INTRODUCTION
Reducing crude protein (CP) might be effective to mitigate environmental and economic problems in swine production. Swine producers are able to lower the level of dietary CP when the diets satisfy the pig requirement for total nitrogen and essential amino acids (AA) [1]. Soybean meal is commonly added to corn-soybean meal feed to increase the lysine content, as corn contains lower levels of lysine [2]. However, excessive protein intake can lead to undigested AA and nitrogen being excreted in feces, resulting in decreased nitrogen utilization and protein fermentation in the hindgut, which can negatively impact intestinal health. Therefore, there is a growing trend towards reducing dietary CP levels and supplementing synthetic AA to meet the pig’s nutritional needs [3–6].
Recent studies have shown that reducing dietary CP levels by 4% with limited AAs, such as lysine, tryptophan, threonine, and methionine, does not affect the growth performance of growing and finishing pigs [7–9]. However, other studies have shown that reducing dietary CP levels by 4% with limited AA supplementation can have a negative impact on growth performance, particularly in younger pigs [10]. Additionally, reducing dietary CP levels by 5% can impair the growth performance of growing pigs due to essential AA deficits [11]. Dietary CP levels have also been found to affect microbial communities, with low levels decreasing pathogen activity in the intestine without affecting beneficial bacteria. Moreover, reducing dietary CP levels and supplementing synthetic AA may decrease odor emission by reducing branched-chain volatile fatty acid (VFA) metabolism in the hindgut [12]. In light of these findings, this study aimed to evaluate the effects of low CP levels with essential AA supplementation on the growth performance, nutrient digestibility, microbiota, and VFA composition of growing pigs.
MATERIALS AND METHODS
A total of 160 growing pigs (Landrace × Yorkshire × Duroc [LYD]; average initial body weight 16.68 ± 0.12 kg) were randomly allotted to one of the four treatments on the basis of initial body weight. A randomized complete block design was used to conduct this study in the Research Center of Animal Life Sciences at Kangwon National University. There were ten pigs per replicate, with four replicates for each treatment. The treatments were CON (17.2% dietary CP level), low protein (LP)-1.10 (15.7% dietary CP level + 1.10% Lys level), LP-1.15 (15.7% dietary CP level + 1.15% Lys level), LP-1.20 (15.7% dietary CP level + 1.20% Lys level). The experimental diets were supplemented for 52 days in three phases; phase 1 (day 0–14), phase 2 (day 15–28), phase 3 (day 29–42). The pigs were grouped in partially slatted concrete floor pens 2.80 m × 5.00 m in size. All pens contained a self-feeder and nipple drinker to allow ad libitum access to feed and water. The diets were formulated to provide all the nutrients that met or exceeded the nutrient requirements listed in the NRC [13], with the exception of Ca (Table 1).
1) Supplied per kilogram of diet: 45 mg Fe; 0.25 mg Co; 50 mg Cu; 15 mg Mn; 25 mg Zn; 0.35 mg I; 0.13 mg Se.
The body weights of all the pigs were measured at the end of each phase. The amount of feed supplemented was measured throughout the experimental period calculate the average daily feed intake (ADFI). The average daily gain (ADG), ADFI, and gain-to-feed ratio (G/F) were calculated at the end of each phase.
The effects of dietary CP and AA supplementation on nutrient digestibility were determined as follows: pigs were fed a diet containing 2.5 g Cr2O3/kg for seven days before sampling, and fecal samples were collected for four days before sampling. In this trial, we evaluated dry matter (DM), gross energy (GE), and CP digestibility. Prior to fecal sample collection, the floor was cleaned to avoid contamination, and fecal samples were retrieved and placed in vacuum-sealed plastic bags. Fecal samples were stored in a freezer at −20°C to preserve the state until analyzed. Samples were thawed, dried at 60°C for 72 h in a forced-air oven, grounded in a 1-mm screen Wiley mill (Thomas Model 4 Wiley Mill; Thomas Scientific, Swedesboro, NJ, USA), and analyzed to calculate digestibility. Each fecal sample was analyzed in quadruplicate for DM (Method 930.15), CP (Method 990.03) according to AOAC methodology [14]. A bomb calorimeter (Model 1261, Parr Instrument, Moline, IL, USA) was used to analyze gross energy.
At the end of each phase, pigs were selected based on their average body weight for each treatment, and samples were collected via gentle rectal massage. The samples were immediately kept in liquid nitrogen and moved to a deep freezer at −80°C until analysis. DNA was extracted using the QIAamp Fast DNA Stool Mini Kit (cat. No. 51604 2016, QIAGEN, Hilden, Germany). The fecal sample (200 mg) was weighed in a 2 mL centrifuge tube and kept on ice. To ensure the highest possible DNA concentration in the final eluate, 1 mL of InhibitEX Buffer was added to each sample and vortexed continuously for 1 min until the sample was thoroughly homogenized. The samples were incubated in a 70°C water bath for 5 min and vortexed for 15 s to achieve consistent lysis. The samples were then centrifuged at 20,000×g and 14,000 rpm for 1 min to pellet the feces. Secondly, 25 µL of proteinase K and 600 µL of the first sample`s supernatant were combined in a fresh 2 mL centrifuge tube. Next, 600 µL of Buffer AL was added and vortexed for 15 s to create a homogeneous solution that was incubated for 10 min at 70°C and centrifuged briefly to eliminate drops inside the tube lid. The lysate was mixed with 600 µL of ethanol (96%) and vortexed. In the QIAamp spin column, the lysate (600 µL) was added to a QIAamp spin column and centrifuged at 20,000 × g” and 14,000 rpm for 1 min. The QIAamp spin column was moved to a new collection tube, and the former tube was removed. QIAamp spin column was carefully opened, and 500 µL of Buffer AW1 was added and centrifuged at 20,000×g and 14,000 rpm for 1 min. The QIAamp spin column was stored in a new collection tube. Subsequently, 500 µL of Buffer AW1 was added to the QIAamp spin column and centrifuged for 3 min at 20,000×g and 14,000 rpm. Finally, the QIAamp spin column was moved into a new 2 mL centrifuge tube, and 200 µL of Buffer ATE was mixed directly onto the QIAamp membrane, kept for 1 min at room temperature, then centrifuged at 20,000×g and 14,000 rpm for 1 min to elute the DNA, which was then later quantified using a spectrophotometer. The levels of fecal microflora, such as Lactobacillus spp., Bifidobacterium spp., Clostridium spp., and Escherichia coli, were estimated using the methodology of Tajudeen et al. [15].
Samples from pigs that were chosen based on the average body weight of each pen to minimize errors were collected (d 14, 28, and 42) directly through rectal massage to estimate VFA concentrations in feces. Fecal samples were immediately stored in collection tubes and placed on ice. VFA concentrations in the feces were estimated using gas chromatography (HP 6890 Plus, Hewlett Packard, Houston, TX, USA) according to the method of Jeon et al. [16].
The collected data from this experiment were analyzed using the Analysis of Variance (ANOVA), implemented through the General Linear Model (GLM) procedure of SAS (version 9.2, SAS Institute, Cary, NC, USA). For assessing growth performance, the initial body weight was employed as a covariate, but was omitted from the model if it proved insignificant. Each pig served as an experimental unit for parameters such as growth performance, feed consumption, nutrient digestibility, blood electrolyte equilibrium, and bone measurements. The Tukey mean comparison test was utilized for treatment mean separation, with a significance level set at p < 0.05. Any probability below 0.1 was recognized 25 as a trend.
RESULTS
The effects of dietary CP and AA levels on growth performance are shown in Table 2. Pigs fed the control and LP-1.20 diet showed greater final body weight than those fed the LP-1.1 diet. Although ADG, ADFI, and G/F did not differ in phases 2 and 3, ADG and G/F were significantly greater in the CON and LP-1.20 in phase 1. However, ADFI showed no difference during the experimental period.
The effects of dietary CP and AA levels on nutrient digestibility are presented in Table 3. DM, metabolizable (ME), and CP digestibility were calculated to evaluate the effects of CP and AA level in the diet. In phase 1, CP digestibility was higher in the LP-1.2 than LP-1.1. However, there was no significant difference between treatments. In this study, DM, ME, and CP digestibility showed no significant differences among the treatments in the phase 2 and 3.
The effects of dietary CP and AA levels on the microflora quantity are shown in Table 4. The content of Lactobacillus spp., Bifidobacterium spp., E.coli, Clostridium in the feces were analyzed to evaluate the effects of CP and AA level in the diet. Although Lactobacillus spp. was increased and Clostridium was decreased in the LP-1.2 than LP-1.1 in phase 1, there was no significant difference among the treatments. In the phase 2 and 3, the content of microflora didn't show difference among the various treatments.
The effect of dietary CP and AA level on VFA is shown in Table 5. Isobutyric acid and isovaleric acid compositions of LP treatments were lower than those of CON in phase 2. The total branched-chain fatty acid composition was significantly lower in the LP treatment in phases 1 and 2. However, there were no significant differences among the treatments in phase 3.
DISCUSSION
The present study investigated the effects of varying levels of dietary CP and AA supplementation on the growth performance, nutrient digestibility, microbiota, and VFA concentrations in growing pigs. The results indicate that reducing the CP level by 1.5% with a balanced supply of essential AA did not significantly affect the growth performance of pigs, but it did lead to a significant reduction in some branched-chain fatty acids. According to Kerr et al. [3], a low-CP diet, reduced by 2%–4%, with the addition of a limited amount of AA, such as lysine, threonine, methionine, and tryptophan, is a viable option for pigs. However, an excessive decrease in dietary CP may hinder pig growth performance [17–19]. In our study, pigs that consumed low-protein diets and received additional essential AA, such as Lys, Thr, and Met, demonstrated growth performance comparable to that of the CON group during the trial period.
This study found that pigs fed the LP diet had poorer ADG and feed efficiency in phase 1 compared to those fed the CON diet, but no significant differences were observed in phases 2 and 3. These results suggest that pigs require a higher nitrogen intake for protein deposition, and the requirements for the first five essential AA are less well-defined in the early growth phase compared to the later phases. This finding is consistent with previous studies that have shown pigs to be more sensitive to dietary CP levels during the growing phase than the finishing phase [20,21]. However, nitrogen retention was observed during the finishing phase [22]. The LP diet contained a higher proportion of corn than the CON diet, resulting in an increased availability of starch, which may explain the compensatory growth observed in the finishing phase. Starch is known to be more efficient for fat deposition than protein [23]. No significant differences in growth performance were observed between the dietary treatments in each growth phase. However, it is possible that the nutrient supply, particularly non-essential AA in LP diets, may be insufficient for protein deposition in rapidly growing pigs, resulting in a lower growth rate compared to pigs fed high-protein diets [24].
Although this study reduced the CP concentration in pig feed by decreasing the soybean meal content, nutrient digestibility was not affected when dietary CP was decreased to 1.5%. The main factors affecting protein digestibility are the levels and balance of essential AA and animal requirements [8]. In this study, the levels (%) of Lys, Met, and Thr were similar for different CP treatments, indicating that the levels of limited AAs were not affected by reducing CP levels. The digestibility of CP remained unchanged despite the reduction in dietary CP levels. When the limiting AA levels are constant, a decrease in CP levels can potentially lead to a more balanced AA composition compared to elevated CP levels. Ball [25] discovered a reduction in energy digestibility as CP levels decreased in diets featuring 6.9 g/kg of readily available lysine. Zervas and Zijlstra [26] echoed this finding, attributing it to the diminished fiber content in diets rich in protein [27]. The influence of CP level on nutrient digestibility warrants consideration since a decrease in digestibility could lower the slurry DM concentration, subsequently resulting in a surge in slurry output [28].
Portune et al. [29] showed a significant correlation between gut microbiota and the metabolism of dietary proteins. Undigested proteins in the gut provide nitrogen for saccharolytic bacterial growth and AA for fermentation by asaccharolytic species. The mammalian intestine harbors a multitude of microbial strains, numbering over 1014 microbial cells. These microorganisms play pivotal roles in the host’s physiology and metabolism. The fermentation process of undigested dietary proteins can foster the growth of protein-fermenting bacteria, thereby suggesting that the origin, quality, and volume of dietary protein can have a bearing on microbial communities. Research indicates that the level of dietary CP exerts a more profound effect on the composition of gut microbiota compared to its origin [30]. In the case of weaned piglets, a decrease in dietary CP led to a reduction in the Clostridium count, however, it didn’t affect the total bacteria, Lactobacilli, Enterobacteria, and Bacteroides. Nonetheless, alterations in the dietary CP content didn’t significantly impact bacterial communities in any part of the intestine under normal physiological circumstances, as the microbiota possesses a certain degree of adaptability. The outcomes of studies examining the influence of dietary CP levels on the microbiota composition are inconsistent, possibly due to the limitations of conventional culture-dependent or low-throughput culture-independent methodologies.
Canh et al. [31] stated that fermentable non-starch polysaccharides are the primary dietary components that affect the VFA concentrations in manure. Most VFAs in manure consist of short straight-chain VFAs such as acetic, propionic, and butyric acids, which account for 91% of the total VFA content. This was consistent with the findings of Otto et al. [32] and Le et al. [33]. They proposed that branched-chain VFAs are only produced during protein metabolism, which could explain the slight increase in isobutyric and isopentanoic acid concentrations in manure as dietary CP levels increased from 12% to 18%, although these changes were not statistically significant.
In summary, a reduction of 1.5% in protein levels by 1.5% with a balance of essential AA did not significantly affect on the growth of pigs; however, it did result in a significant reduction in some branched-chain fatty acids. In the case of lower protein diets, supplementation with AA balance led to increased body weight gain during the 16–50 kg phase, whereas not supplementing with AA during the same phases led to reduced growth performance. In this study, the nutrient digestibility and microbiota of pigs fed diets with different levels of CP were not affected. These results imply that a low-protein diet may be a viable choice when the AA composition is well-balanced.