1. Introduction

Under modern intensive breeding conditions, high breeding density, pathogenic microorganisms, temperature, and humidity factors can induce immune stress in broilers, which results in damage to growth performance and the intestinal barrier in poultry [1,2]. LPS is a common endotoxin and is considered to be one of the most potent immune activators [3]. Previous studies demonstrated that intrabitoneal injection of LPS in broilers could seriously compromise the integrity of the intestinal mucosal barrier, elevate inflammatory factors, alter intestinal flora, and consequently impact growth performance [4,5]. LPS has been shown to activate the NF-κB signaling pathway by binding to the TLR4 receptor on the cell surface to generate a number of pro-inflammatory cytokines [6]. Notably, natural plant extracts contain a variety of nutrients, which can enhance the growth performance and feed utilization of livestock and poultry [7]. Therefore, it is crucial to develop a natural and botanic extract as a feed additive to ameliorate the immune stress of poultry and maintain intestinal health.

Sea-buckthorn (Hippophae rhamnoides L.) is a versatile medicinal and edible plant known for its strong adaptability and high yield [8]. It has been reported to possess typical physiological functions, including anti-inflammatory properties [9], antioxidant activity [10], immunomodulatory effects [11], and lipid-lowering capabilities [12]. Studies have indicated the beneficial impact of sea-buckthorn leaves or extracts on growth performance, feed efficiency, and the development of immune organs in Turkey poults, with long-term feeding being deemed safe and reliable [13]. Sea-buckthorn flavonoids (SF) are the major active components extracted from the fruits, roots, and leaves of sea-buckthorn. They may serve as natural feed additives, enhancing growth performance, rumen fermentation, and serum antioxidant capacity in lambs [14]. Furthermore, evidence suggests that key components of sea-buckthorn flavonoids such as quercetin, isorhamnetin, and kaempferol could alleviate inflammation challenged by LPS in mice [15]. Studies have shown that these compounds fight inflammation through different mechanisms [16,17,18]. It is currently attracting attention from researchers due to its extensive physiological functions. However, there is limited data available regarding the regulatory effects of SF on inflammatory responses, the intestinal barrier, and the microbiota in broilers under LPS-challenged immune stress. The present investigation aims to explore the effects of SF on the performance, serum inflammation, intestinal barrier, and microbiota of LPS challenge broilers via the LPS challenge immune stress model.

2. Materials and Methods

2.1. Experimental Design

A total of 288 healthy one-day-old yellow-feathered male broilers (32.94 g ± 0.10 g, Tang Renshen Group Co., Ltd., Zhuzhou, China) were randomly assigned to 4 groups, including the CON group (basal diet + saline), the LPS group (basal diet+ LPS), the SF group (basal diet + 1000 mg/kg SF + saline), and the SF + LPS group (basal diet + 1000 mg/kg SF + LPS), with 6 replicates of 12 broilers each. SF (purity ≥ 30%) was provided by Baoji Fangsheng Biological Development Co., Ltd. (Xi’an, China) and fed from 1 day of age; the dose of SF supplemented was referred to in previous studies [19]. LPS (Escherichia coli O55: L2880) was obtained from Sigma Aldrich (St. Louis, MO, USA). LPS was dissolved in saline, and 500 μg LPS/mL was prepared before use. LPS-challenged broilers were intraperitoneally injected with 500 μg LPS /kg on 16, 18, and 20 d; non-LPS-challenged broilers were injected with an equal amount of saline, and the frequency and dosage of LPS administration were selected based on previous studies [20,21]. The feeding trial lasted for 20 days. The basal diet (Table 1) was formulated based on the feeding standards of chickens (NY/T33-2004). All broilers were housed on the net floor (cage size: 2.5 m × 1.5 m), which had free access to feed and water. The artificial continuous lighting system was used, with temperatures ranging from 33 °C to 34 °C in the first week and 27 °C to 31 °C in the second week. Heating was applied depending on the specific temperature conditions. Natural ventilation in chicken coops. Maintain a relative humidity between 55 and 65%.

2.2. Sample Collection

At the age of 21 days, one healthy bird with similar weight was selected from each replicate (fasting 8–12 h in advance, and live weight was recorded) and euthanized. Blood was collected using common tubes (Liuyang Sanli Medical Science and Technology Development Co., Ltd., Liuyang, China), centrifuged at 3500 r /min at 4 °C for 10 min, taken as the supernatant, and stored in −20 °C freezers. Open the abdominal cavity; the whole intestinal segment was removed and separated (duodenum, jejunum, and ileum). The middle segment was taken about 2 cm and fixed in 4% paraformaldehyde solution (Wuhan Kanos Technology Co., Ltd., Wuhan, China), scraped portions of the mucosa, and stored in −80 °C freezers. Appropriate amounts of cecal chyme were collected and stored in the refrigerator at −80 °C.

2.3. Index Determination Method

2.3.1. Measurement of Growth Performance

Initial weight (IW), final weight (FW), and feed consumption of each cage were recorded to calculate the average daily gain (ADG), average daily feed intake (ADFI), and feed-to-gain ratio (FCR) in the non-LPS challenged period and LPS challenged period.

2.3.2. Determination of Serum Indicators

The concentrations of interleukin-1β (IL-1β), interleukin-2 (IL-2), interleukin-10 (IL-10), tumor necrosis factor-α (TNF-α), corticosterone (CORT), D-lactate (D-LA), and endotoxin were determined by ELISA kits. The kits were purchased from Jiangsu Enzyme-Free Industrial Co., Ltd. (Yancheng, China), as described by Cheng et al. [22].

2.3.3. Gut Histomorphological Analysis

The duodenum, jejunum, and ileum samples were removed from a 4% paraformaldehyde fixing solution, dehydrated and embedded with paraffin, and cut into 5 μm slices, as described by Chang et al. [23]. Villi height (VH) and crypt depth (CD) were measured by optical microscopy in combination with software (Image Analysis 1.6.1) after staining with hematoxylin eosin (HE), magnifying 40×, and calculating the ratio of villus height to crypt depth (V/C) from the results. Six good villi and crypts were selected from each section for measurement, and the average value was taken.

2.3.4. Gene Expression Using Quantitative Real-Time PCR

Total RNA was extracted from jejunal mucosal tissue samples using AG reagents (Hangzhou Aikerui Biotechnology Co., Ltd., Hangzhou, China). RNA integrity was evaluated by agarose gel. and RNA concentration and purity were measured by a Nanodrop ND-2000 spectrophotometer (Thermo Scientific, Ottawa, ON, Canada). Reverse transcribed into cDNA using AG reagents (Hangzhou Aikerui Biotechnology Co., Ltd., Hangzhou, China). All primers (Table 2) were purchased from Changsha Biotechnology Co., Ltd. Real-time quantitative PCR detection by the SYBR Green PCR kit (Hangzhou Aikerui Biotechnology Co., Ltd., Hangzhou, China) in CFX Connect real-time PCR detection system, measured β-actin, Zonula occludens-1 (ZO-1), Occludin, Claudin-1, MUC-2, Toll-like receptor 4 (TLR4), myeloid differentiation primary response 88 (MyD88), and nuclear factor kappa B (NF-κB) relative mRNA expression levels. Results were calculated using the 2^−ΔΔCT method, as described by Xing et al. [24].

2.3.5. 16S rRNA Sequencing

Genomic DNA was extracted using a commercial kit (Qiagen, Hilden, Germany). The 16S rRNA was amplified by 338F (ACTCCTACGGGAGGCAGCAG) and 806R (GGACTACHVGGGTWTCTAAT) primers, then sequenced using Illumina. Bioinformatics analysis was performed using the online platform (https://cloud.majorbio.com, accessed on 11 September 2023) provided by Shanghai Majorbio Bio-Pharm Technology Co. Ltd. (Shanghai, China).

2.4. Statistical Analysis

All data were carried out using the Shapiro-Wilk test, analyzed by two-way ANOVA, and then Duncan multiple comparisons were performed with IBM SPSS statistical software (26.0 version, Chicago, IL, USA). The main effects include the LPS challenge and SF treatment, as well as the interactions between LPS and SF. Data were expressed as mean ± standard error of the mean (SEM). Values of p < 0.05 were regarded as statistically remarkable.

3. Results

3.1. Growth Performance

The growth performance results were presented in Table 3. There was no remarkable difference in growth performance between broilers fed with SF and without SF (p > 0.05) before the LPS challenge (1–15 days old). However, LPS lowered ADG, ADFI, and FW (p < 0.05) and increased FCR (p < 0.05) during the LPS challenge (16–20 days old) when compared with that of the control. SF supplementation significantly enhanced ADG and FW (p < 0.05), and the ADFI presented a tendency to increase (0.05 < p < 0.1), but the FCR had no significant effect (p > 0.05). However, there was no remarkable interaction between SF and LPS on the growth performance of broilers (p > 0.05). The details were presented in Table 4.

3.2. Serum Inflammation

As presented in Figure 1, the LPS challenge remarkably elevated the serum concentration of IL-1β, IL-2, TNF-α, and CORT (p < 0.05) and decreased the concentration of IL-10 (p < 0.05) when compared with that of the control. SF supplementation markedly attenuated IL-1β, IL-2, and CORT concentrations and increased IL-10 concentrations (p < 0.05). In addition, the multiple comparisons show that the LPS group had a significantly lower serum concentration of IL-10 and a higher concentration of TNF-α compared with the SF + LPS group (p < 0.05).

3.3. Intestinal Morphology

Severe damage to the intestinal morphology of broilers was observed by the LPS challenge (Figure 2a). As shown in Figure 2, LPS challenge significantly lowered duodenum VH and jejunum V/C (p < 0.05) compared with that of control broilers, while an opposite trend was observed for jejunum and ileum CD (p < 0.05) and tended to lower duodenum and ileum V/C (0.05 < p < 0.1). SF addition significantly reduced jejunal CD (p < 0.05) and elevated duodenal VH, V/C, and jejunal V/C (0.05 < p < 0.1). Multiple comparisons have shown that the duodenal VH of the SF + LPS group was significantly higher than that of the LPS group (p < 0.05). SF supplementation could alleviate these negative effects of broilers in duodenal VH stimulated by LPS.

3.4. Intestinal Permeability and Expression of Jejunal Mucosa-Associated Gene mRNA

As shown in Figure 3, LPS stress significantly increased the endotoxin, D-LA levels in serum, and TLR4, MyD88, NF-κB, and IL-1β relative gene expression in the jejunal mucosa (p < 0.05) when compared with that of the control, and signally decreased the MUC-2, Occludin, and ZO-1 relative gene expression in the jejunal mucosa in broilers (p < 0.05). On the contrary, SF supplementation reduced D-LA level and TLR4, NF-κB, and IL-1β relative gene expression in broilers (p < 0.05) and increased the relative expression of Occludin and ZO-1. However, no major changes in Claudin-1, MUC-2, or MyD88 mRNA expression in the jejunal mucosa were observed after SF supplementation (p > 0.05). There was a remarkable interaction between SF and LPS on D-LA level and IL-1β mRNA expression (p < 0.05). Multiple comparisons have shown that the relative expression levels of D-LA and IL-1β mRNA in the SF + LPS group were significantly lower than those in the LPS group (p < 0.05). SF supplementation could reverse these adverse effects in the serum D-LA level and jejunal mucosa IL-1β relative mRNA expression of broilers stimulated by LPS.

3.5. Gut Microbiota Analysis

At the 97% similarity level, 969,264 high-throughput sequence reads were obtained from all cecal content samples (n = 6), with an average of 40,386 sequences per sample. There were 640 core OTUs shared by the cecal flora in each group, and there were 943 OTUs in the cecal flora of the CON group, 954 OTUs in the cecal flora of the LPS group, 901 OTUs in the cecal flora of the SF group, and 959 OTUs in the cecal flora of the SF + LPS group (Figure 4a). No significant difference in community richness of cecal microbiota was observed in broilers, including Ace, Chao, Shannon, Coverage, and Simpson (p > 0.05, Figure 4c–f). The PCA map based on the genus level shows no difference between the four groups of cecal flora (Figure 4b). At the phylum level, the cecal flora consisted mainly of Firmicutes, Proteobacteria, Bacteroidota, and Actinobacteriota in broilers (Figure 4g). Firmicutes, Proteobacteria, and Bacteroidota were the dominant phyla, and their relative abundances were analyzed. SF supplementation presented a tendency to decrease the relative abundance of proteobacteria (0.05 < p < 0.1, Figure 4i). At the genus level, the cecal flora consisted mainly of Faecalibacterium, Escherichia-Shigella, Norank_f_norank_o_Clostridia_UCG-014, Ruminococcus_torques_group, Unclassified_f_Lachnospiraceae, Bacteroides, Erysipelatoclostridium, Unclassified_f_Ruminococcaceae, and Lactobacillus in broilers (Figure 4h). Compared with nonchallenged broilers, LPS presented a tendency to lower the relative abundance of Faecalibacterium (0.05 < p < 0.1, Figure 4j) and elevate the relative abundance of Erysipelatoclostridium (p < 0.05, Figure 4l). In addition, SF supplementation presented a tendency to increase the relative abundance of Unclassified_f_Lachnospiraceae (0.05 < p < 0.1, Figure 4k). Spearman correlation analysis confirmed that changes in intestinal flora were associated with LPS treatment and SF supplementation (Figure 5). There was an obviously negative correlation between IL-10 and Proteobacteria (p < 0.05), and a positive correlation between IL-1β, CORT, D-LA, and Proteobacteria (p < 0.05). In addition, TNF-α and Erysipelatoclostridium were positively correlated (p < 0.05).

4. Discussion

CORT serves as a crucial indicator of hypothalamus–pituitary–adrenal axis activity. Elevated CORT levels directly inhibit growth under immune stress conditions in broilers [25]. In our study, the CORT level of broilers was significantly increased after injection of LPS, validating successful modeling for subsequent tests. In a similar experiment, SF supplementation markedly enhanced the ADG and FW of broilers at days 21, 42, and played a role in improving nutrient digestion and absorption [26]. Quercetin, the primary active component of SF, upregulated the expression of nutrient transporter genes in the intestine, such as glucose transporter 2 and peptide transporter 1, promoted intestinal digestion and absorption, improved intestinal morphology, protected the intestinal barrier, and improved growth performance [27]. Dietary incorporation of 1000 mg/kg SF significantly influenced ADG and FW in broilers, which may be closely related to its active components. The utilization rate of feed and the digestion and absorption of nutrients are critical factors influencing growth performance, especially in the intestine, which plays an important role as the main site for the digestion and absorption of nutrients [28]. The specific reasons need to be further studied.

Intestinal morphology is a key indicator for evaluating digestion [29]. It is primarily characterized by VH, CD, and V/C indexes; longer VH and shallower CD can provide a larger area of intestinal nutrient absorption, on the contrary, which may cause intestinal inflammation and impair intestinal function. Therefore, greater V/C signifies higher absorption capacity; a normal intestinal structure is essential for growth and development [30]. In this study, it was observed that LPS stimulation significantly impaired the intestinal morphology of broilers, which aligns with previous research findings [31,32]. Notably, dietary SF supplementation alleviated the adverse effects of LPS on intestinal morphology by reducing jejunal CD and increasing duodenal VH as well as V/C and jejunal V/C ratios. Thus, SF supplementation-enhanced intestinal VH and V/C may improve intestinal morphology by promoting the proliferation and differentiation of intestinal epithelial cells while increasing the surface area for nutrient absorption in the intestine [33].

D-LA and endotoxin are commonly utilized for evaluating intestinal permeability and intestinal mucosa damage. D-LA and endotoxin are the byproducts of lactic acid fermentation and cleavage of bacteria in the intestine, exclusive to this tissue [34,35]. Under normal conditions, levels of D-LA and endotoxin in the blood of livestock and poultry are minimal, increasing only when there is intestinal mucosal damage [36,37]. Increased intestinal permeability due to damaged integrity leads to decreased nutrient digestion and absorption in livestock and poultry, impacting poultry growth performance [38]. Our study also revealed that intraperitoneal injection of LPS raised the levels of D-LA and endotoxin in broilers, indicating LPS-induced damage to the broiler’s intestinal mucosa barrier function. However, SF supplementation significantly reduced the D-LA level in broilers. These results suggest that SF mitigated LPS-induced impairment of broiler intestinal permeability while positively influencing their mucosal barrier.

The tight junction is the crucial connection between intestinal epithelial cells. Tight junction proteins are essential components of the intestinal barrier protein, playing a crucial role in its composition and function [39]. Numerous studies have shown that during an inflammatory response, various inflammatory factors enter the intestine, leading to intestinal lesions, damage to the intestinal tissue, disruption of the barrier function, and reducing the Occludin, ZO-1, and Claudin-1 mRNA expression levels [40,41]. In this experiment, LPS stimulation significantly decreased the relative gene expression of MUC-2, Occludin, and ZO-1 in the jejunum mucosa of broilers. The expression of intestinal mucosal barrier genes in broilers was lowered, and intestinal permeability was impaired by intraperitoneal injection of LPS in broilers, which was also supported by elevated serum D-LA and endotoxin. It has been reported that dietary supplementation with flavonoids up-regulates the expression of tight junction proteins (especially ZO-1, Claudin-1, E-cadherin, and Occludin) in broilers at days 21 and provides protective benefit against LPS-challenged dysfunction in their intestinal mucosal barriers [42]. The study yielded similar findings: dietary SF could effectively up-regulate the relative gene expression of Occludin and ZO-1 in the jejunum mucosal of broilers. In summary, we recommend that SF supplementation at 1000 mg/kg enhances the expression of tight junctions in the small intestine challenged by LPS and maintains the integrity of the intestinal mucosal barrier.

When poultry is exposed to LPS, LPS binds to TLR4 and initiates a cascade reaction that stimulates the TLR4/NF-κB signaling pathway, leading to the secretion of a number of pro-inflammatory cytokines (IL-1β, IL-2, IL-6, TNF-α, et al.) by monocytes and macrophages, resulting in tissue damage [43]. NF-κB plays a crucial role in activating inflammation through the synthesis and release of pro-inflammatory cytokines [44,45]. Consistent with previous findings, this study observed that LPS significantly elevated serum inflammatory, and up-regulated the expression of genes related to the TLR4/NF-κB signaling pathway in the jejunum mucosa, confirming the LPS-mediated inflammatory response. It has been reported that flavonoids can reduce the occurrence of disease by negatively regulating the inflammatory factor IL-1β [46]. Quercetin, kaempferol, and isorhamnetin are the main active components of SF, which can enhance animal immunity and reduce inflammation [47]. SF shows great potential for treating inflammation, as does quercetin [48] and kaempferol [49]. and isorhamnetin [50] can inhibit the activation of the TLR4/NF-κB signaling pathway, thereby suppressing the production of pro-inflammatory cytokines. The results demonstrated that the addition of SF significantly reduced the levels of IL-1β, IL-2, and CORT in serum, as well as the relative expression levels of TLR4, NF-κB, and IL-1β mRNA in the jejunum mucosa. Additionally, it markedly elevated the concentration of IL-10 in serum. The results indicated that the anti-inflammatory effect of SF was closely related to the TLR4/NF-κB signaling pathway.

Intestinal flora is a complex ecosystem that plays a vital role in the digestion and absorption of nutrients, metabolism, immune regulation, and other processes. Numerous studies have demonstrated the vital importance of intestinal flora in maintaining overall body health [51]. Intestinal microbes can regulate the whole immune system, strengthen the intestinal barrier function, and thus improve the production performance of poultry [52]. It has been reported that the abundant proteobacteria could easily lead to bacterial imbalance and inflammatory responses [53]. The relative abundance of proteobacteria in mice significantly increased after long-term mildronate treatment, leading to a bacterial imbalance [54]. Xie et al. [55] found that quercetin can improve the intestinal environment and down-regulate the relative abundance of proteobacteria and other microorganisms. Supplementation with SF reduced the relative abundance of proteobacteria, which is basically consistent with previous studies. Furthermore, Spearman correlation analysis also revealed that IL-10 was significantly negatively correlated with Proteobacteria, while IL-1β, CORT, and D-LA were significantly positively correlated with Proteobacteria, indicating that Proteobacteria increased inflammation and reduced immune response. Faecalibacterium is a crucial intestinal bacterium with various probiotic effects, such as maintaining intestinal homeostasis and anti-inflammatory properties [56]. LPS challenge enriched potentially harmful microbes and led to an increase in Erysipelatoclostridium, which is indicative of intestinal disorders causing inflammation [57]. According to the study, Fuzhuan brick tea crude polysaccharides (FBTPs) restored the microbial imbalance induced by cyclophosphamide (Cy) by elevating several beneficial bacteria, such as lactic acid bacteria, Unclassified_f_Lachnospiraceae, while reducing Bacteroides and Helicobacter pylori, thus playing an immune protective role in Cy-induced mice [58]. In this experiment, LPS lowered the relative abundance of Faecalibacterium and elevated the relative abundance of Erysipelatoclostridium. In addition, SF supplementation presented a tendency to increase the relative abundance of Unclassified_f_Lachnospiraceae. In addition, Spearman correlation analysis showed that TNF-α and Erysipelatoclostridium were positively correlated, which supported this point. Therefore, we found that SF can up-regulate the relative abundance of beneficial bacteria and down-regulate the relative abundance of harmful bacteria, maintain intestinal health, and improve the production performance of broilers.

5. Conclusions

In conclusion, dietary supplementation with 1000 mg/kg of SF could enhance the growth performance of broilers by mitigating the serum inflammatory response, improving intestinal health via enhancing intestinal morphology and regulating the intestinal barrier, and effectively alleviating the damage caused by LPS.

Footnotes

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Figure 1. Serum inflammation and immune indexes in 20 d broilers (a–e). Data represent mean values of six replicates per group (n = 6). a–c Means in the same row with different superscripts differ (p < 0.05). CON: basal diet + saline; LPS: basal diet +500 μg/kg LPS; SF: 1000 mg/kg SF + saline; SF + LPS: 1000 mg/kg SF + 500 μg/kg LPS.

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Figure 2. Histological morphology of duodenum, jejunum, and ileum in 20 d broilers (a–j). Data represent mean values of six replicates per group (n = 6). ab Means in the same row with different superscripts differ (p < 0.05). CON: basal diet + saline; LPS: basal diet +500 μg/kg LPS; SF: 1000 mg/kg SF + saline; SF + LPS: 1000 mg/kg SF + 500 μg/kg LPS.

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Figure 3. Intestinal permeability and relative expression of jejunal mucosa-associated gene mRNA in 20 d broilers (a–j). Data represent mean values of six replicates per group (n = 6). a–c Means in the same row with different superscripts differ (p < 0.05). CON: basal diet + saline; LPS: basal diet +500 μg/kg LPS; SF: 1000 mg/kg SF + saline; SF + LPS: 1000 mg/kg SF + 500 μg/kg LPS.

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Figure 4. Venn diagram (a). Alpha diversity of cecal flora (b–e). Principal component analysis (PCA) of cecal flora (f). The relative abundance of cecal microbiota composition at the phylum and genus levels (g–l). CON: basal diet + saline; LPS: basal diet +500 μg/kg LPS; SF: 1000 mg/kg SF + saline; SF + LPS: 1000 mg/kg SF + 500 μg/kg LPS.

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Figure 5. Correlation analysis of cecal flora and inflammation indexes. Data represent mean values of six replicates per group (n = 6). * Indicates p < 0.05. ** Indicates p < 0.01.

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