Interference with the transport of heparin-releasable lipoprotein lipase in the perfused rat heart by colchicine and vinblastine

The lipoprotein lipase of white adipose tissue. Changes in the adipocyte cell-surface content of enzyme in response to extracellular effectors in vitro

An indirect labelled-second-antibody cellular immunoassay for adipocyte surface lipoprotein lipase was used to assess the changes that occurred during the incubation of cells in the presence and absence of effectors. In the absence of any specific effectors, the amount of immunodetectable lipoprotein lipase present at the surface of adipocytes remained constant throughout the 4 h incubation period at 37 degrees C. Under such conditions total cellular enzyme activity also remained constant, with no activity appearing in the medium. In the presence of heparin, cell-surface immunodetectable lipoprotein lipase increased by up to 20%, whereas in the presence of cycloheximide they decreased by up to 60%. Thus the obvious turnover of enzyme from this cell-surface site was found to be relatively rapid and dependent for its replenishment, at least in part, on protein synthesis. In the presence of insulin alone, a substantial increase in cell-surface lipoprotein lipase protein occurred, only part of which was dependent on protein synthesis. The total cellular activity of lipoprotein lipase was unaffected by the presence of insulin. The insulin-dependent increase in cell-surface enzyme was potentiated somewhat in the presence of dexamethasone, which was not shown to exert any independent effect. Glucagon, adrenaline and theophylline all produced a significant decline in the cell-surface immunodetectable lipoprotein lipase, which in the case examined (adrenaline) was partially additive with regard to the independent effect of cycloheximide. Cell-surface immunodetectable lipoprotein lipase amounts were decreased significantly when cells were incubated in the presence of either colchicine or tunicamycin. The concerted way in which cell-surface lipoprotein lipase altered during the incubations of adipocytes in the presence of effectors suggested that the translocation of enzyme to and from this cellular site was dependent on hormonal action and the integrity of intracellular protein-transport mechanisms.

Modulation of lipoprotein lipase in the intact rat by cholera toxin--an irreversible agonist of cyclic AMP

Rats were injected intravenously with cholera toxin, a potent stimulator of adenylate cyclase, and lipoprotein lipase was determined in various organs and plasma. 16 h after cholera toxin injection, lipoprotein lipase activity increased 2-6-fold in heart, diaphragm and lung and decreased to one-third in adipose tissue. An increase in lipoprotein lipase activity was seen in the plasma and in the liver, as determined by antiserum to lipoprotein lipase. The increase in heart lipoprotein lipase was preceded by a rise in cyclic AMP and continued for 24 h when cyclic AMP returned to base-line levels. Both heparin-releasable and residual lipoprotein lipase increased in the heart, but to an unequal extent. The more pronounced rise in residual activity (up to 10-fold) could have contributed to an increase in the t1/2 of heart lipoprotein lipase from 1.5 to 2.6 h. The relatively lower increase in heparin-releasable lipoprotein lipase could have been due to a loss of the enzyme from this compartment into the circulation. The effect of cholera toxin on heart and adipose tissue lipoprotien lipase was observed in fasted, fed and super-fed animals and thus appears to be independent of the nutritional state of the animal. Since cholera toxin not only mimics hormonal stimulation, but causes an exaggerated response to hormones, it made studies on some aspects of regulation of both the functional and storage forms of lipoprotein lipase in the intact organism possible.

Lipoprotein lipase activity of rat cardiac muscle. Changes in the enzyme activity during incubations of isolated cardiac-muscle cells in vitro

1. Isolated cardiac-muscle cells from the hearts of adult rats were shown to retain a high amount of viability during 4 h of incubation when viability was assessed by Trypan Bue stain exclusion and intracellular enzyme leakage. 2. The cells also retained their ability to take up O2 and utilize added substrates over the period of incubation at both 25 and 30 degrees C. 3. When cells from the hearts of fed rats were incubated in a buffered-salts solution at pH 7.4 in the presence of amino acids and heparin, lipoprotein lipase activity in the medium increased progressively. 4. During these incubations the intracellular activity of the enzyme remained constant and the total activity of lipoprotein lipase in the system (cells plus medium) increased by 80% over the 4 h of incubation at 25 degrees C. 5. In the absence of heparin only low amounts of enzyme activity were detectable in the medium and the total lipoprotein lipase activity in the system remained constant. 6. The measurement of lipoprotein lipase activity in either fresh homogenates of the cells or in homogenates of acetone/diethyl ether-dried powders of the cells had no effect on the overall pattern of activity change during the incubations, although as reported previously the total activity detected with acetone/diethyl either-dried preparations was approx. 3-fold higher than with fresh cell homogenates. 7. The observations were compared with published data on lipoprotein lipase activity changes in neonatal heart cell cultures maintained in vitro.

Lipoprotein lipase of cultured mesenchymal rat heart cells. IV. Modulation of enzyme activity by VLDL added to the culture medium

Lipoprotein lipase activity was studied in rat heart cell cultures grown in the presence of 20% fetal calf and horse serum and a medium concentration of triacylglycerol of 0.03 mg/ml. After 6--8 days, when the enzyme activity had reached high levels, the cells were incubated for 24 h in a medium containing 20% serum derived from fasted or fed rats. No change in enzyme activity occurred in the presence of fasted rat serum, but a 50% fall was observed with fed rat serium. When the complete culture medium was supplemented with rat plasma VLDL (0.075--0.75 mg triacylglycerol) a pronounced decrease in lipoprotein lipase activity occurred after 3--5 h of incubation. Similar extent of enzyme fall was observed also in the presence of triacylglycerol-rich lipoproteins isolated from rat plasma after feeding of safflower oil or lard, even though the fatty acid composition of the triacylgylcerol varied markedly. As the addition of VLDL to the culture medium resulted in a lesser fall of heparin releasable than residual activity it seems that there was no direct inhibition of surface bound enzyme activity and that the transport of the enzyme to the cell surface was not affected. These data indicate that addition of VLDL to the culture medium resulted in a fall in enzyme synthesis, while total protein synthesis as determined by incorporation of [3H]leucine, remained unchanged. This inhibition could be reproduced by increasing free fatty acid concentration of the medium, however addition of excess albumin to VLDL-containing medium did not prevent the fall in enzyme activity. The present results obtained with cultured rat hearts cells suggest that in vivo plasma levels of triacylglycerol-rich lipoproteins could modulate the lipoproteins could modulate the lipoprotein lipase activity of the heart.

Lipoprotein lipase of cultured mesenchymal rat heart cells. III. Effect of glucocorticoids and insulin on enzyme formation

Lipoprotein lipase activity was studied in mesenchymal cells isolated from rat hearts and cultured for up to 8 days. The enzyme activity increased markedly between day 3 and 5 while the subsequent increase was less pronounced. Addition of hydrocortisone to complete culture medium resulted in an increase in lipoprotein lipase activity at all stages of culture. Lipoprotein lipase activity did not increase after addition of insulin to the complete culture medium. In the presence of serum-poor medium between day 3 and 6, the increase in lipoprotein lipase activity was much lower than in the presence of complete culture medium. Addition of hydrocortisone and insulin to the serum-poor medium resulted in a significant rise in lipoprotein lipase activity while less consistent effects were obtained after addition of each hormone alone. Transfer of cells to serum-poor medium between day 6 and 7 of culture caused a fall in enzyme activity. Addition of hydrocortisone alone and with insulin restored enzyme activity to control values. No effect on lipoprotein lipase was seen with estradiol, growth hormone, or glucagon when added to serum-containing medium, or serum-poor medium. These results indicate that the lipoprotein lipase of heart is controlled by glucocorticoids and that this control might require the presence of insulin for optimal expression.

Synthesis of lipoprotein lipase in cultured avian granulosa cells

Avian granulosa cells cultured as a homogeneous parenchymal population contain lipolytic activity. This activity is stimulated 2--5-fold by serum, inhibited 90% by 1 M NaCl and inhibited 80% by specific anti-lipoprotein lipase immunoglobulins. 85% of the activity binds to heparin-Sepharose 4B, and 70% of bound activity is eluted with 1.5 M NaCl. Thus, the lipolytic activity of cultured granulosa cells is lipoprotein lipase. Granulosa cells were shown to synthesize lipoprotein lipase in culture by incorporating [3H]leucine into the enzyme protein, as measured with an immunoadsorption technique. Finally, colchicine was shown to increase intracellular lipolytic activity, suggesting an inhibition of secretion of this enzyme by cultured granulosa cells.

Triglyceridase and phospholipase A1 activities of rat-heart lipoprotein lipase. Influence of apolipoproteins C-II and C-III

The influence of purified human apolipoprotein C-II on phospholipase A1 and triglyceridase activities of lipoprotein lipase were compared. Lipoprotein lipase was obtained from rat hearts by perfusion with a medium containing heparin and purified on a heparin Sepharose 4-B column. Using phosphatidyl-ethanolamine-coated triglyceride particles as substrate it was found that the phospholipase A1 and triglyceridase activities of lipoprotein lipase similarly depend on the presence of apolipoprotein C-II. Apolipoprotein C-III cannot replace apolipoprotein C-II. However, addition of apolipoprotein C-III in the presence of C-II affects both lipase activities. While strong inhibition of triglyceridase activity was observed under these conditions, phospholipase A1 activity was slightly stimulated. On the basis of these findings a model was constructed for the role of apolipoprotein C-II in lipoprotein lipase action.

Lipoprotein lipase of cultured mesenchymal rat heart cells. I. Synthesis, secretion and releasability by heparin

Cell suspensions prepared from rat hearts were separated by replating into F1, F2 and M cultures, and cultured for 3--11 days. Lipoprotein lipase activity was highest in the F1 cultures which consisted mainly of non-beating, mesenchymal cells. The enzyme activity was released into the medium only after addition of heparin. The release occurred by an initial rapid phase and a continuous slow phase. Both the rapid and the slow release of enzyme activity by heparin were inhibited by about 70% after a 4 h pretreatment with colchicine. Thus, it seems that the vesicular transport is responsible for the translocation of lipoprotein lipase to the cell surface also during the slow process of release. The residual activity in the colchicine treated cultures was higher than in the controls indicating that no inhibition of enzyme synthesis occurred. The slow phase of enzyme release continued also after removal of heparin from the medium but was reduced markedly when protein synthesis was inhibited by cycloheximide. Thus the increase in total enzyme activity encountered after exposure to heparin resulted from stimulation of new enzyme synthesis. The half-time of lipoprotein lipase in the F1 cultures was 35 min and full restoration of enzyme activity was found 60 min after complete removal of cycloheximide from the system. These data indicate that the culture system can be used to study regulation of new enzyme synthesis and its turnover.

Rat heart in culture as a tool to elucidate the cellular origin of lipoprotein lipase

Lipoprotein lipase was determined in 5-day old cell cultures derived from hearts of newborn rats. With the help of the preplating method the cells were subdivided into cultures containing predominantly cardiac myocytes and into those composed mainly of mesenchymal cells. Lipoprotein lipase activity, associated with the mesenchymal cells was ten times higher than the activity found in the cultures containing mainly the myogenic cells. It is suggested that the mesenchymal cells are the progenitors of lipoprotein lipase in rat heart.

Hepatic secretion and turnover of serum phosphatidylcholine-cholesterol acyltransferase in male and female rats

The activity of serum phosphatidylcholine-cholesterol acyltransferase (LCAT), output of the enzyme by the perfused rat liver, and the effect of pretreatment with colchicine on LCAT were studied in male and female rats. It was observed that: 1. Serum LCAT activity in the female exceeded that of the male in fasted animals, whereas in fed animals, LCAT activity was higher in the male than the female. With both sexes, however, serum LCAT activity in fed animals was greater than that in fasted animals. Data are presented which suggest that the observed sex differences were due to concentration and/or composition of the substrate rather than to differences in the serum concentration of the enzyme. 2. The release of LCAT by perfused livers from fasted female rats exceeded that of the male animals. The output of LCAT was inhibited by pretreatment (male) with colchicine, which suggests that hepatic secretion of LCAT is dependent on vesicular transport. 3. The decay of serum LCAT activity in vivo following injection of colchicine was more rapid in fasted female rats than in male animals. These observations lead us to postulate that the turnover rate of LCAT is higher in female rats than in male animals.

Pre- and post-natal development of lipoprotein lipase and hepatic triglyceride hydrolase activity in rat tissues

The ontogenic development of lipoprotein lipase and liver triglyceride hydrolase was studied in the rat. The enzyme activity measured in extrahepatic tissues fulfilled the criteria of lipoprotein lipase from the onset of measurable activity, i.e. it was inhibited by protamine and 1 M NaCl and showed requirement for serum and heparin for optimal activity. In the liver, measurable amounts of triglyceride hydrolase, active at pH 8.6 were detected 6 days prior to birth. However, till the fourth postnatal day about 50% of this activity was inhibited by NaCl and its sensitivity towards protamine was also higher than that of the enzyme in adult liver. Three patterns of development of enzymic activity were observed in extrahepatic tissues. In the lung, the lipoprotein activity reached the adult values one day prior to birth, while in the kidney only 30% of adult activity were found at birth. A linear increase of enzyme activity was observed in the heart; only 25% of adult activity were detected at birth and 100% were reached only 20 days after birth. The increase in lipoprotein lipase activity in the heart was accompanied by morphological differentiation of cardiocytes and by a progressive development of the capillary bed, which might be related to the pattern of development of enzyme activity in this organ. Adipose tissue lipoprotein lipase activity in inguinal fat fell from values 15 times than adult values between the 4th and 40th postnatal days. The enzyme activity in epididymal fat increased steeply between day 10 and 40, at which time it exceeded the adult values very considerably. These findings indicate that the regulation of the development of lipoprotein lipase activity in extrahepatic tissues is governed by local factors, which can differ even in the same type of tissue, as exemplified by the difference between inguinal and epididymal fat.

Interaction of concanavalin A with membrane-bound and solubilized lipoprotein lipase of rat heart

Concanavalin A was used to study the configuration of lipoprotein lipase at the surface of capillary endothelium. Incubation of heart homogenates with increasing concentrations of concanavalin A for 5-60 min resulted in inhibition of up to 50% of enzyme activity. The inhibition was related to the concentration of lectin and the time of incubation and was fully reversible by postincubation with alpha-methyl-D-mannoside. Rat hearts were perfused for 5-60 min and lipoprotein lipase activity determined in postheparin perfusates and in the perfused heart. When the lectin was introduced into the perfusate a significant reduction of heparin-releasable enzyme was found after 30 min of perfusion. The missing enzyme could be recovered by postperfusion with alpha-methyl-D-mannoside, but not by addition of the sugar to the perfusate withdrawn from the apparatus. These results suggested binding of lectin to the surface-located enzyme and support for such a binding was obtained by the finding of release of labeled lectin into the perfusate by heparin. Perfusion of hearts with concanavalin A for 60 min resulted also in a fall in nonreleasable lipoprotein lipase. The mechanism of this fall is not due to impairment of enzyme synthesis, as leucine incorporation into protein was not reduced. Since neither perfusion nor postincubation with alpha-methyl-D-mannoside restored enzyme activity, the fall was most probably due to irreversible inhibition. It is concluded that mannose residues of lipoprotein lipase in heart homogenates and at the endothelial surface of heart capillaries are available to interact with a specific lectin. Such an interaction renders the enzyme less releasable by heparin during perfusion and causes a significant inhibition of enzyme activity in homogenates.

The inhibition in vivo of lipoprotein lipase (clearing-factor lipase) activity by triton WR-1339

1. Lipoprotein lipase activity was measured in heart homogenates and in heparin-releasable and non-releasable fractions of isolated perfused rat hearts, after the intravenous injection of Triton WR-1339. 2. In homogenates of hearts from starved, rats, lipoprotein lipase activity was significantly inhibited (P less than 0.001) 2h after the injection of Triton. This inhibition was restricted exclusively to the heparin-releasable fraction. Maximum inhibition occurred 30 min after the injection and corresponded to about 60% of the lipoprotein lipase activity that could be released from the heart during 30 s perfusion with heparin. 3. Hearts of Triton-treated starved rats were unable to take up and utilize 14C-labelled chylomicron triacylglycerol fatty acids, even though about 40% of heparin-releasable activity remained in the hearts. 4. It is concluded that Triton selectively inhibits the functional lipoprotein lipase, i.e. the enzyme directly involved in the hydrolysis of circulating plasma triacylglycerols. 5. Lipoprotein lipase activities measured in homogenates of soleus muscle of starved rats and adipose tissue of fed rats were decreased by 25 and 39% respectively after Triton injection. It is concluded that, by analogy with the heart, these Triton-inhibitable activities correspond to the functional lipoprotein lipase.

Colchicine inhibition of the heparin-stimulated release of clearing-factor lipase from isolated fat-cells

When isolated fat-cells are incubated at 25 degrees C in serum-based media containing glucose, insulin and heparin, the rise that occurs in the clearing-factor lipase activity of the incubation medium is inhibited by colchicine. The rise in the fat-cell clearing-factor lipase activity that occurs during similar incubations in the absence of heparin is not affected by colchicine.