Weight cycling-induced alteration in fatty acid metabolism

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Weight cycling-induced alteration in fatty acid metabolism

Man-Mei Sea¹, Wing Ping Fong¹, Yu Huang², and Zhen-Yu Chen¹

Departments of ¹ Biochemistry and ² Physiology, The Chinese University of Hong Kong, Shatin, New Territories, Hong Kong

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Epidemiological studies have suggested that repeated weight cycling over time may increase the risk of coronary heart disease.The mechanism involved remains poorly understood, but the changein lipid metabolism during weight cycling has been offered asa possible explanation. The present study investigated the effectof weight cycling on the size and fatty acid composition of ratfat pads as well as serum cholesterol, triglyceride, glucose,insulin, and glucagon in rats. Two consecutive weight cycles wereinduced by 40% energy restriction followed by ad libitum refeedingof either a moderate-fat (MF; 22% energy) or a high-fat (HF; 45%energy) diet. The lipogenic enzymes, including fatty acid synthase,acetyl-CoA carboxylase, malic enzyme, pyruvate kinase, and lipoproteinlipase in the weight-cycled (WC) rats fed only the HF diet, yieldedan overshoot of activities at the end of two weight cycles. Thesechanges were accompanied by an 80% increase in the size of theadipocyte and a 40-50% increase in the size of perirenal and epididymalfat tissues in HF-WC rats. Regardless of whether the rats werefed the HF or MF diet, all WC rats showed a gradual reductionin linoleic and $alpha$ -linolenic acid and an increase in palmitic,palmitoleic, and stearic acid in total body lipid. It is concludedthat weight cycling in rats may promote body fatness if an HFdiet is consumed and can significantly alter whole body fattyacid balance irrespective of whether they consumed an MF or HFdiet. Most importantly, the weight cycling led to an overshootor fluctuation of serum cholesterol, triglyceride, glucose, insulin,and glucagon. If weight cycling is associated with an increasedrisk of cardiovascular disease, then, part of the mechanism mayinvolve the changes in these riskfactors.

weight fluctuation; fasting; refeeding; linoleic acid; $alpha$ -linolenic acid; adipose tissue

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

WEIGHT CYCLING IS PREVALENT when obese people are trying to lose weight. The health effect of weight cycling induced by repeateddieting is controversial. In rats, weight cycling has led to theincreased metabolic efficiency, increased consumption of dietaryfat, heavier fat pads, hyperinsulinemia, and hypertension (10,12). In humans, several epidemiological studies show that anincrease in mortality from all causes and from coronary heartdisease may be associated with weight cycling (17, 29). Incontrast, some studies demonstrate no correlation between weightcycling and heart disease (28, 38).

The underlying mechanisms contributing to the association between weight cycling and coronary heart disease are unknown. Oneof these may be related to the hyperinsulinemia and hypertensioninduced by weight cycling (12, 41). Another possibility isthat repeated weight loss and subsequent regaining of weight maypromote fat deposition and central obesity (11, 42). It isalso possible that weight cycling could change the compositionof tissue lipids and therefore induce an imbalance among saturated,monounsaturated, n-3 and n-6 polyunsaturated fatty acids. It hasbeen known that dietary n-3 fatty acids are inversely relatedto risk in atherosclerosis (24, 36). Several investigationshave also demonstrated that a lower level of linoleic acid (18:2n-6)in human adipose tissue is associated with a higher risk for coronaryheart disease (30, 32, 34, 40). Previous reports showedthat rapid weight loss was associated with accelerated depletionof $alpha$ -linolenic acid [18:3(n-3)] from adipose tissue in humans(21, 27). Weight cycling may not change total body fat massin rodents fed a low-fat diet, but it does modify whole body fattyacid composition. We have previously shown that four weight cyclesinduced by repeated fasting followed by refeeding significantlydecreased both 18:2(n-6) and 18:3(n-3) in carcass and adiposetissue lipids (3, 5, 6). These changes occurred withor without significantly changing final total body weight of theweight-cycled rats compared with ad libitum-fed control animals.We have also used whole body fatty acid balance method to showthat weight cycling significantly increased net whole body oxidationof 18:2(n-6) and 18:3(n-3) in the weight-cycled rats comparedwith ad libitum-fed control animals (2, 4). The presentstudy was carried out to investigate the influence of weigh cyclingon several risk factors of cardiovascular disease, including serumcholesterol and triglyceride. In addition, the changes in twohormones, insulin and glucagon, were also followed during weightcycling.

Several studies (3, 6, 18, 19) that used alternating caloric restriction and refeeding with a low- or moderate-fatdiet were unable to confirm that weight cycling promotes obesity.Furthermore, several studies have shown that weight cycling witha constant low-fat diet did not affect food efficiency, energyexpenditure, and body fat composition (18, 19, 39, 44).In contrast, Uhley and Jen (43) reported that weight cyclingproduced by alternating ad libitum consumption of a high- andlow-fat diet led to an increase in food efficiency. The food efficiencyis, however, consistently increased only during the early periodof weight regain, but a permanent increase has not been foundas a result of the cycle of repeated weight loss and regain. Laueret al. (25) demonstrated that some rats within a strain weremore susceptible than others to develop obesity when given freeaccess to a high-fat diet but that weight cycling did not exacerbatethe obesity produced by high-fat-diet feeding. The present studyexamined the size of perirenal and epididymal fat pads in weight-cycledrats fed a constant high-fat diet compared with that of weight-cycledrats fed a constant moderate-fat diet. We have also sought toascertain whether alternation of lipogenesis might occur duringthe weight cycle. The changes in lipogenesis were monitored bymeasuring the activity of the lipogenic enzymes including fattyacid synthase (FAS), malic enzyme (ME), pyruvate kinase (PK),acetyl-CoA carboxylase (ACC), and lipoprotein lipase(LPL).

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Animals and Diets

One hundred and forty male Sprague-Dawley rats were used in this study. They were housed with two rats per cage in an animalroom at 23°C with 12:12-h light-dark cycles. The rats were randomlydivided into two groups: 75 rats in a high-fat group (HF; 45%energy, Table 1) and 65 rats in a moderate-fat group (MF; 22%energy, Table 1). Before weight cycling, all rats were allowedad libitum access to their corresponding diet for 4 wk. Theirbody weight and food intake were measured daily, and the baselinefood intake was determined. The diet was placed in an open caninserted into a larger open can. The spillage could be recoveredfrom the larger can.

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Table 1. Percentage composition of the high-fat and moderate-fat diets

After the 4-wk stabilizing period, each group of rats was further divided into an ad libitum-fed control group (CTL; 25 ratsin the HF group and 15 rats in the MF group) and a weight-cycledgroup (WC; 50 rats in both HF and MF groups). All the CTL ratswere allowed free access to the diet and water throughout thestudy period, whereas the WC rats were only allowed free accessto water and were subjected to two energy restriction-refeedingcycles.

The WC rats in both the HF and MF groups were subjected to 40% food restriction, and the amount of food given during partialfasting was calculated according to the baseline food intake.In the HF group, two weight cycles were induced by partially fastingthe rats (food intake = 12.5 g · rat¹ · day¹) for a period of 7 days, followed by ad libitum refeeding for10 days. The two weight cycles in the MF group were similarlyinduced, but the amount of food given to the rats was differentduring the energy restriction period (15.5 g · rat¹ · day¹).

The HF-CTL rats were killed at days 0, 7, 17, 24, and 34, whereas MF-CTL rats were killed only at days 0, 17, and 34 (Fig.1). The WC rats from both the HF and MF groups were killed atdays 1, 7 , 8, 12, 17, 18, 24, 25, 29, and 34 (n = 5).

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Fig. 1. Changes in body weight and food intake in control (CTL) and weight-cycled (WC) rats fed either a high-fat (HF; A and B) or a moderate-fat (MF; C and D) diet, respectively. Data are expressed as means ± SD; n = 5 rats. Arrow, time of death.

All the rats were killed under nitrogen-induced anoxia and exsanguinated via the abdominal aorta by using a syringe. The serumwas separated from the whole blood by centrifugation (2,000 gfor 15 min) and stored in aliquots at $-$ 76°C. Liver, epididymal,and perirenal adipose tissue were removed from the abdomen, blotteddry, and then weighed. A portion of epididymal adipose was usedfor adipocyte analysis. Liver and the remaining adipose tissuewere washed with chilled 0.9% saline, freeze clamped in liquidnitrogen, and stored in aliquots at $-$ 76°C for the determinationof fatty acid composition. The carcass [whole body perirenal adiposetissue (2 pads), epididymal adipose tissue (2 pads), liver, blood]was also retained for lipid analysis. This study was approvedby the Animal Care Committee of the Chinese University of HongKong.

Analysis of Adipocytes

The number and size of adipocytes were determined according to Cheung et al. (7) with slight modifications. After removal,the epididymal fat pads were immediately rinsed with saline incubatedat 37°C. After dissecting them free of blood vessels, the fatpads were minced. The minced adipose tissues (1.5 g) were suspendedin 4% BSA-Krebs-Ringer-bicarbonate (KRB; 1 ml/g tissue) containingcollagenase (1 mg/ml, from Clostridium histolytium, Sigma, St.Louis, MO) in 50-ml Falcon tubes. They were then incubated at37°C with continuous shaking (100 rpm) for 60min.

Collagenase treatment was terminated by adding 2 vol of 1% BSA-KRB maintained in a water bath at 37°C. The isolated adipocyteswere collected by filtering the mixture through a layer of cheesecloththat had been immersed in 1% BSA-KRB buffer in advance. The filtratewas allowed to stand for 3 min in a 37°C incubator. After theadipocytes had floated onto the surface, the buffer was removedwith a plastic Pasteur pipette. Adipocytes were resuspended in3 ml of BSA-KRB and swirled gently to disperse the cells. Finally,0.1 ml of adipocyte solution was pipetted onto a hemacytometer.Adipocytes were taken and photographed under a Zeiss microscopeat a magnification of ×50. The number and diameter of isolatedadipocytes were measured on the photographs. To avoid any biasin sampling, four to five photographs were prepared for each adipocytesample. All the cells in a ruled area were counted. Because thereleased adipocytes from 1.5 g of adipose tissue were resuspendedin 3 ml of buffer, and the whole ruled area was 3 × 3 mm witha depth of 0.1 mm, the total volume of ruled area was 9 × 10⁴ ml. Thus

cell concentration (cells/g adipose tissue)

=<FR><NU>cell number in the ruled area</NU><DE>(<IT>9×10−4</IT>)(<IT>1.5/3</IT>)</DE></FR>

The size of the adipocytes was determined by counting the cells distributed around the central horizontal line in photographs.Assuming the adipocytes were spherical, the cell volumes couldbe calculated

cell volume<IT>=</IT>(<IT>&pgr;/6</IT>)(<IT>3&sfgr;2+d2</IT>)<IT>×d</IT>

where d is the mean cell diameter, and $sigma$ ² is the variance in the cell diameter (16).

Fatty Acid Analysis

Total lipids derived from adipose tissue, liver, and carcass were extracted by using chloroform-methanol (2:1, vol/vol). Heptadecanoicacid, triheptadecanoic acid, and L- $alpha$ -phosphatidylcholine diheptadecanoyl(all from Sigma) were added as internal standards to quantifythe free fatty acids (FFA), triglycerides, and phospholipids (PL),respectively. The chloroform-methanol phase containing the lipidextracts was dried under a gentle stream of nitrogen and redissolvedin chloroform, which was then applied to a thin-layer chomatography(TLC) plate (20 × 20 cm, precoated with 250-µm silica gel 60 Å;Macherey-Naged, Duren, Germany) to separate different lipid classes.A solvent system of hexane-diethyl ether-acetic acid (80:20:10,vol/vol/vol) was used for development. The bands containing FFA,triglycerides, and PL were scratched off the plate, and the lipidsextracted were converted to methyl esters by using a mixture of14% BF₃ in methanol and toluene (1:1, vol/vol) under nitrogenat 90°C for 45 min. The fatty acid methyl esters in FFA, triglycerides,PL, and total lipids were analyzed by GLC as described previously(3).

LPL (EC 3.1.1.34)

The activity of LPL was determined as described by Nilsson-Ehle and Schotz (33) with some modifications. First, 10 mCi of[9,10-³H]tri-oleoylglycerol ([³H]TO; 414 mCi/mmol, Amersham) was purified by using a column containing2 g silica acid (Sigma) eluted with petroleum ether followed bydiethyl ether. The labeled TO was mixed with 550 mg of unlabeledTO and 36 mg of lecithin in chloroform followed by evaporationof chloroform. The dried TO mixture was emulsified in 10 ml ofglycerol and then diluted with 4 vol of Tris · HCl buffer (pH8.0, 0.2 M) containing 3% (wt/vol) BSA (Sigma) and 1 vol of coldserum from rats fasted overnight. The TO mixture was then shakenvigorously in a Vortex mixer. Second, the adipose tissue (300mg) was homogenized in 150 µl medium containing Tris · HCl (pH7.4, 67 mM) and the cold serum (1:3, vt/vol). After 3 ml of coldacetone were added, the tissue was rehomogenized and centrifuged(12,000 g for 2 min). The sediment was then homogenized and extractedthree more times (twice with the same volume of cold acetone andonce with cold ether; 12,000 g for 2 min). The powder containingLPL was dried under a stream of nitrogen gas. The extracted powderwas mixed with 1.5 ml of buffer (50 mM Tris · HCl, pH 8.0; 1 Methylene glycol). The supernate (in which all the LPL was dissolved)was saved after centrifugation (40,000 g for 30 min). Third, thereaction (0.2 ml) was initiated by adding 0.1 ml of freshly preparedTO mixture to 0.1 ml of the supernate. The reaction mixture wasthen incubated at 37°C for 30 min. The reaction was stopped byadding 3.25 ml of methanol-chloroform-heptane (1.41:1.25:1) and1.05 ml of 0.1 M potassium carbonate-borate buffer (pH 10.5) followedby vortexing for 15 s and centrifugation (3,000 g for 25 min).Finally, 1 ml of methanol-water phase was counted for radioactivityby using 15 ml scintillation fluid (Triton-X 100-toluene, 1:1,vol/vol) containing 0.4% PPO (wt/vol, Sigma) and 0.04% POPOP (wt/vol,Sigma). A series of controls was also performed without additionof the enzyme solutions. LPL activity (mU) was expressed as theamount of enzyme needed to release 1 nmol of oleic acid/min at37°C.

FAS (EC 2.3.1.85)

The activity of FAS was measured according to the method of Nepokroeff et al. (31). One gram of liver (or 2 g of adiposetissue) was homogenized in 1.5 vol of homogenizing buffer [inmM: 70 KHCO₃, 85 K₂HPO₄, 9 KH₂PO₄, and 1 dithiothreitol (DTT),pH 8.0] by using a Polytron. The homogenate was centrifuged at20,000 g for 10 min. The supernatant was centrifuged again at105,000 g for 60 min. The resulting supernatant obtained was immediatelyused for the enzyme assay, and the activity of FAS was measuredspectrophotometrically by monitoring the rate of NADPH oxidation.All steps up to assay incubation were carried out on ice. Thereaction mixture (500 µmol potassium phosphate buffer, pH 7.0;33 nmol NADPH; 33 nmol acetyl-CoA; 100 nmol malonyl-CoA; 100 nmolNADPH; 1 µmol $beta$ -mercaptoethanol) was preincubated at 30°C for5 min. The reaction was initiated by the addition of 50-100 µgof the enzyme protein (supernatant after centrifugation at 105,000g), which was preincubated in 40 µl of activating buffer (1 Mpotassium phosphate, pH 7.0; 10 mM DTT) at 37°C for 15 min, into960 µl of the preincubated reaction mixture. The oxidation ofNADPH was followed at 340 nm. A correction was made for the rateof NADPH oxidation in the absence of malonyl-CoA as a background.One unit of the enzyme activity represented the amount of enzymeneeded to synthesize 1 nmol of palmitic acid/min (equivalent tothe oxidation of 14 nmol ofNADPH).

ME (EC 1.1.1.40)

ME activity was estimated from the rate of NADPH formation at 25°C (20). One gram of liver was first washed in 0.25 M sucroseand cut into small pieces. It was then homogenized in 3 vol of0.25 M sucrose by using a glass Potter-Elvehjem homogenizer inan ice-water bath. The homogenate was centrifuged at 105,000 gfor 1 h to obtain the supernatant. The reaction was initiatedby mixing 990 µl of assay buffer (400 mM triethanolamine-HCl-30mM L-malate-120 mM MnCl₂ · 4H₂O-3.4 mM NADP⁺, 10:1:2:4, vol/vol/vol/vol, pH 7.4) with 10 µl enzyme (105,000g supernatant). The reduction of NADP⁺ was followed at 340 nm. The background activity was measuredin the absence of L-malate. One unit of enzyme activity was definedas the amount of enzyme needed to reduce 1 nmol of NADP⁺/min at 25°C.

PK (EC 2.7.1.40)

PK activity was measured by the rate of NADH reduction spectrophotometrically as described by Imamura and Tanaka (22). Liver(1 g) was homogenized in 3 vol of homogenization buffer (in mM:20 Tris · Cl, pH 7.5, 100 KCl, 5 MgSO₄, 1 EDTA, 0.2 Fru-1,6-P₂,and 10 $beta$ -mercaptoethanol) by using a Polytron for 1 min in anice-water bath, and the supernatant was obtained by centrifugationat 20,000 g for 1 h. The enzymatic reaction was initiated by adding10 µl supernatant into the assay buffer (50 mM Tris · Cl, pH 7.5,0.1 M KCl, 5 mM MgSO₄, 2 mM phosphoenolpyruvate, 0.5 mM Fru-1,6-P₂,0.18 mM NADH, and 8 U lactate dehydrogenase) that was preincubatedat 37°C. The oxidation of NADH was followed at 340 nm by usinga spectrophotometer. One unit of enzyme activity was defined asthe amount of enzyme catalyzing the formation of 1 µmol of pyruvate/min(or oxidizing 1 µmol of NADH in the coupled system) under theassay conditions. Background was measured by starting the assaywithout phosphoenolpyruvate.

ACC (EC 6.4.1.2)

The method of Inoue and Lowenstein (23) was used to determine the activity of ACC. In brief, 2 g of liver were homogenizedin 2 vol of buffer (0.05 M Tris · Cl, pH 7.5, 20 mM sodium citrate,0.5 mM EDTA, and 5 mM $beta$ -mercaptoethanol) by using a Polytron for10 s in an ice-water bath. It was centrifuged at 2,000 g for 10min, and the residue was homogenized again with 1 ml of the samebuffer by using a glass Potter-Elvehjem homogenizer. The homogenatewas combined with the supernatant from the first centrifugationand recentrifuged at 14,000 g for 45 min. The residue was thenwashed with 1 ml of buffer. The washing was combined with thesupernatant from the second centrifugation and then centrifugedagain at 105,000 g for 45 min to obtain thesupernatant.

Four milliliters of the supernatant were loaded to a Sephadex G-25 column (2.25 × 30 cm, Amersham) equilibrated with 20 mMTris · Cl (pH 7.5) containing 1 mM DTT. Fractions of 1 ml werecollected and those with the highest protein concentration werepooled.

The crude enzyme (supernate) was preactivated by mixing 0.5 ml of the fraction (crude enzyme) with 0.5 ml of activating buffer(in mM: 20 sodium citrate, 20 MgCl₂, 1 DTT, and 50 Tris · Cl,pH 7.5) containing 0.5 mg/ml of BSA (fatty acid poor or free;Sigma) at 37°C for 30 min. The activated enzyme was used for assaywithin 20 min. The assay was initiated by adding 30 µl of theactivated enzyme into 370 µl of assay buffer [in mM: 100 Tris· Cl, pH 7.5, 1 DTT, 0.2 acetyl-CoA, 20 sodium bicarbonate (NaH¹⁴CO₃; 0.25 µCi/µmol, Amersham), 5 ATP, 20 citrate, and 20 MgCl₂as well as 0.5 mg/ml BSA], and the reaction mixture was incubatedat 37°C for 5 min. The reaction was stopped by adding 0.1 ml of4 N HCl, and the unreacted ¹⁴CO₂ was expelled by a gentle stream of air. The residue was thendissolved in 1 ml of H₂O, and its radioactivity was counted. Oneunit of ACC activity was equal to the amount of enzyme neededto form 1 µmol of malonyl-CoA at 37°C/min.

Determination of Serum Insulin and Glucagons

The level of serum insulin and glucagon was determined by using I-125 RIA kits (Amersham and Linco,respectively).

Determination of Serum Cholesterol, Triglycerides, and Glucose

Total serum cholesterol, triglycerides, and glucose were determined by using enzymatic kits(Sigma).

Statistics

Data were expressed as means ± SD. The fatty acid analysis, adipocytes analysis, serum glucose, cholesterol, and triglycerideswere subjected to ANOVA followed by a least significant differencetest for statistical evaluation of the significant differencebetween the CTL and WC rats, and only P < 0.01 was consideredstatistically significant. This was done by running the data onpersonal computer (PC) ANOVA software (PC ANOVA for the IBM PC,version 1.1; IBM, Armonk,NY).

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Body Weight

The changes in body weight of the HF and MF groups over time are shown in Fig. 1. The body weight of all WC rats decreasedgradually during the energy restriction periods of the two weightcycles. At the beginning of refeeding, the body weight of WC ratsincreased significantly, and then increased gradually until theend of the cycle. After the two consecutive weight cycles, thefinal body weight of the WC rats was not significantly differentfrom that of their correspondingcontrols.

The HF-WC rats had a weight reduction of 12.9 and 22.4 g during the fasting periods of cycle 1 and cycle 2, respectively.During the refeeding period, the HF-WC rats had a weight gainof 74.2 and 74.8 g in cycle 1 and cycle 2, respectively (Fig.1). In contrast, the MF-WC rat had a weight reduction of 31.4g in cycle 1 and 20.2 g in cycle 2 during the food restrictionperiod. The refeeding led MF-WC rats to gain 74.9 and 64.4 g incycle 1 and cycle 2, respectively (Fig. 1).

Food Intake

The time course of food intake is graphically illustrated in Fig. 1. The food intake of the controls in HF and MF groups throughoutthe entire experiment was maintained at 20.9 ± 3.4 and 25.3 ±2.8 g · rat¹ · day¹, respectively. The weight reduction of WC rats was achieved bygiving 40% food restriction for 7 days, i.e., 12.5 g · rat¹ · day¹ for the HF group and 15.5 g · rat¹ · day¹ for the MF group. Once the WC rats were allowed free access tothe diet after food restriction, their food intake during thefirst 2 refeeding days was much higher than that of the CTL (Fig.1). Thereafter, their food intake gradually decreased and becamesimilar to that of the CTLrats.

Weight of Adipose Tissue

The weight of epididymal and perirenal adipose fat pads changed similarly during weight cycling in both the HF and MF groups(Fig. 2). Although the weight of the two fat pads of WC rats decreasedand increased concurrently with the change of body weight in thetwo cycles in both groups, the HF-WC rats responded more prominentlyduring the refeeding periods compared with the MF-WC rats. InHF-WC group, the weight of fat pads increased drastically in thefirst several days of refeeding. The HF-WC rats had significantlyhigher final fat pad weights than that of the HF-CTL at the endof the weight cycle. In contrast, the fat pads of MF-WC rats increasedless pronouncedly during refeeding, and their final weight wasslightly lower than that of their MF-CTL.

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Fig. 2. Changes in weight of epididymal and perirenal adipose tissue in CTL and WC rats fed either an HF (A and B) or MF (C and D) diet, respectively. Data are expressed as means ± SD; n = 5 rats. * P < 0.01 between the CTL and WC rats.

Number and Size of Adipocytes

After the two weight cycles, the WC rats from both HF and MF groups had a similar number of adipocytes in epididymal adiposefat pad as their corresponding CTL rats (Fig. 3). In the HF-WCgroup, the number or density of adipocytes was 162.8 ± 39.8 ×10⁴ cells/g adipose tissue whereas that in the HF-CTL was 170.2 ±35.6 × 10⁴ cells/g adipose tissue. In the MF WC group, the number of adipocytesin epididymal adipose tissue pad was 164.6 ± 32.0 × 10⁴ cells/g adipose tissue whereas that in the MF-CTL rats was 169.6± 32.8 × 10⁴ cells/g adipose tissue.

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Fig. 3. Effect of 2 weight cycles on the number (A) and size (B) of adipocytes in control (filled bars) and WC (open bars) rats fed either an HF or MF diet. Data are expressed as means ± SD; n = 5 rats. * P < 0.01 between CTL and WC rats.

The size of adipocytes in epididymal adipose tissue of the HF-WC rats responded differently to weight cycling compared withthe MF-WC and the HF-CTL rats (Fig. 3). In the HF-WC group, thesize of adipocytes was considerably enlarged, being ~80% largerthan that of the HF-CTL (P < 0.01). After two weight cycles, theaverage size of adipocytes of HF-WC rats was 677.5 ± 247.6 × 10³ µm³ whereas that in the HF-CTL rats was 376.2 ± 88.9 × 10³ µm³. In the MF-WC group, the average size of adipocytes was 366.5± 159.4 × 10³ µm³ whereas that in the CTL was 377.3 ± 77.1 × 10³ µm³, and there was no significant difference between MF-WC rats andMF-CTLrats.

Serum Triglycerides, Cholesterol, and Glucose

In the HF-WC group, serum total triglycerides decreased during the food restriction in both weight cycles and then rose toa significantly higher level than that of the HF-CTL rats duringrefeeding (Fig. 4). However, the triglyceride concentration ofthe HF-WC rats was not significantly different from that of theHF-CTL rats at the end of second weight cycle. Moreover, for bothHF-WC rats and HF-CTL rats, their serum triglycerides levels atthe end of the experiment were higher than that at the beginning.In MF-WC group, serum total triglycerides also fluctuated in apattern similar to that in HF-WC group (Fig. 4). The final triglycerideconcentration of MF-WC rats remained the same as that of MF-CTLrats.

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Fig. 4. Changes in the concentrations of serum triglycerides (A and B), cholesterol (C and D), and glucose (E and F) in CTL and WC rats fed either an HF (A, C, E) or MF (B, D, F) diet, respectively. Data are expressed as means ± SD; n = 5 rats. * P < 0.01 between CTL and WC rats.

Similar fluctuation of serum cholesterol level was observed in the HF-WC rats during weight cycling (Fig. 4). There was alsono significant difference between the HF-WC and HF-CTL rats atthe end of cycle 2. Though MF-WC group had a much higher serumcholesterol level than their MF-CTL during the refeeding, therewas no difference between the two groups at the end of the experiment(Fig. 4).

Serum glucose of HF-WC rats fluctuated and differed significantly at several time points from that of HF-CTL rats (Fig. 4).Serum glucose concentration was not different between HF-WC andHF-CTL rats at the end of the experiment. In MF-WC group, serumglucose decreased to a greater extent than that of HF-WC groupduring the food restrictions (Fig. 4). The final serum glucoselevel in MF-WC rats was, however, slightly higher than that ofthe MF-CTL rats at the end of cycle 2 but the difference was notstatisticallysignificant.

Serum Insulin and Glucagon

In both HF and MF groups, there was no significant difference in plasma insulin and glucagon between the WC rats and CTL ratsduring fasting and refeeding (Fig. 5). The levels of serum insulinand glucagon fluctuated during the two weight cycles in WC ratscompared with those in the CTL rats.

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Fig. 5. Changes in the concentrations of serum insulin (A and B) and glucagon (C and D) in CTL and WC rats fed either an HF (A, C) or MF (B, D) diet, respectively. Data are expressed as means ± SD; n = 5 rats. * P < 0.01 between CTL and WC rats.

Carcass Total Lipids

The effects of two weight cycles on carcass total fatty acid composition in HF and MF groups were shown in Figs. 6 and 7.In the HF-WC group, 18:2(n-6) and 18:3(n-3) were gradually decreasedduring the two food restriction periods whereas 14:0, 16:0, 16:1n-7,and 18:0 acids were significantly increased in HF-WC rats comparedwith the HF-CTL rats (Fig. 6). In the MF-WC group, 18:2(n-6) and18:3(n-3) were similarly reduced whereas myristic (14:0), palmitic(16:0), palmitoleic [16:1(n-7)], and stearic (18:0) acids weresignificantly higher compared with the MF-CTL group (Fig. 7).

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Fig. 6. Effect of weight cycling on fatty acid composition of carcass total lipids in CTL (

) and WC ( $black-triangle$ ) rats fed an HF diet. Data are expressed as means ± SD; n = 5 rats. 14:0, Myristic acid; 16:0, palmitic acid; 16:1(n-7), palmitioleic acid; 18:0, stearic acid; 18:2(n-6), linoleic acid; 18:3(n-3), $alpha$ -linolenic acid. * P < 0.01 between CTL and WC rats.

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Fig. 7. Effect of weight cycling on fatty acid composition of carcass total lipids in CTL (

) and WC ( $black-triangle$ ) rats fed an MF diet. Data are expressed as means ± SD; n = 5 rats. * P < 0.01 between CTL and WC rats.

Throughout the two weight cycles, the fatty acid composition of carcass phospholipids was nearly constant in all rats, andthe fatty acid composition in WC rats was not significantly differentfrom the CTL rats regardless of HF or MF diet (data notshown).

Unlike the carcass PL, the fatty acid composition of carcass triglycerides changed in WC rats during the two weight cycles.18:2(n-6) and 18:3(n-3) were gradually decreased in the WC ratsfed both an HF and MF diet compared with CTL rats fed the samediet. During the two refeeding periods of each cycle, the contentof 16:0 and 18:0 of carcass triglycerides was significantly higherthan that in the CTL rats at the end of two cycles. Furthermore,the content of 16:1(n-7) in WC rats fed a MF diet was also increasedafter the two weight cycles (data notshown).

Adipose Tissue Fatty Acids

In HF-WC rats, 18:2(n-6), 18:3(n-3), eicosapentaenoic acid [20:5(n-3)], docosapentaenoic acid [22:5(n-3)], and docosahexaenoicacid [22:6(n-3)], in the two adipose tissues were significantlydecreased during food restriction periods (data not shown). Inthe second food restriction period, 14:0, 16:0, and 18:0 weresignificantly increased in HF-WC rats compared with those in theHF-CTL group. At the end of the first and second cycles, the contentof 18:2(n-6) and 20:5(n-3) was considerably decreased whereas16:0 was significantly increased in the HF-WC rats compared withthat of HF-CTL rats (data notshown).

In the MF-WC group, 18:2(n-6), 18:3(n-3), eicosatrienoic acid [20:3(n-6)], arachidonic acid [20:4(n-6)], docosatraenoic acid[22:4(n-6)], 20:5(n-3), and 22:5(n-3) were significantly lowerthan in MF-CTL rats during food restrictions (data not shown).At the end of the weight cycles, 16:0 was significantly increasedin MF-WC rats, whereas 18:2(n-6) was markedly reduced comparedwith MF-CTL group. At the end of the second cycle, 18:3(n-3) and20:4(n-6) were also reduced in the MF-WC rats compared with thosein MF-CTL group (data notshown).

LPL

The function of LPL catalyzes the conversion of plasma triglycerides to FFA, which enter adipocytes, and are resynthesizedinto triglycerides. There was a general increasing trend for thespecific enzymatic activity for LPL of all the rats in both theHF and MF groups (Figs. 8 and 9). In the HF-WC group, the LPLactivity decreased during the fasting periods of the two cyclescompared with that of HF-CTL rats. During the refeeding, the LPLactivity in HF-WC rats increased rapidly and remained significantlyhigher than that of the HF-CTL rats. At the end of the two WCs,the LPL activity of the HF-WC rats was essentially higher thanthat of the HF-CTL rats (Fig. 8). Similar results were obtainedfor epididymal adipose tissue (data not shown). In MF-WC group,the LPL activity also decreased and then increased simultaneouslywith the body weight during the weight cycles. However, at theend of the two cycles, the LPL activity of the MF-WC rats wasnot significantly different from that of the MF-CTL rats (Fig.9). Similar results were also obtained for both epididymal adiposefat pads (data not shown).

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Fig. 8. Effect of weight cycling on activity of lipoprotein lipase (LPL), fatty acid synthase (FAS), malic enzyme (ME), pyruvate kinase (PK), and acetyl-CoA carboxylase (ACC) in CTL (

) and WC ( $black-triangle$ ) rats fed an HF diet. Data are expressed as means ± SD; n = 5 rats. * P < 0.01 between CTL and WC rats.

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Fig. 9. Effect of weight cycling on activity of LPL, FAS, ME, PK, and ACC in CTL (

) and WC ( $black-triangle$ ) rats fed an MF diet. Data are expressed as means ± SD; n = 5 rats. * P < 0.01 between CTL and WC rats.

FAS

This enzyme catalyzes the addition of acetyl-CoA to the acyl end of a growing long-chain fatty acid in the fatty acid synthesispathway. In the HF-WC group, the FAS activity of epididymal andperirenal adipose tissues decreased considerably during the partialenergy restriction (only data for perirenal adipose tissue shown),but with an overshoot in activities throughout the refeeding periodscompared with that of HF-CTL rats (Fig. 8). The FAS activity ofthe HF-WC rats at the end of the two cycles was also significantlyhigher than that of the HF-CTL rats (Fig. 8). For the hepaticFAS, the specific activity of the HF-CTL rats remained unchangedduring refeeding (Figs. 8 and 9). Although the final hepatic FASactivity of the HF-WC rats was significantly different from thatof the HF-CTL rats, this difference was much smaller comparedwith the difference observed in adipose tissues. In the MF-WCgroup, the FAS activity of two adipose tissues (only data forperirenal adipose tissue shown) and liver showed similar responsesto weight cycling (Fig. 9). During the energy restriction, theFAS activities dropped dramatically during energy restrictionwhile they only rose to a level similar to that of the MF-CTLrats during the refeeding period. Moreover, the final FAS activitiesat the end of the two weight cycles were not significantly differentbetween MF-WC rats and MF-CTL rats. In fact, the former was slightlylower than thelatter.

This enzyme reduces NADP+ to NADPH, which is required as a cofactor for fatty acid synthesis. The activity of hepatic ME ofthe HF-CTL rats remained constant during 35 days of experimentalobservation. The ME activity in HF-WC rats, however, fluctuatedcoincidentally with the body weight loss and regain. It droppedduring energy restriction and rose rapidly during the refeeding.At the end of the two weight cycles, the HF-WC rats had considerablyhigher activity than that in HF-CTL rats (Fig. 8). Furthermore,it was noteworthy that the difference in the activity betweenHF-CTL and HF-WC rats was remarkably larger at the end of thesecond cycle than that of the first cycle. In MF-WC group, theME activity changed parallel to the body weight change. Distinctfrom the HF groups, there was no significant difference in thefinal ME activity between the MF-WC and MF-CTL rats (Fig. 9).

The function of PK is to convert pyruvate to acetyl-CoA, which enters either the citric acid cycle or ME-citric lyase pathwayfor fatty acid synthesis. The hepatic PK activity of the HF-WCrats decreased significantly during fasting and then increasedrapidly during the refeeding periods in both weight cycles. Atthe end of the cycles, the PK activity of the HF-WC rats was slightlyhigher than that of the HF-CTL rats (Fig. 8). In the MF WC group,the PK activity also decreased drastically during fasting, andwith an overshoot in activity throughout the two refeeding periods.There was a significant difference in the final activity betweenthe MF WC rats and the MF-CTL rats, with the MF-WC rats havinga higher PK activity than the MF-CTL rats (Fig. 9).

ACC

This enzyme accelerates the first reaction in fatty acid synthesis, converting acetyl-CoA to malonyl-CoA. The hepatic ACCactivity in HF-WC rats decreased considerably during the energyrestriction in both cycles (Fig. 8). During the refeeding periods,the ACC activity in HF-WC rats rose rapidly and was significantlyhigher than that of the HF-CTL rats. In the MF-WC group, the ACCactivity also dropped when the rats were fasted, but there wasno significant difference between the MF-WC and MF-CTL rats atthe end of experiment (Fig. 9).

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The present study clearly demonstrated that an HF diet and weight cycling were associated with a significant modificationof both fatty acid composition and the size of fat depots in rats.This was in contrast to the report by Lauer et al. (25), whofound that weight cycling did not promote whole body fatness inrats fed an HF diet. This is probably due to the varying susceptibilityof different strains or individual differences within the samestrain to develop obesity by HF feeding (25). The major observationin the present study was that weight cycling caused a substantialincrease in the size of both epididymal and perirenal fat pads(the two most visible fat depots in rats) in HF-WC rats comparedwith HF-CTL after two consecutive weight cycles (Fig. 2). Theincrease in the size of epididymal adipose tissue pads in HF-WCrats was associated with an increase in the size of adipocytesbut not associated with an increase in the number of adipocytes(Fig. 3). We hypothesize that the lipogenesis stimulated by twoconsecutive weight cycles lead to an enlarged size of adiposetissues in the HF-WC rats. To demonstrate this hypothesis, wemeasured all the key enzymes involved in fatty acid synthesisand LPL. The results clearly showed that FAS, ME, PK, ACC, andLPL were suppressed during the energy restriction period but theywere activated to a higher level in HF-WC rats compared with HF-CTLduring the refeeding phase. This higher activity in lipogenesisand LPL was sustained even when the body weight in HF-WC ratshad returned to that of the HF-CTL rats. Thus the lipogenic enzymeswere activated to induce hyperlipogenesis. Triglycerides endogenouslysynthesized or exogenously obtained from diet were then efficientlystored in the adipose tissue by the highly activated LPL. Theresults were consistent with previous reports (8, 9, 13,14, 27), which showed that the lipogenic activity was higherwhen the rats were fasted and then refed. The response of HF-WCrats to weight cycling, however, was different from that of MF-WCrats. First, the increase of lipogenic enzyme activity duringrefeeding was more pronounced in HF-WC rats compared with MF-WCrats. Second, the duration of the overshoot of the enzymatic activitiesduring refeeding was longer in HF-WC rats compared with MF-WCrats. There was no difference in the size of adipose tissue padsbetween MF-WC and MF-CTL rats at the end of two weight cycles.The present study emphasizes the role of dietary fat in weightmaintenance and weight loss. If the data could be extrapolatedto humans, the obesity promoted by weight cycling would be trueonly when a HF diet wasconsumed.

Several longitudinal epidemiological studies have documented an increased risk of cardiovascular disease with weight cycling,but relevant risk factors have not been identified (17, 18,28, 38). To the best of our knowledge, the present study wasthe first to observe that weight cycling was associated with anovershoot of several risk factors including serum cholesteroland triglyceride in WC rats fed either an HF or an MF diet. Interestingly,the weight cycling also induced a fluctuation of serum glucose,insulin, and glucagon. These observations have clinical significancefor several reasons. First, the present study was able to closelymonitor these factors over periods of controlled weight cyclingin rats, whereas most clinical studies failed to observe thesephenomena because the time of sampling vs. the regain of lostweight is not able to be well controlled in human studies (21,28, 29). Second, these factors were only measured at the endof the weight cycles in human studies, when the levels of serumcholesterol, triglyceride, glucose, insulin, and glucagon wereback to the control level. If weight cycling in humans increasessignificantly the risk of cardiovascular disease, then the overshootand fluctuation of these factors should not beoverlooked.

Another major observation in the present study was that weight cycling caused a substantial decrease in 18:2(n-6) and 18:3(n-3)in both HF- and MF-WC rats. At the end of two consecutive weightcycles, 18:2(n-6) and 18:3(n-3) decreased by 43 and 32%, respectively,in the carcass lipid of HF-WC compared with that of the HF-CTLgroup (Fig. 6). Similarly, 18:2(n-6) decreased from 25.5 to 15.3%whereas 18:3(n-3) was reduced from 2.5 to 1.6% in the carcasslipid of MF-WC rats compared with that of the MF-CTL (Fig. 7).In contrast, 14:0, 18:0, 16:0, and 16:1(n-7) were proportionallyincreased in WC rats compared with those in CTL group (Figs. 6and 7). Together with our previous reports (3-5), the presentstudy clearly demonstrated that weight cycling does change thebody fatty acid composition with or without changing the totalbody weight, total body fat, and size of fat pads. The reductionin 18:3(n-3) and 18:2(n-6) occurs regardless of the pattern ofWC caused by either fasting (100% energy restriction) or partialenergy restriction followed by ad libitum refeeding (3-5).

The mechanism by which 18:2(n-6) and 18:3(n-3) were substantially decreased whereas 14:0, 18:0, 16:0, and 16:1(n-7) were increasedduring WC remains poorly understood. It is possible that 18:2(n-6)and 18:3(n-3) were preferentially oxidized during the energy restriction(15, 26), and the lipogenesis of saturated and monounsaturatedfatty acids during the refeeding was stimulated in liver and adiposetissue. This was reflected in the observation that the activityof FAS, ME, PK, ACC, and LPL was elevated during the refeedingphase (Figs. 8 and 9). Thus the repeated overshoot in lipogenesisduring weight cycling may lead to the higher concentrations of14:0, 18:0, 16:0, and 16:1(n-7), all of which can be synthesizedby mammals, and concomitantly, to the lower concentration of thosefatty acids that cannot be synthesized, including 18:2(n-6) and18:3(n-3), in adipose tissue and carcass. It has been reportedthat starved rats have a two- to eight-fold increase in the rateof 16:0 and 16:1(n-7) synthesis during refeeding (1). It shouldalso be pointed out that alteration of the fatty acid profileof carcass total lipids was mainly due to the change in the fattyacid composition of carcass triglycerides. There was no or littlechange in the carcass PL and carcassFFA.

Perspectives

The relevance of weight cycling in normal-weight rats fed an MF or HF diet as a model for risks associated with weight cyclingin humans is unclear (17, 21, 28, 29). The present studyclearly demonstrated that two weight cycles remodeled the wholebody fatty acid composition. This change was specific and irrespectiveof the level of dietary fat. This weight cycling-induced alterationmarkedly lowered the ratio of polyunsaturated to saturated fattyacids in tissue (3, 4, 6). The present study emphasizesthat weight cycling may promote body fatness if an HF diet wasgiven. Most important was that weight cycling repeatedly led toan overshoot or fluctuation of lipogenic enzymes, serum cholesterol,triglycerides, glucose, insulin, and glucagon. If weight cyclingincreases cardiovascular risk, part of the mechanisms may be associatedwith the disturbance of whole body fatty acid balance, overshootof risk factors including serum cholesterol and triglyceride,and changes in metabolic and hormonalprofile.

	ACKNOWLEDGEMENTS

We thank Dr. Anthony James of the Laboratory Animal Services Centre, The Chinese University of Hong Kong, for helping to editthismanuscript.

	FOOTNOTES

This research was supported by a direct grant from the Biological Science Panel, The Chinese University of HongKong.

Address for reprint requests and other correspondence: Z.-Y. Chen, Dept. of Biochemistry, The Chinese Univ. of Hong Kong,Shatin, New Territories, Hong Kong (E-mail: zhenyuchen{at}cuhk.edu.hk).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.§1734 solely to indicate thisfact.

Received 14 September 1999; accepted in final form 25 April 2000.

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