant of the preparation in cytochrome P-450. Although endogenous prothrombin precursors were absent in the crude starting preparation, a constant ratio of endogenous substrate carboxylation and carboxylation of a soluble substrate was observed during fractionation. A protein with a molecular weight of approximately 120,000 which copurified with Complex B was identified as substrate for the carboxylase.     

Soluble enzyme system for vitamin K-dependent carboxylation.

The vitamin K-dependent carboxylating system has been solubilized by Lubrol PX or Triton X-100 treatment of vitamin K-deficient rat liver microsomes. As obtained from vitamin K-deficient rat liver, this soluble preparation is dependent upon the in vitro addition of vitamin K1 for carboxylating activity. The enzyme system is complex and is dependent upon NADH and dithiothreitol for maximum activity. While detergents used to solubilize the enzyme complex do markedly inhibit the activity of the system, the solubilized system is still highly responsive to vitamin K addition and can be used for further study of the carboxylating enzyme system. The requirement for dithiothreitol and the inhibition by p-hydroxymercuribenzoate indicate the involvement of an --SH enzyme in the carboxylating system.     

Vitamin K dependent carboxylase: subcellular location of the carboxylase and enzymes involved in vitamin K metabolism in rat liver

Vitamin K dependent carboxylation of an exogenous peptide substrate and endogenous protein substrates, vitamin K epoxidation, and reduction of vitamin K epoxide were measured in subcellular fractions from rat liver. The rough microsomal fraction was highly enriched in all four activities; lower levels were found in smooth microsomes. Mitochondria, nuclei, and cytosol had negligible activities. The addition of 0.2% Triton X-100 to intact microsomes resulted in a 10-20-fold stimulation in carboxylation of a peptide substrate. This marked latency suggests that the active site of the carboxylase may be accessible only from the lumen of the microsomal membrane. A lumen-facing orientation of the carboxylase was also supported by its inaccessibility to trypsin in intact microsomes contrasted with marked inhibition by trypsin in detergent-permeabilized microsomes. Vitamin K epoxidase and epoxide reductase activities were also inhibited by trypsin much more effectively in permeabilized than in intact microsomes, although some degree of exposure at the cytosolic surface was also indicated. These data suggest that carboxylation is an early event in prothrombin synthesis occurring primarily on the lumen side of the rough endoplasmic reticulum membrane. The location of the vitamin K epoxidation-reduction cycle enzymes is consistent with their possible role in the carboxylation reaction.     

Evidence for increased formation of preprothrombin and the noninvolvement of vitamin K-dependent reactions in sex-linked hyperprothrombinemia in the rat.

The rate of appearance of plasma prothrombin was measured in vitamin K-deficient male and female rats after the administration of vitamin K₁, and the disappearance of prothrombin was measured in normal rats after injection of cycloheximide. The results suggest that hyperprothrombinemia in female rats is due to a faster rate of formation of the clotting protein rather than to a slower rate of its degradation. Preprothrombin activity in liver microsomes was higher in warfarin-treated female rats than in warfarintreated male rats; but the activity of preprothrombin in liver disappeared at approximately the same rate in both sexes after administration of vitamin K. The rate and extent of vitamin K-dependent formation of γ-carboxyglutamic acid and the appearance of prothrombin activity in vitro were not significantly different between the sexes. These results suggest that elevated levels of plasma prothrombin in female rats are probably due to a higher rate of synthesis of preprothrombin and not to any difference in the vitamin K-dependent step. A difference was observed in the amount of cycloheximide required to inhibit synthesis of liver microsomal protein in the two sexes.     

Cytochemical analysis of the reconstitution of endoplasmic reticulum after microinjection of rat liver microsomes into Xenopus oocytes

Fragments of rough and smooth endoplasmic reticulum purified from rat liver were injected into Xenopus oocyte cytoplasm. Light and electron microscopy, cytochemistry, immunocytochemistry, and enzyme assay were employed to determine the fate of heterologous membranes in the host cytoplasm. The in vivo-incubated microsomes disappeared in a time-dependent manner. Within 3 hr, rough microsomes were replaced by flattened ER cisternae and smooth microsomes were replaced by a network of anastomosing tubules. Polyclonal antibodies against rat liver microsomes and protein A-gold complexes were applied to glycol methacrylate sections of microinjected oocytes. Specific labeling was observed over discrete rough and smooth ER cisternae 3 hr after microinjection. Endogenous ER was not labeled by this technique, and label was not observed when sections were treated with pre-immune antibodies. Diaminobenzidene cytochemistry of microinjected rat lacrimal gland microsomes revealed enzyme activity in heterologous microsomes after 3 hr of in vivo incubation. Control injected microsomes (inactivated by heat denaturation) became associated with autophagic vacuoles, coincident with changes in lysosomal activity. Freshly isolated un-denatured microsomes did not provoke changes in lysosomal activity, and glucose-6-phosphatase activity associated with microinjected membranes could be detected 21 hr after in vivo incubation. Since rat liver microsomes reconstitute after in vivo incubation into cytoplasmic structures resembling those from which they were derived, we conclude that the microinjected membrane fragments act as templates for their own three-dimensional organization.     

Characterization of vitamin K-dependent carboxylase from the livers from the adult ox and dicoumarol-treated calf.

The properties of the microsomal vitamin K-dependent carboxylase from the livers of the adult ox and dicoumarol-treated calf were investigated. The enzymes from both sources utilized glutamic residues of synthetic peptides as substrates and could be solubilized with Triton X-100 similarly to the enzyme from vitamin K-deficient rat liver. Under the optimal assay conditions, the microsomes from calf liver had peptide carboxylase activity comparable with that of the rat liver microsomes and 6.5-fold that of adult ox liver microsomes. The apparent Km for reduced vitamin K and the ionic strength optima of the calf and adult ox enzyme clearly differ from those of the rat enzyme. Pyridoxal phosphate activated the adult ox carboxylase only slightly, whereas the calf enzyme was activated by pyridoxal phosphate as effectively as was the enzyme from the vitamin K-deficient rat. Mn2+ activated the adult ox enzyme 9-fold and calf enzyme 22-fold under optimal conditions (no KCl). Three other divalent metal cations (Ca2+, Ba2+, and Mg2+) activated the adult ox and calf enzymes to about half the extent caused by Mn2+, KCl inhibited this activation. The vitamin K-dependent carboxylase from the dicoumarol-treated calf is apparently more tightly bound to the microsomal membrane than is the adult ox enzyme. In many other respects (pH optimum), temperature optimum, Km values for peptide substrate, substrate specificity, inhibitor effects), the properties of the adult ox and calf enzymes resemble closely those of the rat enzyme.     

Phosphatidylcholine synthesis for incorporation into membranes or for secretion as plasma lipoproteins by Golgi membranes of rat liver

Phosphatidylcholine, the major phospholipid of very low density lipoproteins, is packaged with triglyceride in the Golgi cisternae. CTP-phosphocholine cytidyltransferase and CDP-choline phosphotransferase activities of Golgi subfractions were higher than those of rough or smooth microsomes measured under the same conditions, indicating that phosphatidylcholine synthesis can occur in Golgi membranes. Consistent with this, the specific activity of phosphatidylcholine of Golgi membranes rose more rapidly than that of rough and smooth microsomes after injection of [14C]choline in vivo. The specific activity of the Golgi content phosphatidylcholine (non-membrane fraction) remained low. The S-adenosylmethionine phosphatidylethanolamine methyltransferase activity of Golgi subfractions was also higher than that of rough or smooth microsomes. After injection of [3H]methyl-labeled methionine in vivo, the specific activity of phosphatidylcholine of the Golgi membranes rose in parallel with that of the rough and smooth microsomes. The specific activity of the Golgi content phosphatidylcholine rose above that of the Golgi membranes and exhibited a different pattern, suggesting that this pathway may selectively label phosphatidylcholine which is secreted as lipoproteins. These observations indicate that the Golgi membranes have the enzymes necessary for synthesis of phosphatidylcholine, and incorporation of lipid precursors indicates that synthesis of phosphatidylcholine by Golgi membranes occurs in vivo.     

ATPase activity of the smooth and rough microsomal subfractions of the heart and liver in rabbits with a short-term microcirculatory disorder]

Short-time disturbances of the microcirculation in rabbits had a different influence on the ATP-ase activity of smooth and rough microsomes of the liver and heart. Mg+2ATP-ase activity in the liver decreased in both microsome fractions; as in the heart, the enzyme activity increased only in the smooth (light) microsomes.