The Comparison of the Effect of Oat and Shiitake Mushroom Powder to Prevent Body Weight Gain in Rats Fed High Fat Diet ()
1. Introduction
In recent years, the prevalence of obesity has been widely reported to induce metabolic syndrome, cardiovascular disease, diabetes mellitus and cancer [1-3]. It has been reported that lowering plasma triacylglycerol (TAG) levels will be efficient in combating body weight gain as an increased plasma TAG level was significantly correlated with increase in body mass index and fat pad masses on rats [4]. Beta-glucan is well documented as lowering plasma lipids in human [5-8] and animal [9,10] studies.
Oats and mushrooms have been found to be good sources of beta-glucan. An enrichment diet of oats in a clinical study was not reported to lower plasma TAG levels [11-14] but lowered total plasma cholesterol (TC) [11,13]. Limited human studies such as [15] have shown the prevention of increased TAG plasma levels using a mushroom enriched diet.
One of the mechanisms of oat beta-glucan in lowering plasma lipid is its capacity to increase food viscosity [9, 10,16]. By increasing viscosity of food in the lumen, beta-glucan was reported to prevent and delay the absorption of nutrients. However, the viscosity of beta-glucan is dependent on the molecular weight, molecular structure, and food matrix [7,10,17].
While in nearly all of the reported research beta-glucan was found to be the main component from oats with the potential to lower plasma lipid, in contrast, in research using the shiitake mushroom, not only was beta-glucan reported to lower lipid, but other nutrient content such as eritadenine also lowered plasma lipids [18-20]. Another difference between oats and shiitake mushrooms is the molecular structure of their beta-glucan [21].
Thus it will be predicted from compositional data that, when comparable amounts of beta-glucan are consumed, shiitake mushrooms will lower plasma lipid more effectively than oats. These predictions are supported by the findings of an extraction of each component of shiitake mushrooms; for instance, polysaccharide, and eritadenine lower plasma TAG by 15% [22], and 39% [23] respectively. Also reported exoskeleton mushroom contains chitin-chitosan lower plasma TAG lipid by 32% [24].
To the best of our knowledge, no data are available to examine the comparative effect of oats and shiitake mushrooms in preventing body weight gain in a similar designed study. Such a study would use equivalent dosages of beta-glucan for both the oat and mushroom powder, and in addition, the same background high fat diet (HFD) would be given and the same type of food matrix used to administer the oats and mushrooms.
The aims of this research were to 1) compare the effect of oats and mushrooms powder to prevent body weight gain, 2) to determine the effective dose of oat and mushroom powder necessary to prevent body weight gain and 3) to determine the potential underlying mechanisms to preventing body weight gain.
2. Material and Methods
2.1. Animals and Diet
Seventy male Wistar rats at 9 weeks of age were purchased from the Animal Resource Centre (ARC)-Perth, Western Australia. All experimental procedures were approved by the Animal Ethics Committee of the University of Wollongong, AE 09/01. The animals were housed two rats per cage in environmentally controlled conditions (temperature 22˚C, light cycle from 06:00 to 18:00 hours and dark cycle from 18:00 to 06:00 hours) and had ad libitum access to food and water. Rats were fed a commercial chow (rat and mouse YS Feed, Young, NSW) in order to acclimatise to the new facility and environment. The seventy rats were divided into seven groups (n = 10) and fed ~50% HFD with additional nil, low, medium and high doses of oat powder and Shiitake mushroom powder 1) HFD, 2) low dose oat (LD-O), 3) medium dose oat (MD-O) and 4) high dose oat (HD-O), 5) low dose Shiitake mushroom (LD-M), 6) medium dose Shiitake mushroom (MD-M), 7) high dose Shiitake mushroom (HD-M). Oat bran powder was from OatWell® Crea-nutrition and the Shiitake mushroom was from Shenzen Dashan, Food Stuff. Co. Ltd., Shanghai that was imported by a local store in Australia. The nutrient composition of the oats and mushrooms is shown in Table 1. The low, medium and high doses of either oats or mushrooms contain beta-glucan that is comparable to 3, 9 and 27 g of the beta-glucan requirement for humans, respectively. The composition of the seven diets is shown in Table 2.
2.2. Body Weight, Food Intake and Fat Pad Masses
Animals were weighed weekly throughout the six week intervention period. Food intake was measured every 24 hours by weighing the amount of total food (g) provided to the rats and subtracting the remaining food (g) in the cage after 24 hours.
After completion of food intervention, rats were sacrificed via carbon dioxide asphyxiation. The white adipose tissue (WAT) comprised of visceral fat (epididymal, perirenal, and omental fat) and subcutaneous fat (inguinal fat) were then removed and weighed.
2.3. Plasma Lipid Profile
Blood samples were obtained by puncturing the right ventricle of the heart and collected in EDTA coated tubes and centrifuged at 3000 rpm at 22˚C for 25 minute. High density lipoprotein (HDL) was isolated from plasma with dextran sulphate and magnesium chloride, based on a modified method from Sjoblom and Eklund [25]. Total plasma cholesterol (TC), TAG, high density lipoprotein (HDL) and plasma Non Esterified Fatty acid (NEFA) were measured using the Konelab® 20XT automatic analyser. The TC, TAG and HDL were analysed with InfinityTM reagent from Thermo Fisher Scientific (Auburn NSW, Australia) and plasma NEFA were analysed use a highly specific enzymatic (Wako Chemical, Richmond, VA, USA).
2.4. Viscosity and Molecular Weight (MW) from Oat and Mushroom Beta-Glucan
2.4.1. Extraction of Beta-Glucan
Beta-glucans were extracted from commercial varieties of oats and shiitake mushrooms. Oats and Shiitake mushrooms were pulverized separately using a blender (Breville, Sydney, Australia) and sieved through 355 µm mesh. Different concentrations of oats and mushrooms (Table 3) were prepared by stirring a measured amount of each powder in de-ionised water at 70˚C for 30 minutes. The suspensions were then centrifuged in a Sorvall RC-5B centrifuge (DuPont Company, Wilmington, Delaware, USA) at 10,000 rpm for 30 minutes. The clear viscous supernatant solutions, containing extracted beta-glucans, were collected for viscosity measurement.
2.4.2. Viscosity Measurement
The apparent viscosity of the extract was determined at a constant temperature of 37˚C, to mimic the human body temperature, using a DV III Rheometer (Brookfield, Middleboro, Massachusetts, USA). A water-jacketed sample cup was employed to maintain a constant sample temperature during the measurement. The speed of the rotating spindle was increased and then decreased to the starting speed. The speeds were chosen so that the torque exerted on the liquid was between the manufacturer’s
Table 1. Nutrient information of OatWell® and Shiitake mushroom.
recommended ranges of 10% to 100%. At a particular speed, the viscosity was measured over the duration of 10 minutes. For the Shiitake mushroom beta-glucan, the minimum and maximum speeds used were 35 rpm (shear rate of 263 s–1) and 55 rpm (shear rate of 413 s–1), respectively, with an increment of 5 rpm. However, for the concentration 2 mg/ml, the maximum speed possible before the torque exceeded 100% was 45 rpm. For the oat beta-glucan, since there was a significant difference in viscosity with the change of concentration, the range of speed that could be used (ensuring torque was between 10% - 100%) also differed considerably. For 3 mg/ml, 8 mg/ml, and 2.5 mg/ml, the speeds used varied from 20 to 55 rpm, 8 to 45 rpm, and 0.01 to 0.5 rpm, respectively.
2.4.3. Determination of Molecular Weight
Molecular weights of the oat and mushroom beta-glucans were determined by high performance liquid chromatography (LC-20AT, Shimadzu, Kyoto, Japan) using a refractive index detector (RID-10A, Shimadzu, Kyoto, Japan). Samples of 100 µL were injected into a Waters Ultrahydrogel Linear 7.8 × 300 mm size exclusion column (Waters, Milford, MA, USA) that was maintained at 50˚C during measurement. De-ionised water (filtered
Table 2. Composition of experimental diet.
Table 3. Viscosities of oat and shiitake mushroom solutions at different concentrations. The values presented here were obtained at 45 rpm, except for high dose oat which was obtained at 0.01 rpm.
through a 0.45 µm filter membrane) was the mobile phase, set to flow at 0.7 mL/min. The run time per sample was 30 minutes. Polyethylene glycol (PEG) with different molecular weights (1000, 3000, 4000, 6000, and 8000 dalton) and pure beta-D glucan from Barley (Lot# BCBC4494V, Sigma Aldrich, Sydney, Australia) with a molecular weight of 230,000 dalton, were used as standards. The concentrations of the standards were 15 mg/ml. Oat and mushroom beta-glucan extracts, with concentrations 3 mg/ml and 2 mg/ml respectively (concentration in Table 3), were run through the HPLC together with the standards.
2.5. Faecal Weight and Fat Content
In the last week of intervention, faecal samples were collected each day for 3 days from all groups. The faecal samples from each cage (2 rats per cage) were collected, weighed and frozen at –80˚C until analysed for fat content. Fat content was analysed according to the modified procedure described by [31] . In brief, faeces were dried in a freeze dryer for 48 h. The dried faecal samples were ground using a mortar and pestle. Fat from the ground dried faeces was extracted by stirring in chloroformmethanol 2:1, which was mixed well. The supernatant was recovered after centrifugation at 3000 rpm for 5 minute at 22˚C. The supernatant was then dried using a stream of nitrogen. The dried fat was weighed using analytical balance (AND/HM-300, Japan). The ratio of faecal fat to faecal weight was calculated as mg faecal fat per g faecal weight.
2.6. Statistical Analysis
Data were expressed as mean ± standard error of the mean (SEM). Data were analysis by two way ANOVA. Dunnet’s method was used to examine the significance between the control group (HFD) and the treatment groups. To examine the significance among treatment groups, contrasts method was used followed by a post hoc-LSD test. A p value of 0.05 or less was considered significant. Statistical analysis was performed using SAS 9.1 (SAS Institute, Cary, NC, USA) and SPSS software (version 17.0, SPSS Inc., Chicago, IL, USA).
3. Results
3.1. Food Intake, Body Weight Gain and Fat Mass
This study compared the dose response effects of oat and mushroom enrichment diets on the amount of food intake, body weight gain (BWG) and fat deposition of rats fed a high-fat diet (HFD). Food intake did not differ among the seven groups of dietary intervention (Table 4). The BWG was significantly affected by both diets and doses (Table 4). The rats fed with the mushroom enrichment diet had lower BWG compared with the oat enrichment diet (Figure 1; p = 0.003). Furthermore, when comparing between oats and mushroom powder there was no effect in the low dose (p = 0.743), but significant effect in the me-
dium dose (–16%, p = 0.040) and in the high dose (–34%, p = 0.002) groups (Figure 1). The total fat deposition (epididymal + perirenal + omental + inguinal) was affected by both diets and doses (Table 5). The rats fed a mushroom enrichment diet had significantly lower total fat mass than the rats fed an oat enrichment diet (Figure 2(a), p = 0.001). Furthermore, there was no effect in total fat mass when comparing the low dose (p = 0.515) and medium dose (p = 0.117) groups, but significant effects were seen in the high dose (–41%, p = 0.015) group.
The WAT was affected by the diets and doses (Table 5). The rats fed a mushroom enrichment diet had significantly lower WAT than the rats fed an oat enrichment diet (Figure 2(b), p = 0.018). Furthermore, there were no significant effects in WAT when comparing the low dose and medium dose groups but a trend towards an effect in the high dose (–32%, p = 0.072) group. The inguinal fat mass was affected by the diets and doses (Table 5). The rats fed a mushroom enrichment diet had significantly lower inguinal fat mass than the rats fed an oat enrichment diet (Figure 2(c), p = 0.006). Furthermore, there were trends towards effects in the low dose (–30%, p = 0.082), medium dose (–32%, p = 0.086) and high dose (–47%, p = 0.078) groups. No statistical differences were found in the amount of other fat mass (epididymal, perirenal, omental, and visceral) deposition between rats fed a mushroom and rats fed an oat enrichment diet.
3.2. Plasma Triacylglycerol, Total Cholesterol, High Density Lipoprotein, and Non Esterified Fatty Acids
Plasma TAG levels were significantly affected by the diets and doses (Table 6). The rats fed a mushroom en-
Table 4. Food intake and body weight gain in rats fed experimental diets.
Table 5. Fat pad masses in rats fed experimental diets.
richment diet had significantly lower plasma TAG levels than the rats fed an oat enrichment diet (Figure 3, p = 0.004). Furthermore, there were significant effects on plasma TAG in rats fed a mushroom enrichment diet in low (–25%, p = 0.022), medium (–23%, p = 0.035), and high dose (–27%, p = 0.011) groups compared to rats on oat enrichment diet. Plasma high density lipoprotein (HDL) levels were significantly affected by diet (Table 6). The rats fed a mushroom enrichment diet had significantly higher plasma HDL levels than the rats fed an oat enrichment diet (p = 0.002). There was a trend towards higher HDL levels in high doses of mushroom enrichment diet compared to the oat enrichment diet (+22%, p = 0.052). There were no significant effects of diets and doses on plasma TC and non esterified fatty acids (NEFA) (Table 6).
3.3. Oat and Mushroom Beta-Glucan Viscosity and Molecular Weight
In order to find the mechanisms for the different effects of the oat and mushroom enrichment diets, this study characterized the beta-glucan viscosity and molecular
Table 6. Plasma lipid in rats fed experimental diets.
weight from the oats and mushrooms. Generally, both the oat and shiitake mushroom beta-glucans showed sheer thinning behavior where the viscosity decreased with higher speed. At low speed, they also showed thixotropic behavior where the viscosity decreased over time under constant shear rate. Due to the variety of speeds used (to ensure that the torque exerted on the liquid was between the manufacturer’s recommended range), for comparison, the viscosity data at 45 rpm is presented (Table 3). At this speed, the viscosity of the oat beta-glucan, at the concentrations studied in this work, was considerably higher than that of the mushroom. The viscosity of mushroom beta-glucan even at the highest concentration (18 mg/ml) was lower than that of oat beta-glucan at the lowest concentration (3 mg/ml), suggesting that viscosity is not the reason that mushroom beta-glucan is more effective to prevent weight gain and fat accumulation than oat beta-glucan. The viscosity data of high dose beta-glucan in oat solution (25 mg/ml) is shown separately because its value is 1000-fold higher (Table 3). Size exclusion chromatography data showed that both the Shiitake mushroom and oat extracts contained high molecular weight polymers, with those from Shiitake mushrooms larger than those from oats (Figure 4).
3.4. The Weight of Faeces and Total Lipid in Faeces
The faecal weights were significantly affected by the diets and doses (Table 7). The only diet that was statistically different to HFD was HD-O group showing a 24% reduction in faecal weight (Table 7).
The faecal fat weight to faecal weight ratio was significantly affected by doses in rats fed either mushroom or oat enrichment diets (Table 7). The faecal fat weight to faecal weight ratio was 16% higher in HD-M enrichment diet compared to HD-O (p = 0.026). However, no differences in faecal fat weight to faecal weight ratio
Figure 4. The high performance liquid chromatography (HPLC) profiles of β-glucan solutions extracted from oat and shitake mushroom and pure β D-glucan from Barley.
Table 7. Plasma lipid in rats fed experimental diets.
were found between rats fed the same amount of low and medium doses of mushroom and oat enrichment diets.
4. Discussion
The present study for the first time found that rats fed a HFD enriched with shiitake mushroom powder had stronger effects in lowering body weight gain, fat deposition and plasma TAG, and compared with oat powder. To determine the beneficial effect of shiitake mushrooms, dosage must also be considered. This study showed that a high dose of mushroom enriched diet led to more exclusion of fat in the faeces compared to a high dose of oat enriched diet.
In general, animal studies have been previously reported in the literature and these showed that mushroom enriched diet had an effect on body weight gain prevention [24,32-34]. The data of BWG prevention by mushroom was depending on the rat species [22,32,34,35], dosages in the diet and the variety of mushroom [32,33, 35-38]. There are no reported clinical trials in mushroom enriched diet to prevent BWG in humans.
The clinical study of oat enriched diet to prevent body weight gain was not largely reported, even though oat enrichment diet has been studied in different studies with different initial plasma lipid levels [5,7,11-14], doses of additional oat [8,11,12], length of treatment [5,7,12,13] and food matrix [5,7] all of which cannot achieve the constructive effect to prevent body weight gain. However a clinical study in oat enrichment diet reported decrease BWG when oat gives concurrently with exercise and low fat diet for 8 weeks [6]. Furthermore enriched oat in animal model diet showed decreasing in body weight gain when 20% oat bran concentrate enriched diet have 43% beta glucan content [10]. However, enrichment 4% and 8% oat beta glucan for replacing cellulose on hamster fed hypercholesterolemic diet did not affect on BWG [39].
There are very few studies that investigated the effect of oats and mushroom powder as part of a HFD on fat deposition. This current study showed that mushroom powder (HD-M) was more effective than oat powder (HDO) in lowering total fat mass (35% vs 5%), WAT (33% vs 2%) and inguinal fat (50% vs 13%). Similar results were reported by [34] an additional 20% of Maitake mushrooms in rats fed a cholesterol diet decreased 43% fat deposition. On the other hand no studies have reported the effect of oat enrichment diet on fat deposition.
It has been reported in the literature that mushroom and oat enriched diets have the effect of lowering plasma TAG in humans and animals. For example, mushroom enriched diets significantly lowered plasma TAG level in animal studies [22,23,33-35,40] and a human study [15], evidence from oat enriched diets showed that more than 20% of oats in the diet is necessary to achieve TAG lowering effects in rats [9]. Another study reported, the effect of an additional 20% oats with different molecular weight (370.000 g/mol - 1450.000 g/mol) in mice fed HFD had a significant effect on lowering plasma TAG level [10]. However, in human studies, additional oats in the diet had no effect on plasma TAG lowering effect [5- 8,11-13,17].
It is well known that lowering plasma TAG will decrease the fatty acid (FA) circulation, so it will decrease the source of fatty acid in adipose tissue through the adipogenesis process [41]. This was also reported by Novelli [4] that the increasing of plasma TAG level in rats fed HFD promoted fat deposition and BWG.
This current study showed that HD-M and HD-O resulted in 58% and 33%, respectively, increase in faecal fat excretion per faecal weight compared to HFD. Studies have found that 40% oat enriched diets significantly increased faecal cholesterol fourfold increase in mice fed a high fat diet accompanied by a decreased plasma TC and TAG levels [9]. A clinical study also reported that an oat bran diet in healthy subjects increased fat in faeces 57% more than a wheat bran diet [42]. Again, Cheung [36] reported hamsters fed HFD and Straw mushrooms enrichment significantly increased faecal sterol 81% more than hamsters fed the control diet (HFD and cellulose) which was accompanied by a significant 36% TC lowering effect.
Some studies reported the improvement in dyslipidaemia by beta-glucan was due to viscosity [7,16,17]. Both beta-glucan from oats [43,44] and mushrooms [45] can slow down the digestion transit time in the lower part of the small intestine and in the large intestine, therefore delaying nutrient absorption. This study measured both oat and mushroom beta-glucan molecular weight before these were added and mixed to the rat food. The results showed that MW in Shiitake mushroom beta glucan was higher than oat beta glucan used in this study. However, it is uncertain whether the viscosity of oats or mushrooms alone would be similar to the actual viscosity of rat food after it was added to oats or Shiitake mushrooms. This is because in food enriched with oats and Shiitake mushrooms viscosity was affected by the food preparation, such as food stored in a frozen state, and the digestion process that could decrease the MW of beta-glucan.
For instance, the freeze-thaw process will decrease MW by 40% and the digestion process will decrease by 100,000 Dalton [46]. In this study, the rat foods were frozen before being given to rats. As the mushroom MW was greater than oat MW, after the freeze-thaw process and digestion, the MW of the oats was expected to remain <1,000,000 Dalton and the MW of the mushrooms was expected to remain >1,000,000 Dalton. Although the correlation of MW and the effect of viscosity were still doubtful, Tosh, Brummer et al. [47] reported that in order to achieve the viscosity effect of beta-glucan, the MW should be >1,000,000 Dalton. Kerckhoffs, Hornstra et al. [7] also reported that a MW of beta-glucan <1,200,000 Dalton could still lower plasma lipid if administered with a drink. Therefore the viscosity in oats and Shiitake mushrooms tested before they were added to the rat food may not be able to explain the different effects of oat and Shiitake mushroom enriched diets in lowering plasma lipid levels in vivo.
Shiitake mushroom powder contains other active ingredients such as eritadenine and chitin. Eritadenine may contribute to the effect by inhibiting the plasma TAG derived lipoprotein release from the liver [48,49]. The concentration of eritadenine is about 0.36% in Shiitake mushroom powder [29]. The HD-M diet used in this study contains ~200 mg eritadenine/kg food. Sugiyama [18] reported that an additional 50 mg eritadenine in choline deficient rats lowered plasma lipid by –68% and –83% of plasma TC and TAG respectively.
Chitin is insoluble in water and grouped as functional fibre to lower blood lipids [50,51]. However, chitin needs to be converted to chitosan to lower plasma lipid levels [52]. The process of converting chitin to chitosan is by alkaline hydrolysis (45% NaOH, 100˚) [53]. Hence this conversion is unlikely to have occurred in vivo, and therefore chitin is unlikely to explain the reduction in plasma TAG in this study.
Accordingly, this result and references suggest the lowering of plasma TAG levels in HD-M has possibly also been affected by eritadenine. This reason was supported by data that showed that although the fat faecal exclusion both of HD-M and HD-O were not significantly different the plasma TAG level, fat mass deposition and body weight gain between HD-O and HD-M were significantly different. Therefore other mechanisms possibly promoted the lowering of plasma TAG levels in HD-M.
5. Conclusion
In summary, the mushroom diet is better than the oat diet as part of a HFD because it reduces BWG, total fat mass, plasma TAG and increased fat faecal excretion. The dosage required for these effects was the HD-M (1.8% wt:wt beta glucan from mushroom or 6% mushroom powder) with lower doses having minimal effects. The potential reason why mushrooms were better than oats was possibly its chemical structure. Food enriched with Shiitake mushroom was more stable and retained viscosity effects after the freeze-thaw process compared to food enriched with oats. In addition, Shiitake mushrooms also contain another potential biological component, namely eritadenine.
6. Acknowledgements
This study was supported by the School of Health Science, University of Wollongong (HDR student funding), IHMRI and URC grant of the University of Wollongong. Dian Handayani was supported by a DIKTI Post-graduate Scholarship for lecturers in Indonesian universities.
NOTES