Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.1.34 (lipoprotein lipase)
 7,025 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Effects of prolactin (PRL) on lipid metabolism were examined in the patients with hyperprolactinemia and rabbits. Significant correlation between serum PRL and triglyceride (TG) levels was observed in the patients with hyperprolactinemia (r = 0.417, p less than 0.05). Serum TG levels in non-pregnant adult rabbits were elevated in feeded states by the administration of o-PRL. Marked changes were not observed in the activity of plasma lipoprotein lipase in rabbits by the administration of o-PRL, but in in vitro experiments, the up-take of 14C-acetate into lipid fraction of rabbit liver slice significantly increased by the addition of o-PRL. These findings suggest that PRL activates TG synthesis in liver and consequently increases serum TG levels. The serum levels of TG, free fatty acid, cholesterol and glucose significantly rose in rabbits' fetuses after the administration of o-PRL intraperitoneally. These facts also suggest that the high levels of PRL in maternal and fetal serum and amniotic fluid may have some roles in the growth of the fetus through lipid metabolism.
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PMID:[Effects of prolactin on lipid metabolism (author's transl)]. 708 39

The effect of tri-iodothyronine (T3) administration on the utilization of dietary [14C]lipid by the mammary gland and adipose tissue of lactating and litter-removed rats was studied. (1) After an oral load of [1-14C]triolein, the lactating rats treated with T3 (50 micrograms/100 g body wt.) over 24 h showed an increase in 14CO2 production and a decrease in the total [14C]lipid transferred through the mammary gland that was paralleled by a decrease in tissue lipoprotein lipase (LPL) activity. (2) T3 administration decreased plasma prolactin in the lactating rats. Prolactin replacement in T3-treated rats restored LPL activity in the mammary gland, but did not increase the amount of dietary [14C]lipid transferred to the milk. (3) Chronic T3 administration (4 days) to lactating rats did not affect pup growth or the lipogenic rate in the mammary gland. (4) The administration of T3 to litter-removed rats inhibited the increase of LPL activity in white adipose tissue and decreased the accumulation of dietary [14C]lipid. This decrease was accompanied by increased 14CO2 production and [14C]lipid accumulation in skeletal muscle and heart. (5) It is concluded that hyperthyroidism depresses LPL activity in mammary gland and white adipose tissue, but not in muscle. The increased accumulation of [14C]lipid in muscle and increased production of 14CO2 in lactating and in litter-removed rats treated with T3 is in part due to the decreased total LPL in mammary gland and adipose tissue respectively, which are therefore less able to compete with muscle for the available plasma triacylglycerols.
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PMID:Effects of tri-iodothyronine administration on the disposal of oral [1-14C]triolein, lipoprotein lipase activity and lipogenesis in the rat during lactation and on removal of the litter. 804 94

The effects of insulin deficiency (streptozotocin-induced) or insulin plus prolactin deficiency on the disposal of orally administered [1-14C]triolein between oxidation to 14CO2, uptake by mammary gland and transfer to suckling pups were studied. Insulin deficiency decreased mammary-gland total weight (by 40%), but caused no change in total tissue DNA. A greater proportion of the [1-14C]triolein was oxidized to 14CO2 (120% increase) in the insulin-deficient rats, and there was a tendency for total transfer of [14C]lipid to mammary gland and suckling pups to be decreased. A parallel decrease in total mammary-tissue lipoprotein lipase activity occurred. Combined hormone deficiency caused more dramatic changes in all parameters measured. Replacement of insulin (24 h) in insulin-deficient rats decreased 14CO2 production, increased the uptake of [14C]lipid into the mammary gland and tended to increase total lipoprotein lipase activity. In contrast, administration of prolactin to insulin-deficient rats had no effect on any of the parameters measured. Replacement of insulin (24 h) in the combined hormone-deficient rats increased uptake of [14C]lipid and lipoprotein lipase approx. 3-fold, whereas prolactin again had no significant effects. Replacement of both hormones increased (6-fold) transfer of [14C]lipid to the pups, but did not increase overall uptake of [14C]lipid (mammary gland, milk clot and pups) above the value for insulin alone. It is concluded that insulin is the primary regulator of triacylglycerol uptake and of lipoprotein lipase activity in the lactating mammary gland of the rat and that the action of prolactin on these processes is indirect. Prolactin, but not insulin, appears to have a direct effect on milk lipid transfer to pups.
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PMID:Regulation of rat mammary-gland uptake of orally administered [1-14C]triolein by insulin and prolactin: evidence for bihormonal control of lipoprotein lipase activity. 819 43

The effects of exogenous insulin or vanadate (an insulin mimetic) on the disposal of dietary [14C]lipid between oxidation to 14CO2, deposition in adipose tissue or uptake by mammary gland and transfer to suckling pups were studied in virgin and lactating rats. After an oral load of [1-14C]triolein, virgin rats treated with a supraphysiological dose of insulin over 24 h showed a decrease (58%) in 14CO2 production and increased accumulation of [14C]lipid in carcass and white adipose tissue. There was a 2.5-fold increase in lipoprotein lipase activity in the latter. Chronic vanadate administration (12 days) had no effect on these parameters. In lactating rats, the stimulation of the deposition of [14C]lipid in adipose tissue by exogenous insulin was about 10% of that in virgin rats. In prolactin-deficient lactating rats there was no stimulation of [14C]lipid deposition in adipose tissue by insulin. However, both insulin and vanadate treatment increased the accumulation of [14C]lipid in mammary gland to the values seen in the mammary glands plus pups of normal lactating rats. Lipoprotein lipase activity in the gland was also restored to normal values. It is concluded that in lactation there is resistance to insulin stimulation of dietary lipid deposition in adipose tissue, and that this is not due to circulating prolactin. In addition, exogenous insulin plays a role in the regulation of lipoprotein lipase and hence of dietary lipid uptake into lactating mammary gland.
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PMID:Effects of exogenous insulin or vanadate on disposal of dietary triacylglycerols between mammary gland and adipose tissue in the lactating rat: insulin resistance in white adipose tissue. 845 46

Some arachidonic acid metabolites might be among the intracellular signalling substances that regulate hormone release. We report that the phospholipase A2 and diacylglycerol lipase inhibitor quinacrine (1-10 mumol l-1) inhibited the thyroliberin stimulated prolactin (rPRL) production in a dose-dependent way in a rat pituitary tumour cell line (GH4Cl cells). The lipoxygenase inhibitor nafazatrom (5-50 mumol-1) also dose-dependently inhibited the thyroliberin stimulated rPRL production, while the cyclo-oxygenase inhibitor indomethacin had no such effect on rPRL production. The inhibitors of the arachidonic acid metabolism (quinacrine, ETYA and nafazatrom) had no effect on the accumulation of inositolpolyphosphates indicating that the arachidonic acid metabolites are not involved in the regulation of the phospholipase C activity.
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PMID:Inhibitors of the arachidonic acid metabolism attenuate the thyroliberin (TRH) stimulated prolactin production without modifying the production of inositolphosphates in GH4C1 pituitary cells. 846 10

To determine the role of the hormone prolactin and its receptor on the differentiation, growth, and metabolic activity of cells of bone marrow origin, prolactin receptor expression was assessed in bone marrow stromal cells. Using reverse transcription - polymerase chain reaction, BMS2 cells, a bone marrow stromal cell line, were shown to express prolactin receptors following adipocyte differentiation, using three different adipocyte-differentiation protocols. Primary bone marrow stromal cells also show a dose-dependent increase in prolactin receptor expression following treatment with adipogenic agonists. That prolactin receptor expression is inducible upon adipocyte differentiation was confirmed using a preadipocyte cell line 3T3 - L1. Further, prolactin receptor parallels lipoprotein lipase gene expression in 3T3-L1 cells. These results suggest that prolactin and its receptor may play a role in differentiation and/or metabolism of pre-adipocytes and adipocytes.
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PMID:Prolactin receptor expression during adipocyte differentiation of bone marrow stroma. 894 Apr 6

To understand the mechanism responsible for maternal hyperlipidemia, 25 healthy pregnant women were studied longitudinally during the three trimesters of gestation and at post-partum, and 11 were studied again at post-lactation. Triglyceride and cholesterol levels increased with gestation in all the lipoprotein fractions. However, the greatest change appeared in low density (LDL) and high density (HDL) lipoproteins, both of which showed an increase in their triglyceride/cholesterol ratio. The proportional distribution of HDL subfractions showed that the HDL2b fraction was the only one that increased with gestation, whereas both HDL3a and HDL3b had the greatest decrease. Cholesteryl ester transfer protein activity increased during the second trimester of gestation. While postheparin lipoprotein lipase activity decreased during the third trimester, postheparin hepatic lipase activity progressively decreased from the first trimester. The 17 beta-estradiol, progesterone, and prolactin hormones progressively increased from the first trimester of gestation. The lipoprotein-triglyceride values correlated linearly and negatively with the logarithm of either postheparin lipase activities, HDL-triglycerides showing the highest correlation coefficient when plotted against the hepatic lipase values (r = -0.757). It appeared that the highest correlation between any of the HDL subclasses and the activity of the enzymes was for hepatic lipase activity versus HDL2b (r = 0.456) or HDL3a (r = 0.519). A significant lineal correlation also appeared between the postheparin hepatic lipase activity and the logarithm of any of the sex hormones studied, the highest value corresponding to estradiol (r = -0.783). Therefore, during gestation, the effect of estrogen in enhancing very low density lipoprotein (VLDL) production and decreasing hepatic lipase activity plays a key role in the accumulation of triglycerides in lipoproteins of density higher than VLDL.
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PMID:Longitudinal study on lipoprotein profile, high density lipoprotein subclass, and postheparin lipases during gestation in women. 902 28

The in vitro effects of prolactin (PRL) on lipoprotein lipase (LPL) activity and on LPL mRNA levels were studied in cultured mammary tissues derived from mid-pregnant mice. Mouse mammary gland tissues were initially incubated for 24 hr in M199 media containing 1 microg/ml insulin and 10(-7) M cortisol. A subsequent treatment of the tissues with 1 microg/ml PRL caused a 76% increase in heparin-releasable LPL (hrLPL) activity after 24 hr. A significant increase in LPL activity was detected 16 hr after PRL addition, but not at earlier times. PRL at 100 ng/ml elicited a maximum stimulation of LPL activity. When Northern hybridization techniques were employed, PRL was also found to increase the tissue content of LPL mRNA; this effect was initially detected after a 6-hr PRL treatment employing PRL concentrations of 50 ng/ml and above. Specificity studies revealed that only lactogenic hormones stimulated LPL activity and LPL mRNA accumulation in cultured mammary tissues. PRL also expressed a small (25% increase), but significant, effect on ATP citrate-lyase activity in mammary tissues cultured for more than 6 hr with the hormone.
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PMID:Prolactin's effects on lipoprotein lipase (LPL) activity and on LPL mRNA levels in cultured mouse mammary gland explants. 903 34

During lactation serum levels of prolactin (PRL) are elevated, and the activity of lipoprotein lipase (LPL) is decreased in the adipose tissue and increased in the mammary gland. However, PRL has been suggested to affect the adipose tissue in an indirect fashion during lactation. In the present study, we demonstrated expression of four PRL receptor (PRLR) mRNA isoforms (L, I, S1(a), and S1(b)) in human sc abdominal adipose tissue and breast adipose tissue using RT-PCR/Southern blot analysis. In addition, L-PRLR [relative molecular mass (M(r)) 90,000] and I-PRLR (M(r) 50,000) protein expression was detected in human sc abdominal adipose tissue and breast adipose tissue using immunoblot analysis. Two additional protein bands with the molecular weight M(r) 40-35,000 were also detected. The direct effect of PRL on the regulation of LPL activity in human abdominal adipose tissue cultured in vitro was investigated. PRL (500 ng/ml) reduced the LPL activity in human adipose tissue to 31 +/- 7.7%, compared with control. GH (100 ng/ml) also reduced the LPL activity, to 45 +/- 8.6%, compared with control. In agreement with previous studies, cortisol increased the LPL activity and GH inhibited cortisol-induced LPL activity. Furthermore, we found that PRL also inhibited the cortisol-induced LPL activity. Taken together, these results demonstrate a direct effect of PRL, via functional PRLRs, in reducing the LPL activity in human adipose tissue, and these results suggest that LPL might also be regulated in this fashion during lactation.
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PMID:Identification of functional prolactin (PRL) receptor gene expression: PRL inhibits lipoprotein lipase activity in human white adipose tissue. 1267 77

GH and PRL are both implicated in adipose tissue development. Whilst direct effects of GH have been clearly demonstrated, direct effects of PRL have been subject to considerable debate. Recent studies have however provided compelling evidence for PRL receptors on adipocytes and in vitro effects on leptin and lipoprotein lipase activity have been demonstrated. Quantitatively however these effects of PRL are less significant than those of GH and the most pronounced effects of PRL on adipose tissue are indirect, for example, during lactation, when prolactin drives milk synthesis which results in a homeorhetic shift towards lipid mobilization from adipose tissue to support milk production. GH also exhibits such homeorhetic effects, most notably in ruminants, but also clearly has direct, insulin-antagonistic, metabolic effects. The roles of GH and PRL on adipocyte proliferation and differentiation have also been controversial, with GH stimulating adipocyte differentiation in vitro in cell lines whilst stimulating proliferation and inhibiting differentiation of primary cell cultures. Examination of adipose tissue development in PRLRko and GHRko mice has revealed roles for both hormones. PRLRko mice show impaired development of both internal and subcutaneous adipose tissue due to decreased numbers of adipocytes. In contrast, GHRko mice exhibit major decreases in the number of internal (parametrial) adipocytes whereas subcutaneous adipocytes develop almost normally. This leads to major changes in the sites of adipose tissue accretion and bears interesting parallels with the adipose tissue redistribution which occurs in HIV-induced lipodystrophy. Such individuals exhibit a central obesity which can be partially corrected by GH treatment. However, recent studies suggest that this may be a physiological response in which adipose tissue sites containing lymphoid tissue (such as mesenteric) show preservation of adipose tissue perhaps to support augmented immune responses.
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PMID:Effects of growth hormone and prolactin on adipose tissue development and function. 1470 19


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