Hostname: page-component-586b7cd67f-g8jcs Total loading time: 0 Render date: 2024-11-26T17:02:51.610Z Has data issue: false hasContentIssue false

Actinidin from kiwifruit (Actinidia deliciosa cv. Hayward) increases the digestion and rate of gastric emptying of meat proteins in the growing pig

Published online by Cambridge University Press:  19 November 2013

Carlos A. Montoya*
Affiliation:
Riddet Institute, Massey University, Private Bag 11222, Palmerston North, New Zealand
Shane M. Rutherfurd
Affiliation:
Riddet Institute, Massey University, Private Bag 11222, Palmerston North, New Zealand
Trent D. Olson
Affiliation:
Riddet Institute, Massey University, Private Bag 11222, Palmerston North, New Zealand
Ajitpal S. Purba
Affiliation:
Riddet Institute, Massey University, Private Bag 11222, Palmerston North, New Zealand
Lynley N. Drummond
Affiliation:
ZESPRI International Limited, Mount Maunganui, New Zealand
Mike J. Boland
Affiliation:
Riddet Institute, Massey University, Private Bag 11222, Palmerston North, New Zealand
Paul J. Moughan
Affiliation:
Riddet Institute, Massey University, Private Bag 11222, Palmerston North, New Zealand
*
*Corresponding author: C. A. Montoya, fax +64 6 3505655, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

The present study aimed to investigate the effect of dietary actinidin on the kinetics of gastric digestion of beef muscle proteins and on the rate of stomach emptying in growing pigs. For this purpose, 120 pigs (mean body weight 28 (sd 2·9) kg) were fed beef muscle protein-based diets containing either actinidin (fresh green kiwifruit pulp or gold kiwifruit pulp supplemented with purified actinidin) or no actinidin (fresh gold kiwifruit pulp or green kiwifruit pulp with inactivated actinidin). Additionally, fifteen pigs were fed with a protein-free diet to determine the endogenous protein flow. Pigs were euthanised at exactly 0·5, 1, 3, 5 and 7 h postprandially (n 6 per time point for each kiwifruit diet and n 3 for protein-free diet). Stomach chyme was collected for measuring gastric retention, actinidin activity, individual beef muscle protein digestion based on SDS–PAGE and the degree of hydrolysis based on the appearance of free amino groups. The stomach emptying of DM and N was faster when actinidin was present in the diet (P< 0·05): the half gastric emptying time of DM was 137 v. 172 min ( ± 7·4 min pooled standard error) for the diets with and without actinidin, respectively. The presence of dietary actinidin in the stomach chyme increased the digestion of beef muscle protein (P< 0·05) and, more specifically, those proteins with a high molecular weight (>34 kDa; P< 0·05). In conclusion, dietary actinidin fed in the form of fresh green kiwifruit increased the rate of gastric emptying and the digestion of several beef muscle proteins.

Type
Full Papers
Copyright
Copyright © The Authors 2013 

Actinidin is a cysteine protease present at high levels (284 μmol-o-nitrophenol/min per g DM) in several varieties of kiwifruit, including ‘green’ kiwifruit (Actinidia deliciosa cv. ‘Hayward’), but is not present in ‘gold’ kiwifruit (Actinidia chinensis cv. ‘Hort16A’). Although the function of actinidin is unknown, it has been suggested that actinidin acts as a pathogen defence and assists in the ripening of kiwifruit( Reference Boland 1 ). Dietary actinidin from kiwifruit affects gastric protein digestion. Kaur et al. ( Reference Kaur, Rutherfurd and Moughan 2 ), using an in vitro model of gastric digestion, showed that actinidin (in the form of a green kiwifruit extract) increased the extent and rate of gastric digestion of several proteins (casein, soya protein isolate and beef muscle). Moreover, Rutherfurd et al. ( Reference Rutherfurd, Montoya and Zou 3 ), using an in vivo rat model, showed that dietary actinidin (in the form of freeze-dried whole kiwifruit) increased the extent of gastric digestion of several protein sources, including soya protein isolate, beef muscle, gelatin and gluten. To date, however, there is no information available describing the effect of actinidin or of green kiwifruit on the kinetics of gastric digestion for different food proteins.

Previous studies have suggested that the rate and the extent of gastric digestion of dietary proteins may modulate the stomach emptying rate (SER)( Reference Rehner, Heil and Auge 4 Reference Feinle, Christen and Grundy 7 ). Furthermore, altering the SER may influence the rate of digestion and absorption of food nutrients( Reference Rehner, Heil and Auge 4 , Reference Mahé, Roos and Benamouzig 8 ). If actinidin increases the rate at which proteins are digested and are thus emptied from the stomach, it may play a role in the digestion and absorption of dietary proteins and other nutrients overall. There is no information, however, as to whether an increase in gastric protein digestion observed in the presence of dietary actinidin influences the SER.

In the present study, it was hypothesised that actinidin would increase the rate of gastric digestion of dietary proteins and that this would in turn modulate the SER of proteins. Consequently, the present study aimed to explore the effect of dietary actinidin (supplied in the form of fresh green kiwifruit) on the kinetics of gastric digestion and the SER of a beef muscle protein source. The growing pig was used as a model for adult humans( Reference Moughan and Rowan 9 ) and beef muscle protein was chosen as a model protein, as previous studies in our laboratory, based on a rat model, have shown that actinidin can affect the gastric digestion of some beef muscle proteins and also that anecdotally consuming diets high in meat has been associated with gastric discomfort.

Experimental methods

Dietary treatments

A basal diet, a protein-free diet (used to determine the endogenous proteins present in the stomach chyme) and four semi-synthetic experimental diets containing beef muscle protein as the sole source of protein and either green (Hayward) or gold (Hort16A) kiwifruit were formulated (Table 1). The quantity of fresh kiwifruit included in the diets was calculated with reference to the prescribed daily food intake for an adult human (approximately 500 g DM)( Reference Baer, Rumpler and Miles 10 ), to provide an intake equivalent of consuming two kiwifruit with an average-sized meal( Reference Kaur, Rutherfurd and Moughan 2 ); thus, kiwifruit represented 20 % of the daily DM intake. Beef muscle was prepared by grinding freeze-dried and minced low-fat beef steak through a 1 mm mesh.

Table 1 Ingredient and nutrient compositions of the experimental diets (g/kg DM)

* In the green kiwifruit test diet, the green kiwifruit contained 284 μmol-o-nitrophenol/min per g DM of actinidin activity.

In the green kiwifruit negative control diet, actinidin present in the green kiwifruit was inactivated with 15 μl H2O2/g of fresh green kiwifruit pulp.

The actinidin activity of the purified actinidin was 2154 μmol-o-nitrophenol/min per g DM, and was added to the gold kiwifruit positive control diet to supply the same actinidin activity as in the green kiwifruit test diet.

§ The green and gold kiwifruit pulp was prepared fresh and added to the diets just before each meal.

Meat protein was prepared by freeze-drying low-fat beef steak and then by grinding, as described in the Experimental methods section.

Vitamin/mineral mix was formulated to meet the requirements for vitamins and minerals as described by the National Research Council( 16 ).

A. chinensis cv. ‘Hort16A’ (gold kiwifruit) was chosen as an actinidin-negative control, as it is almost devoid of actinidin activity( Reference Bublin, Mari and Ebner 11 ) (gold kiwifruit negative control). Although the chemical composition and microstructure of gold kiwifruit is similar to that of green kiwifruit (A. deliciosa cv. Hayward), they are not identical (7 and 5 % crude protein, 13 and 17 % total dietary fibre, 4 and 3 % starch, 3 and 5 % total lipids and 4 and 4 % minerals for gold and green kiwifruit, respectively)( Reference Henare, Rutherfurd and Drummond 12 ). Thus, a second negative control was used; green kiwifruit in which actinidin was chemically inactivated (green kiwifruit negative control). A test diet (green kiwifruit test diet) containing fresh green kiwifruit pulp was also prepared along with a positive control diet (gold kiwifruit positive control) containing gold kiwifruit pulp to which purified actinidin (New Zealand Pharmaceuticals Limited) was added such that the actinidin activity was the same as in the test diet. For the green kiwifruit negative control, actinidin was inactivated using H2O2 (30 %, 15 μl H2O2/g of blended green kiwifruit pulp), to oxidise the sulfhydryl groups of cysteine proteases( Reference Kniel, Sumner and Lindsay 13 ). The concentration of H2O2 was lower than that suggested for the Food and Drug Administration security range (up to 3 %)( 14 ), and well below the toxic level for pigs (0·13 v. 6·7 g/kg body weight (BW), Material Safety Data Sheet)( 15 ). The diets were formulated to meet the nutrient requirements of the growing pig, as prescribed by the National Research Council( 16 ), for all nutrients, except protein in the protein-free diet. Titanium dioxide was added to the experimental diets as an indigestible marker. The daily ration was calculated as 90 g DM/kg metabolic BW (BW0·75) per d, and was fed to the pigs as two equal meals given at 09.00 and 16.00 hours. The fresh kiwifruit were peeled and crushed. The other ingredients and fresh kiwifruit were then thoroughly mixed immediately before the feeding of each pig. Simultaneously, purified actinidin was added to the gold kiwifruit positive control diet and mixed thoroughly. For the green kiwifruit negative control diet, actinidin in the green kiwifruit pulp was inactivated, as described above, 12 h before being added to the diets.

Experimental design

Ethics approval for the animal trials was obtained from the Animal Ethics Committee, Massey University, Palmerston North, New Zealand. A total of 135 entire male pigs (PIC Camborough 46 × PICboar 356L, 28 (sd 2·9) kg BW) were used in the study. Pigs were kept individually in metabolism crates in a room maintained at 21 ± 2°C with a 10 h light–14 h dark cycle. Pigs were adapted to their environment and diet (basal diet) for 10 d. On the 11th day, pigs were allocated to one of the four experimental diets (green kiwifruit test, green kiwifruit negative control, gold kiwifruit positive control and gold kiwifruit negative control (n 30 per dietary group constituting five time points × six pigs per time point)) or the protein-free diet (n 15, five time points × three pigs per time point). On the 13th day, water was withheld from the pigs for 2 h before each animal received a single meal at 09.00 hours, consisting of one half of its daily ration (45 g DM/kg BW0·75). At 0·5, 1, 3, 5 and 7 h after the start of feeding, the pigs were anaesthetised with an intramuscular injection of an anaesthetic cocktail (0·04 ml/kg BW of Zoletil 100 (50 mg/ml), Ketamine (50 mg/ml) and Xylazine (50 mg/ml); Provet). Immediately after sedation, the pigs were euthanised by an intra-cardial injection of sodium pentobarbitone (0·3 ml/kg BW of Pentobarb 300; Provet). The stomach was immediately dissected out, and contents were collected, weighed and thoroughly mixed. A representative aliquot of chyme was taken, frozen at − 20°C and freeze-dried before chemical analysis. Additionally, approximately 0·5 g of each stomach chyme and diet sample were collected into Eppendorf tubes containing 1 ml of 0·05 m-phosphate buffer solution and 0·4 m-sodium metabisulphite for the determination of actinidin activity. From the pigs fed the diets containing kiwifruit on the final day, only one of the pigs fed the gold kiwifruit positive control diet and euthanised at 0·5 h did not eat all of the diet (the pig consumed 89 % of the offered diet). For this pig, the feed refusal was collected, dried and weighed to enable the calculation of the SER.

Chemical analysis

The diets were analysed in duplicate for DM (method 930.15( 17 )), protein (N × 6·25, method 968.06 using a LECO elemental analyser; LECO Corporation), ash (method 942.05 using a muffle furnace at 500°C), gross energy (LECO AC-350 Automatic Calorimeter; LECO Corporation), total dietary fibre( Reference Prosky, Asp and Schweizer 18 ) and titanium dioxide( Reference Short, Gorton and Wiseman 19 ). Stomach chyme was analysed for DM, N and titanium dioxide as described above.

Actinidin activity

The kiwifruit pulp was mixed and manually homogenised at 4°C in 0·05 m-phosphate buffer solution (pH 6) containing 0·4 m-sodium metabisulphite (5·6 g/ml) to avoid enzyme oxidation before being filtered through muslin cloth. The same phosphate buffer solution was also mixed with purified actinidin (5 mg/ml), the green and gold kiwifruit diets and stomach chyme (approximately 0·5 g/ml). Each of the above preparations was centrifuged at 13 000  g for 30 min at 4°C. The supernatants were collected, and actinidin activity was measured as described previously( Reference Boland and Hardman 20 ). Briefly, 100 μl of the substrate Cbz-l-Lys-o-nitrophenol hydrochloride (1·2 g/l of deionised distilled water, Sigma; Sigma-Aldrich Pty Limited) were added to 2·85 ml of phosphate buffer solution (0·05 m, pH 6·0) directly in a spectrophotometer cuvette. No spontaneous breakdown of the substrate was observed. Then, 50 μl of a mixture containing the actinidin solution and 0·1 m-dithioerythritol (1:1, v/v) were added. The rate of change in absorbance was measured at 348 nm using a spectrophotometer.

Total degree of protein hydrolysis

Total degree of protein hydrolysis was determined as the increase in the concentration of free amino groups in the chyme samples, and was analysed using the o-phthaldialdehyde method( Reference Church, Swaisgood and Porter 21 ). Proteins were extracted from the chyme samples after mixing with sodium tetraborate buffer (12·5 mm and 2 % SDS) for 1 h at room temperature (10 mg sample/ml buffer). The extracted proteins were mixed with the o-phthaldialdehyde solution (0·1:1, v/v) and left to stand for 2 min before reading the absorbance at 340 nm. The total amino groups in the diets were determined after acid hydrolysis with 6 m-HCl for 24 h at 110°C. Then, HCl was removed using a centrifugal concentrator and replaced by sodium tetraborate buffer to measure the amino groups as described above.

Electrophoresis analysis (SDS–PAGE)

Tricine SDS–PAGE analysis was carried out as described by Rutherfurd et al. ( Reference Rutherfurd, Montoya and Zou 3 ). The measurement of intact proteins and peptides stained with Coomassie Brilliant Blue R was carried out using gel scanning densitometry (Molecular Imager Gel Doc XR; Bio-Rad) followed by analysis using Quantity One 1-D Analysis software (Bio-Rad). Staining density was measured (in arbitrary density units (ADU)) horizontally for each protein band. Samples of the stomach chyme from pigs fed the protein-free diet were run on separate gels, and the ADU at the same MW of the dietary proteins were used to correct for endogenous proteins. In addition, the MW of each protein band was determined from the MW standards run in each gel, using Quantity One 1-D Analysis software (Bio-Rad).

Calculations and statistical analysis

The gastric disappearance of the individual proteins was calculated as follows:

$$\begin{eqnarray} True protein disappearance (\%) = (BI_{diet} - (BI_{chyme}\times TiO_{2 diet}/TiO_{2 chyme} - BI_{endogenous protein flow}))/BI_{diet}\times 100, \end{eqnarray}$$

where BI is the band intensity of each individual beef muscle protein measured as ADU/kg DM on the SDS–PAGE gels. TiO2 content was expressed as g/kg DM.

The BI flows of endogenous proteins in the stomach were calculated using the following equation (expressed as ADU/kg DM):

$$\begin{eqnarray} BI_{endogenous protein flow} (ADU/kg DM intake) = BI_{chyme} (ADU/kg DM)\times TiO_{2 diet}/TiO_{2 chyme}. \end{eqnarray}$$

The time required to reach half of the gastric disappearance (TD50) of each individual protein in each dietary treatment was calculated according to the Michaelis–Menten non-linear model, with time replacing substrate concentration( Reference Lopez, France and Gerrits 22 ):

$$\begin{eqnarray} Gastric disappearance (\%) = \alpha \times time/( \beta + time), \end{eqnarray}$$

where the parameter α is the maximum gastric disappearance (100 %) at maximum time and β the half time of gastric disappearance (TD50). The parameter β for the fitted curve of each diet and for each individual protein was estimated using the PROC NLIN of SAS (SAS Institute Inc.)( 23 ) via the Gauss–Newton method. The fitted curves of the diets were then compared using the F test by considering whether the data for all the treatments were better explained by a single non-linear model (i.e. no difference between the treatments) or by individual non-linear models( Reference Bruin 24 ). As the parameter β was the only parameter differing between the fitted curves for each diet, the P value obtained from the F test described above was ascribed to the parameter β.

The true gastric degree of protein hydrolysis of the total beef muscle protein was calculated as follows:

$$\begin{eqnarray} True degree of protein hydrolysis (\%) = (NH_{2diet} -- (((NH_{2diet} -- NH_{2chyme}) -- NH_{2EF})\times TiO_{2diet}/TiO_{2chyme}))/NH_{2diet}\times 100. \end{eqnarray}$$

where NH2 diet and NH2 chyme are the total amino groups in the diets and the amino groups in the chyme of each treatment, respectively, at each time point in g/kg DM. NH2EF is the flow of endogenous amino groups which was calculated from the stomach chyme of the pigs fed the protein-free diet (g/kg DM):

$$\begin{eqnarray} Endogenous NH_{2} flow (g/kg DM intake) = NH_{2 chyme} (g/kg DM)\times TiO_{2 diet}/TiO_{2 chyme}. \end{eqnarray}$$

The relative amounts of DM and N in the stomach over time (expressed as g DM) were determined as follows:

$$\begin{eqnarray} Relative DM in the stomach over time (\%) = DM_{(time i )}/DM_{(intake)}\times 100, \end{eqnarray}$$
$$\begin{eqnarray} Relative N in the stomach over time (\%) = (DM\times concentration N_{(time i )})/(DM\times concentration N_{(intake)})\times 100, \end{eqnarray}$$

where time i (0·5, 1, 3, 5 and 7 h) is the time between when the pigs received their meal and when they were euthanised.

The relative retention of DM and N in the stomach was then analysed according to the power exponential model reported( Reference Elashoff, Reedy and Meyer 25 ):

$$\begin{eqnarray} Relative\,\,remaining_{time} = \alpha _{0} exp -- ( \kappa \times time)^{\beta }, \end{eqnarray}$$

where α0 is the proportion remaining at time 0 (100 %). The parameters κ (the slope of the curve) and β (an index for the shape of the curve) for the fitted curves of each diet were estimated using the PROC NLIN of SAS( 23 ) via the Gauss–Newton method for each diet before being compared statistically( Reference Bruin 24 , Reference Freund and Littell 26 ). They were also used to determine the half gastric emptying time (T 1/2) according to the equation proposed by Odunsi et al. ( Reference Odunsi, Camilleri and Szarka 27 ):

$$\begin{eqnarray} T _{1/2} = (1/ k )\times (log(1/0\cdot 5))^{(1/ \beta )}. \end{eqnarray}$$

To identify the time points where dietary actinidin influenced the response variables, an ANOVA was conducted, with the pig as the experimental unit, to test the effect of dietary treatment, time and their interaction (factorial design four dietary treatments × five time points) using the PROC MIXED procedure of SAS( 23 ). The model diagnostics of each variable based on its residuals were tested after combining the PROC UNIVARIATE and the ODS GRAPHICS procedures of SAS( 23 ) before comparing the means. A variable was transformed when it failed in one or more of the diagnostic model assumptions (expected mean of the residuals is 0, independent residuals, constant variance across the treatments and normal distribution of the residuals). A completely randomised factorial design without replication( Reference Milliken and Johnson 28 ) was used to test the effect of the diet and the protein on the time required to reach half of the protein degradation using the PROC ANOVA procedure( 23 ).

Results

Apart from two pigs presenting loose stools during the first week of the trial, all of the pigs were healthy during the experiment. Data were gathered from all the pigs, and no data were excluded from the data analysis.

Determined actinidin activity in the diets and the stomach chyme

To confirm the presence or absence of actinidin in the diets and also to assess the stability of actinidin in the stomach, diet samples and stomach chyme samples from each pig were collected and actinidin activity determined (Table 2). As expected, the green kiwifruit test and gold kiwifruit positive control diets had higher actinidin activity than both the negative control diets (P< 0·01).

Table 2 Actinidin activity (μmol-o-nitrophenol/min per g DM) in the experimental diets and the stomach chyme of growing pigs fed the diets* (Mean values with their pooled standard errors, n 30 for diet, n 6 per chyme)

a,b,cMean values within a row with unlike superscript letters were significantly different (P< 0·05).

z,y,xMean values within a column with unlike superscript letters were significantly different (P< 0·05).

* The experimental diets contained beef muscle protein as the sole protein source containing either fresh green kiwifruit pulp (green kiwifruit test), green kiwifruit pulp with inactivated actinidin (green kiwifruit negative control), fresh gold kiwifruit pulp (gold kiwifruit negative control) or fresh gold kiwifruit pulp supplemented with purified actinidin to provide the same actinidin activity as in the green kiwifruit test diet (gold kiwifruit positive control).

In the stomach, there was an interaction between dietary treatment and time for actinidin activity in the chyme (P< 0·001). The actinidin activity was similar between the green kiwifruit negative control and gold kiwifruit negative control diets at all postprandial time points, but lower than the diets containing dietary actinidin during the first 5 h (P< 0·05). Additionally, the gold kiwifruit positive control diet had higher actinidin activity than the green kiwifruit test diet during the first 5 h of gastric digestion (P< 0·05), but at 7 h, there was no difference in their actinidin activity. The average actinidin activity of the chyme for the pigs fed the protein free-diet was 27·3 μmol-o-nitrophenol/min per g DM (data not shown). There was a marked increase in actinidin activity between the dietary and chyme values for each diet.

Effect of dietary actinidin on stomach emptying rate

Recognising that the data are from a time–response study, and also considering the importance of identifying the time points at which dietary actinidin influenced both the stomach emptying and the gastric disappearance of beef muscle proteins, the results of the study were analysed using two approaches (time–response using established models and the multiple range test at each time point when the interaction between dietary treatment and time was statistically significant). Both approaches led to the same overall conclusions, but each approach provided additional insight.

The gastric DM content decreased during the postprandial period, such that between 80 and 93 % of the consumed DM had exited the stomach at 7 h after the meal (Table 3). There was an interaction between dietary treatment and time on the amount of DM retained in the stomach (P< 0·05). In general, the DM retained in the stomach was lower for the diets containing actinidin (green kiwifruit test and gold kiwifruit positive control) than for both the negative control diets at 1–3 h postprandially. The gold kiwifruit negative control diet was associated with a lower gastric DM content at 7 h compared with the green kiwifruit negative control and gold kiwifruit positive control diets (P< 0·05). The effect of dietary actinidin on DM retention was confirmed when the β (shape of the curve) and κ (slope of the curve) parameters were compared. The gold kiwifruit negative control diet had the highest β parameter compared with the diets containing actinidin, while the green kiwifruit negative control diet had the lowest κ parameter compared with the other diets (P< 0·05). The values of the β and κ parameters were then used to estimate the time required to empty half of the gastric contents (T 1/2). T 1/2 was 1·3-fold higher in the absence of dietary actinidin (159–184 min) than in its presence (134–139 min) (P< 0·01; Table 3).

Table 3 Gastric relative retention and gastric retention parameters of DM and nitrogen in growing pigs fed the experimental diets* (Mean values with their pooled standard errors, n 6)

a,b,cMean values within a row with unlike superscript letters were significantly different (P< 0·05).

z,y,xMean values within a column with unlike superscript letters were significantly different (P< 0·05).

* The experimental diets contained beef muscle protein as a sole protein source containing either fresh green kiwifruit pulp (green kiwifruit test), green kiwifruit pulp with inactivated actinidin (green kiwifruit negative control), fresh gold kiwifruit pulp (gold kiwifruit negative control) or fresh gold kiwifruit pulp supplemented with purified actinidin to provide the same actinidin activity as in the green kiwifruit test diet (gold kiwifruit positive control).

T 1/2, the time at which half the DM or N had emptied from the stomach; this value was calculated based on the fitting parameters (β and κ) of a non-linear model( Reference Elashoff, Reedy and Meyer 25 ) and the equation( Reference Odunsi, Camilleri and Szarka 27 ) described in the Experimental methods section.

The percentage of N retained in the stomach at 0·5, 1, 3, 5 and 7 h was 86·2a, 75·3b, 45·1c, 22·4d and 6·1e, respectively. Values with unlike superscript letters were significantly different (P< 0·05).

The relative retention of N in the stomach was influenced by actinidin and time (P< 0·01), but there was no interaction (P>0·05) between actinidin and time. The N retained in the stomach was lower for the green kiwifruit test diet when compared with the other dietary treatments (P< 0·05). As expected, the amount of N retained in the stomach decreased over time (P< 0·01). The gold kiwifruit negative control diet had the highest β parameter compared with the other diets, while the green kiwifruit test diet had the highest κ parameter compared with the other diets (P< 0·05). Based on previous results, the estimation of T 1/2 showed that the green kiwifruit test diet had a lower T 1/2 when compared with the other dietary treatments (123 v. 147–158 min, P< 0·01).

Effect of dietary actinidin on the gastric hydrolysis of beef muscle proteins

The effect of dietary actinidin on the gastric hydrolysis of the total beef muscle protein is shown in Table 4. For true gastric hydrolysis, there was an interaction between dietary treatment and time (P< 0·001). The diets containing actinidin had higher gastric hydrolysis during the first 5 h postprandially than the diets without actinidin (P< 0·001). In addition, the gold kiwifruit positive control diet had higher gastric hydrolysis at 3 and 5 h compared with the green kiwifruit test diet (P< 0·001). At 7 h, there were no differences in gastric hydrolysis between the dietary treatments (P>0·05).

Table 4 True gastric hydrolysis of dietary proteins in growing pigs fed the experimental diets* (Mean values with their pooled standard errors, n 6)

a,b,cMean values within a row with unlike superscript letters were significantly different (P< 0·05).

z,y,xMean values within a column with unlike superscript letters were significantly different (P< 0·05).

* The experimental diets contained beef muscle protein as a sole protein source containing either fresh green kiwifruit pulp (green kiwifruit test), green kiwifruit pulp with inactivated actinidin (green kiwifruit negative control), fresh gold kiwifruit pulp (gold kiwifruit negative control) or fresh gold kiwifruit pulp supplemented with purified actinidin to provide the same actinidin activity as in the green kiwifruit test diet (gold kiwifruit positive control).

The proteins detected in the beef muscle preparation were similar to those seen previously( Reference Rutherfurd, Montoya and Zou 3 ), including myosin heavy chain (MHC), β-actinin, α-actinin, desmin, actin, tropomyosin-β-chain, tropomyosin-α-chain, myosin light chain (MLC) 1, troponin I and MLC2, as well as unidentified proteins with molecular weights (MW) of 64, 45, 32, 29 and 25 kDa. In addition, two other unidentified proteins (88 and 43 kDa) were observed. The results from the SDS–PAGE analysis of the diet and chyme are given in Fig. 1, and the mean values for determined true gastric disappearance (%) of each protein selected using the SDS–PAGE analysis are presented in Table 5 and Supplementary table (available online).

Fig. 1 SDS–PAGE analysis of a beef muscle protein diet and stomach chyme of growing pigs sampled at 0·5, 1, 3, 5 and 7 h after consuming the diets: (a) green kiwifruit test and green kiwifruit negative control or (b) gold kiwifruit positive control and gold kiwifruit negative control. The amount of the sample loaded in each lane was normalised based on the DM per ml of Tricine sample buffer (10 mg/ml). The protein bands were identified as follows: a, myosin heavy chain; b, β-actinin; c, α-actinin; d, 88 kDa protein; e, desmin; f, 45 kDa protein; g, 43 kDa; h, actin; i, tropomyosin-β-chain; j, tropomyosin-α-chain; k, myosin light chain 1; l, troponin I; m, myosin light chain 2. MW, molecular weight.

Table 5 True gastric disappearance and time to reach half of the gastric true disappearance (TD50) of proteins in growing pigs fed the experimental diets (Mean values with their pooled standard errors, n 6)

ID, identification; MHC, myosin heavy chain; MLC, myosin light chain; T-β-chain, tropomyosin-β-chain; T-α-chain, tropomyosin-α-chain.

a,b,cMean values within a row with unlike superscript letters were significantly different (P< 0·05).

z,y,xMean values within a column with unlike superscript letters were significantly different (P< 0·05).

* The experimental diets contained beef muscle protein as a sole protein source containing either fresh green kiwifruit pulp (green kiwifruit test), green kiwifruit pulp with inactivated actinidin (green kiwifruit negative control), fresh gold kiwifruit pulp (gold kiwifruit negative control) or fresh gold kiwifruit pulp supplemented with purified actinidin to provide the same actinidin activity as in the green kiwifruit test diet (gold kiwifruit positive control).

MHC, actin and MLC1 were selected for this table because they are some of the main beef muscle proteins and they described the effect of actinidin on their gastric disappearance. The gastric disappearance for the other proteins is detailed in the Supplementary table (available online).

The gastric disappearance of MLC1 at 0·5, 1, 3, 5 and 7 h was 15·3d, 15·9d, 40·6c, 67·5b and 88·7a, respectively. Values with unlike superscript letters were significantly different (P< 0·05).

§ This value was calculated based on the Michaelis–Menten model described in the Experimental methods section. The P value reported for the TD50 was obtained after comparing the fitted curve for the diets. The mean comparison between the treatments was conducted from the confidence limits at 95 % reported after fitting the non-linear model.

The overall true gastric disappearance of beef muscle proteins in the presence or absence of dietary actinidin ranged from 0 to 68 % at 0·5 h, 0 to 81 % at 1 h, 15 to 92 % at 3 h, 38 to 94 % at 5 h and 61 to 100 % at 7 h of digestion (Table 5 and Supplementary table (available online)). There was an interaction between dietary actinidin and time on the gastric disappearance of all the beef muscle proteins (P< 0·05), with the exception of the proteins 45 kDa, MLC 1, troponin I and MLC2. In general, the true gastric disappearances of the beef muscle proteins of the green kiwifruit test and gold kiwifruit positive control diets were similar for most of the proteins across the different postprandial sampling times (P>0·05). The only exceptions were tropomyosin-β-chain and tropomyosin-α-chain at 1 h and tropomyosin-β-chain at 0·5 h postprandially, for which gastric disappearances were higher for the gold kiwifruit positive control diet (P< 0·05). Furthermore, the two negative control diets had similar degradability values for most of the proteins (P>0·05), with the exceptions of MHC, β-actinin, 88 kDa, actin and tropomyosin-β-chain, for which the green kiwifruit negative control diet had higher true gastric disappearance values (P< 0·05) for some of the sampling times. Dietary actinidin increased the true gastric disappearance of several beef muscle proteins (P< 0·05) particularly for some of the higher-MW proteins (MHC, β-actinin, α-actinin, 88 kDa, desmin, 45 kDa, 43 kDa, actin, tropomyosin-β-chain and tropomyosin-α-chain). For these proteins, the true gastric disappearances were higher for the diets containing actinidin (green kiwifruit test and gold kiwifruit positive control) compared with the two negative control diets, especially during the first 3 h of digestion (P< 0·05). However, from 5 h onwards, there were no differences among the dietary treatments (P>0·05). In contrast, the true gastric disappearance of proteins with low MW (MLC1, troponin I and MLC2) was only influenced by time (P <0·05).

The time required to reach half of the gastric disappearance (TD50 or the parameter β in the non-linear gastric disappearance model) for each individual protein in each dietary treatment reflects the results above (Table 5). In general for both the negative control diets, a longer time was required to reach half of the protein disappearance than was required for the green kiwifruit test and gold kiwifruit positive control diets (e.g. the TD50 for MHC was >36 and < 22 min for the diets without and with dietary actinidin, respectively; P< 0·01; Fig. 2).

Fig. 2 Fitted curves( Reference Lopez, France and Gerrits 22 ) of gastric disappearance for myosin heavy chain in growing pigs fed the green kiwifruit negative control (□), green kiwifruit test (■), gold kiwifruit negative control (Δ) and gold kiwifruit positive control (▲) diets. The pooled standard error of the fitted curves was 4·46 %.

Also, there was a difference among the proteins (within the diet) for the time required for half of the amount of each protein present to disappear (TD50) (P< 0·001). MHC, β-actinin, α-actinin, actin, MLC2, and the unidentified 88, 45 and 43 kDa proteins required less time to reach 50 % disappearance (TD50= 22–76 min for the green kiwifruit test diet) than the remaining proteins (e.g. 119–357 min for the green kiwifruit test diet).

Discussion

Actinidin is a cysteine protease present in several varieties of kiwifruit. Actinidin has been shown to increase the rate and extent of both gastric and intestinal digestion of different dietary proteins, including beef muscle, in both in vitro ( Reference Kaur, Rutherfurd and Moughan 2 ) and in vivo ( Reference Rutherfurd, Montoya and Zou 3 ) studies with rats. Beef muscle protein was chosen here to explore the effect of dietary actinidin on other factors such as the SER and the kinetics of gastric hydrolysis of proteins in the growing pig during a 7 h postprandial period. The pig was chosen as an animal model for humans, given the close similarities in the physiology of digestion between the two species( Reference Moughan and Rowan 9 , Reference Rowan, Moughan and Wilson 29 ). Determination of the gastric hydrolysis or disappearance of proteins was based on the extracted soluble proteins, and insoluble proteins would not have been considered. The SDS–PAGE technique is a useful method for estimating the gastric disappearance of individual proteins within a complex protein mixture( Reference Rutherfurd, Montoya and Zou 3 ); however, it is a semi-quantitative method, and may overestimate the gastric disappearance of a protein as only a single bond break is required for the protein (original MW) to disappear from the gel and reappear as two new separate protein bands. However, in the SDS–PAGE gels of the beef muscle shown here, new bands were not observed. A protein-free diet was used to determine the endogenous proteins present in the gastric chyme and, as expected, few endogenous protein bands were present. Some of the observed endogenous proteins had MW similar to some of the beef muscle proteins (57, 46 and 36 kDa). For the beef muscle proteins desmin, 45 kDa and tropomyosin-β-chain, gastric disappearance was corrected accordingly. For the remaining beef muscle proteins, no correction was necessary. Titanium dioxide is frequently used in nutrition studies as a solid-phase marker for determining nutrient flows. In the present study, titanium dioxide represented both the solid and liquid phases. The latter is a caveat of the study as the liquid phase may have a faster SER than the solid phase. Nevertheless, we assumed that this potential difference was small and constant across the treatments.

In the present study, some ‘actinidin activity’ was detected in the chyme of pigs fed the protein-free diet and the negative control diets, where no actinidin was present. The determined activity found in these samples may be explained by a proteolytic effect of pepsin on the substrate Cbz-l-Lys-o-nitrophenol hydrochloride, suggesting that the method is not specific to actinidin, and the determined values for actinidin activity should be viewed as approximations. Surprisingly, actinidin activity in the chyme was about double that found in the diets. Due to the low specificity of the method to determine actinidin activity in the chyme, as described above, this increase could be explained by the activation of the pro-enzyme form of actinidin by either HCl, actinidin itself or pepsin in the chyme. Significant amounts of cysteine proteases are known to be present as the pro-enzyme( Reference Turk, Podobnik, Turk, Hopsu-Havu, Jarvinen and Kirschke 30 ). This increase in activity could also be explained by the conversion of pepsinogen to pepsin, which normally occurs in the stomach in the presence of HCl and pepsin( Reference Richter, Tanaka and Yada 31 ). Such conversion could be enhanced by the presence of cysteine proteases, which are known to activate pro-enzymes( Reference Turk, Podobnik, Turk, Hopsu-Havu, Jarvinen and Kirschke 30 , Reference Dubey, Pande and Singh 32 ).

The reduction in actinidin activity at 7 h postprandially is most probably explained in that stomach emptying was largely complete by 7 h (only 10 % of the DM remained in the stomach at this time), and therefore most of the actinidin would have exited the stomach. The lower level of actinidin activity in the chyme for the green kiwifruit test diet compared with the gold kiwifruit positive control diet may potentially be explained by actinidin being entrapped in the cell walls of green kiwifruit that differs from the gold kiwifruit positive control diet to which purified actinidin was added. Further experiments focusing on the gastric activation of actinidin may be warranted.

Gastric emptying is a complex process in which several factors including meal size( Reference Kwiatek, Menne and Steingoetter 33 ), diet composition( Reference Brener, Hendrix and McHugh 34 , Reference French and Read 35 ) and plasma hormone levels( Reference Mearadji, Masclee and Onkenhout 6 , Reference Feinle, Christen and Grundy 7 , Reference Gregory, McFadyen and Rayner 36 ) may play a role in its control. For example, the release of proteins and lipids into the duodenum modulates the secretion of the hormone cholecystokinin, which in turn reduces gastric motility and stomach emptying( Reference Mearadji, Masclee and Onkenhout 6 , Reference Feinle, Christen and Grundy 7 , Reference Schwizer, Borovicka and Kunz 37 ). The presence of actinidin (in the form of fresh green kiwifruit pulp or purified actinidin added to the gold kiwifruit pulp) in the diets increased the rate of stomach emptying of DM and proteins during the first 3 h postprandially.

The effect of actinidin on accelerating stomach emptying has also been observed in rats fed with a beef muscle protein diet, and determined using a magnetic resonance spectroscopy approach( Reference Montoya, Hindmarsh and Boland 38 ). During the 2·5 h period after feeding the rats, 41 % of the stomach contents had emptied for a beef muscle protein diet containing green kiwifruit. However, a lesser amount (32 %) had emptied from the stomach for an equivalent beef muscle protein diet containing actinidin-devoid gold kiwifruit.

The presence of dietary actinidin in a beef muscle protein diet increased the rate of hydrolysis of the total beef muscle protein during the first 5 h postprandially (based on the degree of hydrolysis) and the rate of disappearance of the high-MW proteins (MHC, β-actinin, α-actinin, desmin, actin, tropomyosin-β-chain and tropomyosin-α-chain and unidentified proteins with MW of 88, 45 and 43 kDa) for the first 3 h. In contrast, there was much less effect of dietary actinidin on the lower-MW proteins ( < 34 kDa). The extent of gastric disappearance varied markedly among the individual beef muscle proteins probably as a result of inter-protein differences at the structural level (e.g. different amino acid sequences and tertiary structure leading to different susceptibilities to proteases). After 5 h post-ingestion, actinidin did not further enhance gastric disappearance for most of the beef muscle proteins. It is likely that the hydrolytic action of pepsin and actinidin on the digestion of the beef muscle proteins was essentially complete (as judged by the method used in the present study) 5 h postprandially. The mean disappearance values across all the proteins and all the treatments after 5 h were between 75 and 83 %.

A high correlation between gastric protein digestion and gastric DM retention has been observed in rats fed different protein sources (r 0·69)( Reference Montoya, Hindmarsh and Boland 38 ). Thus, the present results may infer that the faster stomach emptying observed for the pigs fed with diets containing actinidin is mainly due to greater gastric digestion of the beef muscle proteins by actinidin rather than by a hormone-mediated change in gastric motility, as has been described previously for cholecystokinin( Reference Mearadji, Masclee and Onkenhout 6 , Reference Feinle, Christen and Grundy 7 , Reference Schwizer, Borovicka and Kunz 37 ). The greater gastric hydrolysis and more rapid stomach emptying of the beef muscle proteins when pigs were fed a diet containing actinidin suggest a higher release of peptides and amino acids into the duodenum, which may result in a more rapid digestion and absorption in the small intestine with implications for the rates of amino acid delivery to the cells. The coordination of nutrient delivery (including amino acids) is an important, but often overlooked, factor for utilisation( Reference Rehner, Heil and Auge 4 , Reference Mahé, Roos and Benamouzig 8 , Reference Boirie, Dangin and Gachon 39 ). Moreover, it is possible that actinidin, consumed as part of whole kiwifruit, may be a means by which dietary amino acid delivery to the cells can be modulated. This hypothesis warrants investigation.

In conclusion, the presence of dietary actinidin in a beef muscle protein-based diet significantly enhanced the gastric disappearance of the higher-MW proteins (>32 kDa) during the first 3 h postprandially, but had little effect on the smaller proteins ( < 32 kDa). This enhancement in disappearance correlated with an increase in the SER of both DM and proteins during the same period. After 5 h postprandially, dietary actinidin had little further effect on the gastric hydrolysis of the beef muscle proteins and on stomach emptying. The implications of these findings are that actinidin assists the gastric digestion of meat protein and may potentially assist to reduce the feeling of stomach fullness experienced after consuming high-meat diets. The effect of dietary actinidin on the gastric hydrolysis of beef muscle proteins may also have an impact on the rate at which amino acids are absorbed from the gastrointestinal tract.

Supplementary material

To view supplementary material for this article, please visit http://dx.doi.org/10.1017/S0007114513003401

Acknowledgements

We acknowledge Stuart Saigeman for running the animal trial and ZESPRI International Limited for supplying the kiwifruit.

The present study was funded by ZESPRI International Limited. ZESPRI International Limited had no role in the design, analysis or writing of this article other than the contribution described in the authorship for L. N. D.

C. A. M., S. M. R., M. J. B. and P. J. M. were responsible for planning the study, which was accepted by L. N. D. before being conducted. C. A. M. and T. D. O. were responsible for conducting the experiment in pigs. A. S. P. was responsible for preparing and analysing the SDS–PAGE gels. Additionally, C. A. M. performed the statistical analysis and prepared the first draft of the manuscript that was revised by S. M. R., L. N. D., M. J. B. and P. J. M. All authors read and approved the final manuscript.

L. N. D. is employed by ZESPRI International Limited. There are no other conflicts of interest.

References

1 Boland, M (2013) Kiwifruit proteins and enzymes: actinidin and other significant proteins. Adv Food Nutr Res 68, 5980.CrossRefGoogle ScholarPubMed
2 Kaur, L, Rutherfurd, SM, Moughan, PJ, et al. (2010) Actinidin enhances gastric protein digestion as assessed using an in vitro gastric digestion model. J Agric Food Chem 58, 50685073.Google Scholar
3 Rutherfurd, SM, Montoya, CA, Zou, ML, et al. (2011) Effect of actinidin from kiwifruit (Actinidia deliciosa cv. Hayward) on the digestion of food proteins determined in the growing rat. Food Chem 129, 16811689.CrossRefGoogle Scholar
4 Rehner, G, Heil, M, Auge, M, et al. (1985) Effect of proteins on availability of zinc. I. Gastrointestinal transit time of casein and whey protein and zinc absorption in weaned rats. Z Ernährungswiss 24, 245255.CrossRefGoogle ScholarPubMed
5 Hara, H, Nishikawa, H & Kiriyama, S (1992) Different effects of casein and soyabean protein on gastric emptying of protein and small intestinal transit after spontaneous feeding of diets in rats. Br J Nutr 68, 5966.Google Scholar
6 Mearadji, B, Masclee, AA, Onkenhout, W, et al. (2001) Effect of intraduodenal and intravenous amino acids on proximal gastric motor function in man. Dig Dis Sci 46, 3845.CrossRefGoogle ScholarPubMed
7 Feinle, C, Christen, M, Grundy, D, et al. (2002) Effects of duodenal fat, protein or mixed-nutrient infusions on epigastric sensations during sustained gastric distension in healthy humans. Neurogastroenterol Mot 14, 205213.CrossRefGoogle ScholarPubMed
8 Mahé, S, Roos, N, Benamouzig, R, et al. (1996) Gastrojejunal kinetics and the digestion of [15N] β-lactoglobulin and casein in humans: the influence of the nature and quantity of the protein. Am J Clin Nutr 63, 546552.Google Scholar
9 Moughan, PJ & Rowan, AM (1989) The pig as a model animal for human nutrition research. Proc Nutr Soc 14, 116123.Google Scholar
10 Baer, DJ, Rumpler, WV, Miles, CW, et al. (1997) Dietary fibre decreases the metabolisable energy content and nutrient digestibility of mixed diets fed to humans. J Nutr 127, 579586.Google Scholar
11 Bublin, M, Mari, A, Ebner, C, et al. (2004) IgE sensitisation profiles toward green and gold kiwifruits differ among patients allergic to kiwifruit from 3 European countries. J Allergy Clin Immunol 114, 11691175.CrossRefGoogle ScholarPubMed
12 Henare, SJ, Rutherfurd, SM, Drummond, L, et al. (2012) Digestible nutrients and available (ATP) energy contents of two varieties of kiwifruit (Actinidia deliciosa and Actinidia chinensis). Food Chem 130, 6772.Google Scholar
13 Kniel, KE, Sumner, SS, Lindsay, DS, et al. (2003) Effect of organic acids and hydrogen peroxide on Cryptosporidium parvum viability in fruit juices. J Food Protect 66, 16501657.Google Scholar
14 Food and Drug Administration (2003) Department of Health and Human Service. 21 CFR Part 356. Fed Reg 68, 32232–32287. Google Scholar
15 Material Safety Data Sheet (2011) Hydrogen peroxide 30 %. Science Lab.com. Chemicals and Laboratory Equipment. http://www.sciencelab.com/msds.php?msdsId = 9924299 (accessed accessed November 2011). Google Scholar
16 National Research Council (1998) Nutrient Requirements of Swine, 10th revised ed. Washington, DC: National Academy of Sciences–National Research Council.Google Scholar
17 Association of Official Analytical Chemists (2007) Official Methods of Analysis, 18th ed. Arlington, VA: AOAC.Google Scholar
18 Prosky, L, Asp, NG, Schweizer, TF, et al. (1988) Determination of insoluble, soluble, and total dietary fibre in foods and food products: interlaboratory study. J Assoc Off Anal Chem Int 71, 10171023.Google Scholar
19 Short, FJ, Gorton, P, Wiseman, J, et al. (1996) Determination of titanium dioxide added as an inert marker in chicken digestibility studies. Anim Feed Sci Technol 59, 215221.CrossRefGoogle Scholar
20 Boland, MJ & Hardman, MJ (1972) Kinetic studies on the cysteine proteinase from Actinidia chinensis . FEBS Lett 27, 282284.Google Scholar
21 Church, F, Swaisgood, H, Porter, DH, et al. (1983) Spectrophotometric assay using o-phthaldialdehyde for determination of proteolysis in milk and isolated milk proteins. J Dairy Sci 66, 12191227.Google Scholar
22 Lopez, S, France, J, Gerrits, WJJ, et al. (2000) A generalized Michaelis–Menten equation for the analysis of growth. J Anim Sci 78, 18161828.CrossRefGoogle ScholarPubMed
23 SAS (2009) User's Guide Statistics. Version 9.2. Statistical Analysis System. Cary, NC: SAS Institute, Inc.Google Scholar
24 Bruin, J (2006) Newtest: Command to Compute New Test. UCLA: Academic Technology Services, Statistical Consulting Group. http://www.ats.ucla.edu/stat/stata/ado/analysis/ (accessed accessed May 2012).Google Scholar
25 Elashoff, JD, Reedy, TJ & Meyer, JH (1982) Analysis of gastric emptying data. Gastroenterology 83, 13061312.Google Scholar
26 Freund, R & Littell, R (2000) SAS System for Regression, 3rd ed. Cary, NC: SAS Publishing.Google Scholar
27 Odunsi, ST, Camilleri, M, Szarka, LA, et al. (2009) Optimizing analysis of stable isotope breath tests to estimate gastric emptying of solids. Neurogastroenterol Motil 21, 706–e38.Google Scholar
28 Milliken, GA & Johnson, DE (1989) Analysis of Messy Data: Volume 2: Nonreplicated Experiments. New York, NY: Van Nostrand Reinhold.Google Scholar
29 Rowan, AM, Moughan, PJ, Wilson, MN, et al. (1994) Comparison of the ileal and faecal digestibility of dietary amino acids in adult humans and evaluation of the pig as a model animal for digestion studies in man. Br J Nutr 71, 2942.Google Scholar
30 Turk, V, Podobnik, M, Turk, B, et al. (1997) Regulation of cysteine proteinase activity by protein inhibitors, zymogen activation and pH. In Proteolysis in Cell Functions, Biomedical and Health Research, vol. 13, pp. 128136 [Hopsu-Havu, VK, Jarvinen, M and Kirschke, H, editors]. Turku: IOS Press.Google Scholar
31 Richter, C, Tanaka, T & Yada, RY (1998) Mechanism of activation of the gastric aspartic proteinases: pepsinogen, progastricsin and prochymosin. Biochem J 335, 481490.CrossRefGoogle ScholarPubMed
32 Dubey, VK, Pande, M, Singh, BK, et al. (2007) Papain-like proteases: applications of their inhibitors. Afr J Biotechnol 6, 10771086.Google Scholar
33 Kwiatek, MA, Menne, D, Steingoetter, A, et al. (2009) Effect of meal volume and calorie load on postprandial gastric function and emptying: studies under physiological conditions by combined fiber-optic pressure measurement and MRI. Am J Physiol Gastrointest Liver Physiol 297, G894G901.Google Scholar
34 Brener, W, Hendrix, TR & McHugh, PR (1983) Regulation of the gastric emptying of glucose. Gastroenterology 85, 7682.CrossRefGoogle ScholarPubMed
35 French, SJ & Read, NW (1994) Effect of guar gum on hunger and satiety after meals of differing fat content: relationship with gastric emptying. Am J Clin Nutr 59, 8791.Google Scholar
36 Gregory, PC, McFadyen, M & Rayner, DV (1995) Control of gastric emptying in the pig: influence of cholecystokinin, somatostatin and prokinetic agents. Exp Physiol 80, 159165.CrossRefGoogle ScholarPubMed
37 Schwizer, W, Borovicka, J, Kunz, P, et al. (1997) Role of cholecystokinin in the regulation of liquid gastric emptying and gastric motility in humans: studies with the CCK antagonist loxiglumide. Gut 41, 500504.Google Scholar
38 Montoya, CA, Hindmarsh, JP, Boland, MJ, et al. (2011) Actinidin-containing kiwifruit extract enhances the stomach protein digestion of some dietary proteins in rats. In Proceedings of the Nutrition Society of Australia, vol. 35, p. 83 .Google Scholar
39 Boirie, Y, Dangin, M, Gachon, P, et al. (1997) Slow and fast dietary proteins differently modulate postprandial accretion. Proc Natl Acad Sci 94, 1493014935.Google Scholar
Figure 0

Table 1 Ingredient and nutrient compositions of the experimental diets (g/kg DM)

Figure 1

Table 2 Actinidin activity (μmol-o-nitrophenol/min per g DM) in the experimental diets and the stomach chyme of growing pigs fed the diets* (Mean values with their pooled standard errors, n 30 for diet, n 6 per chyme)

Figure 2

Table 3 Gastric relative retention and gastric retention parameters of DM and nitrogen in growing pigs fed the experimental diets* (Mean values with their pooled standard errors, n 6)

Figure 3

Table 4 True gastric hydrolysis of dietary proteins in growing pigs fed the experimental diets* (Mean values with their pooled standard errors, n 6)

Figure 4

Fig. 1 SDS–PAGE analysis of a beef muscle protein diet and stomach chyme of growing pigs sampled at 0·5, 1, 3, 5 and 7 h after consuming the diets: (a) green kiwifruit test and green kiwifruit negative control or (b) gold kiwifruit positive control and gold kiwifruit negative control. The amount of the sample loaded in each lane was normalised based on the DM per ml of Tricine sample buffer (10 mg/ml). The protein bands were identified as follows: a, myosin heavy chain; b, β-actinin; c, α-actinin; d, 88 kDa protein; e, desmin; f, 45 kDa protein; g, 43 kDa; h, actin; i, tropomyosin-β-chain; j, tropomyosin-α-chain; k, myosin light chain 1; l, troponin I; m, myosin light chain 2. MW, molecular weight.

Figure 5

Table 5 True gastric disappearance and time to reach half of the gastric true disappearance (TD50) of proteins in growing pigs fed the experimental diets (Mean values with their pooled standard errors, n 6)

Figure 6

Fig. 2 Fitted curves(22) of gastric disappearance for myosin heavy chain in growing pigs fed the green kiwifruit negative control (□), green kiwifruit test (■), gold kiwifruit negative control (Δ) and gold kiwifruit positive control (▲) diets. The pooled standard error of the fitted curves was 4·46 %.

Supplementary material: PDF

Montoya et al. Supplementary Material

Table

Download Montoya et al. Supplementary Material(PDF)
PDF 36.7 KB