Studies on fat digestion, absorption, and transport in the suckling rat. IV. In vivo rates of triacylglycerol secretion by intestine and liver

Dietary caprylic acid and ghrelin O-acyltransferase activity to modulate octanoylated ghrelin functions: What is new in this nutritional field?

Caprylic acid (octanoic acid, C8:0) belongs to the class of medium-chain saturated fatty acids (MCFAs). Dairy products and specific oils such as coconut oil are natural sources of dietary caprylic acid. MCFAs display distinct chemico-physical and metabolic properties from those of long-chain saturated fatty acids (LCFAs ≥ 12 carbons) and potential beneficial physiological effects of dietary C8:0 have been studied for many years. More recently, caprylic acid was shown to octanoylate ghrelin, the only known peptide hormone with an orexigenic effect. Through its covalent binding to the ghrelin peptide, caprylic acid exhibits an emerging and specific role in modulating physiological functions themselves regulated by octanoylated ghrelin. Dietary caprylic acid is therefore now suspected to provide the ghrelin O-acyltransferase (GOAT) enzyme with octanoyl-CoA co-substrates necessary for the acyl modification of ghrelin. Recent studies suggest that decreasing the circulating octanoylated ghrelin level through the inhibition of GOAT activity, or simply by modulating the availability of its C8:0 substrate, might constitute a therapeutic strategy against obesity. Both dietary caprylic acid availability and GOAT activity may indeed be important to modulate octanoylated ghrelin concentration and functions. This review highlights recent findings in the field of nutrition.

Lipid malabsorption persists after weaning in rats whose dams were given GLP-2 and dexamethasone

Glucagon-like peptide-2 (GLP-2) enhances intestinal growth and absorption in mature animals, and glucocorticosteroids (GC) increase the sugar and lipid uptake in adult animals. However, the role of GC and GLP-2 in the ontogeny of lipid absorption is unknown. We hypothesized that GLP-2 and the GC dexamethasone (DEX), when administrated to rat dams during pregnancy and lactation, would enhance lipid uptake in the offspring. Rat dams were treated in the last 10 d of pregnancy and during lactation with GLP-2 [0.1 microg/g/d subcutaneous (sc)], DEX (0.128 microg/g/d sc), GLP-2 + DEX, or a placebo. Sucklings were sacrificed at 19-21 d of age, and weanlings were sacrificed 4 wk later. Lipid uptake was assessed using an in vitro ring uptake method. Although DEX and GLP-2 + DEX increased the jejunal mass, the jejunal lipid uptake was unchanged. In contrast, GLP-2, DEX, and GLP-2 + DEX reduced the ileal lipid uptake in suckling and weanling rats. This reduction was not due to alterations in intestinal morphology or to changes in fatty acid-binding protein abundance, but it was partially explained by an increase in the effective resistance of the intestinal unstirred water layer. In sucklings, DEX dramatically reduced the jejunal lipid uptake to levels similar to those seen in weanlings, such that the normal ontogenic decline in lipid uptake was not observed. Giving dams GLP-2 or DEX during pregnancy and lactation reduced lipid uptake in the offspring, and this persisted for at least 1 mon. The impact this may have on the nutritional well-being of the animal in later life is unknown.

Treatment of suckling rats with GLP-2 plus dexamethasone increases the ileal uptake of fatty acids in later life

Glucocorticosteroids such as dexamethasone (Dex) increase sugar and lipid uptake in adult animals and accelerate the development of the immature intestine. The effect of Dex on the ontogeny of lipid absorption is unknown. In adult rats, glucagon-like peptide-2 (GLP-2) has a trophic effect on the intestine and enhances nutrient absorption. This study was undertaken to determine the effect of GLP-2 and Dex on the intestine uptake of lipids in suckling rats and to determine whether any such effect persists into the postweanling period. Sixty-four suckling rats were randomized into four groups. They were treated from days 11 to 21 with GLP-2 (0.1 microg.g(-1).day(-1) sc), Dex (0.128 microg.g(-1).day(-1) sc), GLP-2 plus Dex (GLP-2 0.1 microg.g(-1).day(-1) sc + Dex 0.128 microg.g(-1).day(-1) sc), or placebo. One-half the pups were killed at days 19-21 ("sucklings"), and one-half were killed 4 wk later ("weanlings"). The rate of intestinal uptake of six fatty acids (12:0, lauric; 16:0, palmitic; 18:0, stearic; 18:1, oleic; 18:2, linoleic; and 18:3, linolenic) and cholesterol was assessed using an in vitro ring technique. GLP-2 had no effect on lipid uptake. Dex increased the uptake of 18:3 in sucklings, and the ileal uptake of 18:0 was increased in weanlings. The combination of GLP-2 plus Dex had no effect in sucklings and increased the ileal uptake of 12:0, 18:0, 18:1, 18:2, and 18:3 in weanlings. The enhanced uptake of fatty acids with GLP-2 plus Dex was not explained by alterations in the animals' body or intestinal weights, intestinal morphology, or intestinal- or liver-fatty acid binding proteins. Unlike adults, GLP-2 does not enhance lipid uptake in sucklings. Dex has a modest enhancing effect on selected fatty acid uptake both in sucklings as well as weanlings. GLP-2 plus Dex has an enhancing effect on the ileal uptake of fatty acids in weanlings 4 wk after their previous injection with GLP-2 plus Dex. It remains to be established what is the nutritional importance of this late effect of prior exposure to Dex or GLP-2 plus Dex on the intestinal uptake of lipids.

Distinct ontogenic patterns of overt and latent DGAT activities of rat liver microsomes

We have studied the ontogeny of the two functional diacylglycerol acyltransferase (DGAT) activities (overt and latent) during postnatal development in rat liver. We find that the ontogenic patterns of the two are highly distinct. Overt DGAT shows a transient rise in activity up to day 4 postnatally, after which it declines until weaning; thereafter, it increases steadily to reach high adult values that may contribute to the high rates of turnover of cytosolic triacylglycerol (TAG). By contrast, latent DGAT activity increases continuously during the suckling period but falls sharply upon weaning onto chow but not onto a high-fat diet. Rates of TAG secretion by hepatocytes are higher than in the adult during the first 7 days after birth, and are largely dependent on the mobilization of the abundant intrahepatocyte TAG as a source of acyl moieties. When the hepatic steatosis is cleared (after day 7) the TAG secretion rate declines by 80% to reach adult values. Quantification of the content of mRNA for the DGAT1 and DGAT2 genes does not show correlation with either of the DGAT activities. We conclude that post-translational modification may play an important role in the overt and latent distribution of DGAT activity in the liver microsomal membrane.

Lymphatic absorption of fatty acids and cholesterol in the neonatal rat

High-fat diets are essential in suckling animals to ensure adequate calories for postnatal growth, but their lymphatic transport of dietary lipids has not been characterized. We established a lymph fistula model in suckling rats to quantify intestinal uptake and lymphatic transport of dietary lipids and analyzed lipoprotein fractions. Suckling 19-day-old Sprague-Dawley rats had their mesenteric lymph ducts cannulated and gastroduodenal tubes inserted. After overnight recovery, [(3)H]triolein and [(14)C]cholesterol were infused for 6 h. Of the total dose, only 38% of triolein and 24% of cholesterol were transported in the lymph of suckling rats. Analyses of residual luminal contents and intestinal mucosal homogenate showed neither reduced absorption nor delayed mucosal processing of ingested lipids to be the cause. Thin-layer chromatographic analysis of radioactive mucosal lipids, however, showed a predominance of free fatty acids (60%) and free cholesterol (67%), implying impaired esterification capacity in these animals. We speculate that this reduced esterification allows for portal transport or direct enterocyte metabolism of dietary lipids.

Use of a nonionic detergent (Triton WR 1339) in healthy cats to assess hepatic secretion of triglyceride

OBJECTIVE

To determine whether a nonionic detergent (Triton WR 1339) can be used in cats to assess hepatic secretion of triglyceride.

ANIMALS

28 healthy cats.

PROCEDURE

Triton WR 1339 was administered IV according to the following schedule: 5, 50, 150, and 250 mg/kg of body weight. Control cats did not receive an injection or received 0.9% NaCl or PBS solutions at the same osmolarity and volume as the 250 mg/kg group. Blood samples were collected throughout the 48-hour period after administration for determination of triglyceride and cholesterol concentrations and for RBC morphology and osmotic fragility studies.

RESULTS

Administration of Triton WR 1339 at 150 and 250 mg/kg caused profound hypertriglyceridemia. Triglyceride concentrations increased in a curvilinear fashion for the first 2 hours and remained increased for approximately 24 hours. Area under the time-concentration curve for triglyceride at 5 hours differed significantly among groups. At 12 and 24 hours, cholesterol was significantly higher in cats receiving 250 mg/kg. The most dramatic changes in osmotic fragility and RBC morphology were in cats receiving 250 mg/kg; 1 of these cats developed severe icterus and died 5 days later. Feeding rice and casein before administering Triton WR 1339 at 150 mg/kg did not appear to affect the hypertriglyceridemia response.

CONCLUSIONS AND CLINICAL RELEVANCE

Triton WR 1339 can be administered IV to cats at a rate of 150 mg/kg to assess hepatic triglyceride secretion, although some cats may have increased RBC osmotic fragility. Higher dosages caused substantial adverse effects, whereas lower dosages did not alter plasma triglyceride concentration.

Members of the caudal family of homeodomain proteins repress transcription from the human apolipoprotein B promoter in intestinal cells

Apolipoprotein B (apoB) is the major protein component of low density lipoproteins, and plays a central role in cholesterol transport and metabolism. The apoB gene is transcribed in the liver and in the intestine in humans. Although much is known about the DNA sequence elements and protein factors that are important for transcription of the human apolipoprotein B gene in the liver, less is known about the mechanisms that control transcription of this gene in the intestine. The sucrose isomaltase gene (SI), is expressed exclusively in the intestine. Two sequences from the promoter region of the SI gene, namely SIF-1 and SIF-3, are essential for promoter activity of the SI gene in intestinal cells. Sequences displaying a high degree of similarity to those of SIF-1 and SIF-3 are present in the third intron of the apoB gene. Rather than stimulating apoB promoter activity, the BSIF-1 and BSIF-3 sequences repressed transcription in CaCo-2 cells. Gel retardation studies demonstrated that BSIF-1, like SIF-1, binds to proteins related to the caudal family of proteins such as mCdx-4 and mCdx-2. These proteins appear to repress transcription from the apoB promoter by a mechanism that involves an interaction with members of the C/EBP family of proteins, that bind to a target sequence for the repressor in the segment from -139 to -111 of the apoB promoter. On the other hand, BSIF-3, like SIF-3, binds to HNF-1 and also represses transcription from the apoB promoter.

Immunochemical methods for quantification of apolipoprotein A-IV

Several methods are available for the immunoassay of apoA-IV levels in plasma, or lipoproteins. The method of choice depends on the question being asked. If sensitivity is not a major determinant, simple immunoelectrophoresis is probably sufficient. To determine apoA-IV levels in plasma or lipoprotein fractions, either radioimmunoassay or a competitive ELISA is indicated. The competitive ELISA described above, however, offers sensitivity as well as rapidity and case of performance. When very low levels of apoA-IV are present (such as those produced by cultured cells), the higher sensitivity of the sandwich ELISA may be required.

Regulation of intestinal apo A-IV mRNA abundance in rat pups during fasting and refeeding

The amount of intestinal apolipoprotein (apo) A-IV mRNA was examined in rat pups during fasting and refeeding. When 14-day old pups were fasted for 15 h, apo A-IV mRNA levels in the whole intestine decreased to 20% of the prefasting level. Refeeding casein and lactose, and the artificial milk composed of Intralipid, casein and lactose, caused an elevation of the apo A-IV mRNA after 3 h, without accompanying an elevation of serum triacylglycerols and apo A-IV (fat-independent elevation of apo A-IV mRNA). Refeeding Intralipid alone simultaneously elevated the apo A-IV mRNA, and serum triacylglycerols and apo A-IV after 3 h (fat-dependent elevation of apo A-IV mRNA). Administration of physiological saline during fasting partly suppressed the reduction of the apo A-IV mRNA (40% of the prefasting level), and the dietary fat-independent elevation of the message disappeared. Refeeding dam's milk to the pups, fasted without water administration, increased the apo A-IV mRNA after 3 and 15 h, although the elevation of serum triacylglycerols and apo A-IV occurred only after 15 h. Refeeding the milk increased the apo A-IV mRNA after 3 h and 15 h. Refeeding dam's milk to the pups fasted with saline administration accelerated the fat-dependent elevation of the apo A-IV mRNA. Simultaneously refeeding Intralipid and Pluronic L-81, an inhibitor of lymphatic fat transport, delayed the elevation of the apo A-IV mRNA and serum triacylglycerols and apo A-IV. Transcription rates of the apo A-IV mRNA, determined by nuclear run/on assay, were similar before and after fasting and refeeding Intralipid. During fasting, administration of puromycin, as compared with actinomycin D, enhanced the disappearance rate of the apo A-IV message. Intestinal mRNA for apo B, but not for apo A-I and beta-actin, similarly changed to the apo A-IV message. Thus, it can be concluded that: (1) dietary fat-dependent and -independent factors are involved in the elevation of the intestinal apo A-IV message; (2) the elevation of the message is not mediated by lipid uptake in the enterocytes but rather stimulated by the events leading to secretion of chylomicrons; and, (3) dietary fat-dependent elevation of the message appears to be due to the stabilization of the message.

Effect of sucrose diet on expression of apolipoprotein genes A-I, C-III and A-IV in rat liver

A sucrose-rich diet stimulates hepatic lipogenesis and induces net production of very low density lipoproteins in the liver. To study changes of hepatic apolipoprotein gene expression in response to such a diet, we measured the mRNA abundance of apolipoproteins A-I, C-III and A-IV in livers of rats fed a sucrose-rich diet or a control diet for 3 weeks. In livers of sucrose-fed rats, the abundance of cellular and nuclear apo A-IV mRNA increased to 185% +/- 21% and 142% +/- 22% of control values (P less than 0.01), respectively. In sucrose-fed rats, the transcriptional activity of the apo A-IV gene, measured in a cell-free transcription system using isolated liver nuclei, increased to 144% +/- 23% of control (P less than 0.05). In contrast, this diet neither affected the abundance of cellular and nuclear apo A-I and apo C-III mRNA nor the transcriptional activity of these genes in liver. These results are consistent with specialization of the regulatory elements of the genes coding for apolipoproteins A-I, C-III and A-IV. Alternatively, enhanced transcription of the apo A-IV gene may preclude increased synthesis of apo A-I and/or apo C-III mRNA due to the close linkage of the three genes in the rat genome.

The ontogeny and site of intestinal lipid and lipoprotein synthesis

The developmental aspects of characteristic intestinal lipoprotein synthesis, chlomicrons (CM), very low density lipoproteins (VLDL) and high density lipoproteins (HDL), are unknown. Our objective was to determine the ontogeny of intestinal lipid and lipoprotein synthesis in both the jejunum and the ileum. Explants of the jejunum and the ileum from fetal (F) (18-19 days of gestation), suckling (S) (5 days old) and weaning (W) (23 days old) rats were cultured in the presence of [14C]-oleic acid to examine lipid synthesis. The results indicate the following. (1) The incorporation of oleic acid is higher for the fetal explants. However, the efficiency of esterification of free fatty acids (FFA) into triglycerides (TG) in the jejunum increases with age (33% F, 37% S, 48% W) (P less than 0.05, by ANOVA). (2) The same profile is found at the ideal site for the incorporation of oleic acid. However, the capacity for the synthesis of TG is more intense at the suckling period (34% F, 54% S, 42% W) (P less than 0.05, by ANOVA). (3) The relative content of TG in CM changes with age: F, 90-93%; S, 80-84%; W, 33-40%. (4) A low percentage of TG content is found in CM at the weaning period while high levels are detectable in VLDL (40-42%). (5) A most significant difference is noted between the jejunum and the ileum in TG synthesis at the suckling period. The ileum synthesizes 53% more TG than the jejunum (P less than 0.025). (6) HDL particles contain substantial amounts of FFA. Nevertheless, they were also found to be able to transport TG mainly in the suckling rat. Thus, this study demonstrates that with growth the rat is able to synthesize CM, VLDL and HDL. Our findings indicate changes in the synthesis of intestinal lipids and lipoproteins, depending on both the development and the site, which suggests an ontogeny. These modifications can be attributed to dietary and hormonal influences present during the period of development.

Developmental changes in the expression of genes involved in cholesterol biosynthesis and lipid transport in human and rat fetal and neonatal livers

Cloned cDNAs encoding a number of enzymes involved in cholesterol biosynthesis as well as extracellular and intracellular lipid transport were used to compare the developmental maturation of these biologic functions in the fetal and neonatal rat and human liver. The results of RNA blot hybridization analyses indicate that steady-state levels of rat HMG-CoA synthase, HMG-CoA reductase and prenyl transferase mRNAs are highest in late fetal life and undergo precipitous (up to 80-fold) co-ordinate reductions immediately after parturition. These changes reflect the ability of the fetal rat liver to produce large quantities of cholesterol as well as the repression of this function during the suckling period in response to exogenous dietary cholesterol. Striking co-ordinate patterns of HMG-CoA synthase, reductase and prenyl-transferase mRNA accumulation were also observed in four extrahepatic rat tissues (brain, lung, intestine and kidney) during the perinatal period. The concentrations of all three mRNAs in the 8-week-old human fetal liver are similar to those observed throughout subsequent intrauterine development with less than 2-fold changes noted between the 8th through 25th weeks of gestation. Analysis of the levels of human apo AI, apo AII, apo B and liver fatty acid binding protein mRNAs during this period and in newborn liver specimens also indicated less than 2-3-fold changes. These observations suggest that the 8-week human liver has achieved a high degree of biochemical differentiation with respect to functions involved in lipid metabolism/transport which may be comparable to that present in 19-21 day fetal rat liver. Further analysis of human and rat fetal liver RNAs using cloned cDNAs should permit construction of a developmental time scale correlating hepatic biochemical differentiation to be constructed between these two mammalian species.

Apolipoprotein-E-gene expression in rat liver during development in relation to insulin and glucagon

An apolipoprotein-E (apo-E) cDNA probe, cloned by immunoscreening of a lambda GT11 rat liver cDNA library, was used to further characterize the expression of the apo-E gene in rat liver during development, in relation to plasma insulin and glucagon levels. The apo-E mRNA level was low in fetus liver, then abruptly increased at birth and rose further during the suckling period. It returned to the level at birth in 10-week-old adults. These variations were paralleled with dramatic changes in plasma glucagon, which rose at birth and remained high during suckling. At the same time, the insulin/glucagon molar ratio fell. Administration of N6,O2-dibutyryl cAMP to 5-day-old rats resulted in a significant induction of liver apo-E mRNA. Moreover, liver apo-E mRNA rose in 10-h-fasted suckling rats as compared to controls, while plasma glucagon increased and the insulin/glucagon ratio decreased. Conversely, glucose feeding of suckling rats did not induce any increase in liver apo-E mRNA, the insulin/glucagon ratio was 10-fold higher than in fasted animals. Our results are consistent with liver apo-E gene expression being under the control of plasma glucagon and of the glucagon/insulin balance.

Changes of apolipoprotein A-IV in the human neonate: evidence for different inductions of apolipoproteins A-IV and A-I in the postpartum period

The levels, isoforms and distribution of apolipoprotein A-IV (apo A-IV) were investigated in 127 term human umbilical cord sera. In addition, apo A-IV levels and isoforms were determined on the 3rd (n = 82) and 6th (n = 68) day following parturition and compared to apo A-I concentrations. Levels of apo A-IV were low in umbilical cord serum (5.7 +/- 1.9 mg/dl) as compared to adult serum (17.6 +/- 4.8 mg/dl). No difference was found between male and female neonates. The serum distribution of apo A-IV closely resembled that seen in the adult human. Apo A-IV concentrations dramatically increased during the first week of life reaching levels of 13.4 +/- 4.1 mg/dl on day 3 and 16.7 +/- 3.4 mg/dl on day 6 post-partum. During this time apo A-I levels did not change significantly (81.0 +/- 16.5 mg/dl in cord serum, 75.3 +/- 10.6 mg/dl and 84.2 +/- 14.5 mg/dl on day 3 and 6, respectively). Cord serum already exhibited the major serum apo A-IV isoforms seen in the adult. Isofocusing of apo A-IV also identified the known genetic polymorphism of apo A-IV. Among 127 cord sera studied we identified 109 homozygote normal patterns, apo A-IV (1-1), 16 heterozygotes, apo A-IV (1-2) and 2 individuals homozygote for the variant peptide, apo A-IV (2-2). We provide evidence that apo A-IV and apo A-I are differently induced in the human neonate during the beginning of the feeding period.(ABSTRACT TRUNCATED AT 250 WORDS)