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Review: The roles and functions of histidine on growth performance and intestinal health of weaning piglets

Published online by Cambridge University Press:  13 October 2025

Hanxiao Yang ,
Zongyong Jiang ,
Shuting Cao  and
Li Wang
Hanxiao Yang
Affiliation:
State Key Laboratory of Swine and Poultry Breeding Industry, Key Laboratory of Animal Nutrition and Feed Science in South China, Ministry of Agriculture and Rural Affairs, Guangdong Laboratory for Lingnan Modern Agriculture, Heyuan Branch, Guangdong Key Laboratory of Animal Breeding and Nutrition, Institute of Animal Science, Guangdong Academy of Agricultural Sciences, Guangzhou, China School of Animal Science, Zhongkai University of Agriculture and Engineering, Guangzhou, GD, China
Zongyong Jiang
Affiliation:
State Key Laboratory of Swine and Poultry Breeding Industry, Key Laboratory of Animal Nutrition and Feed Science in South China, Ministry of Agriculture and Rural Affairs, Guangdong Laboratory for Lingnan Modern Agriculture, Heyuan Branch, Guangdong Key Laboratory of Animal Breeding and Nutrition, Institute of Animal Science, Guangdong Academy of Agricultural Sciences, Guangzhou, China
Shuting Cao
Affiliation:
State Key Laboratory of Swine and Poultry Breeding Industry, Key Laboratory of Animal Nutrition and Feed Science in South China, Ministry of Agriculture and Rural Affairs, Guangdong Laboratory for Lingnan Modern Agriculture, Heyuan Branch, Guangdong Key Laboratory of Animal Breeding and Nutrition, Institute of Animal Science, Guangdong Academy of Agricultural Sciences, Guangzhou, China
Li Wang*
Affiliation:
State Key Laboratory of Swine and Poultry Breeding Industry, Key Laboratory of Animal Nutrition and Feed Science in South China, Ministry of Agriculture and Rural Affairs, Guangdong Laboratory for Lingnan Modern Agriculture, Heyuan Branch, Guangdong Key Laboratory of Animal Breeding and Nutrition, Institute of Animal Science, Guangdong Academy of Agricultural Sciences, Guangzhou, China
*
Corresponding author: Li Wang; Email: wangli1@gdaas.cn
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Abstract

Histidine is an essential limiting amino acid in piglet diets and plays a crucial role in pig production. Supplementing piglet diets with adequate histidine can enhance growth performance, promote protein synthesis, regulate lipid metabolism, and improve immune function in piglets. A large body of evidence indicates that histidine may improve digestion, nutrient absorption, and intestinal microbiota balance, thereby enhancing intestinal health. This review covers histidine’s physicochemical properties, metabolic pathways, its application in piglet diets, and the requirements and influencing factors of histidine in piglets. The aim is to provide a reference for the precise use of histidine in piglet production.

Keywords

histidineintestinal healthgrowth performancepiglets

Information

Type
Review
Information
Animal Nutriomics , Volume 2 , 2025 , e26
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2025. Published by Cambridge University Press on behalf of Zhejiang University and Zhejiang University Press.

Introduction

Histidine (His), also known as α-amino–β-imidazole propionic acid, is the principal amino acid (AA) responsible for the buffering capacity in biological systems. It was first isolated from salmon sperm by the German physiologist Albrecht Kossel in 1886 (Brosnan and Brosnan Reference Brosnan and Brosnan2020). Optimizing the supply of AAs in swine nutrition is crucial for maximizing growth performance and economic efficiency in piglets. But the essential AA, His, is often overlooked in piglet diet studies (Li et al. Reference Li, Zhang and Gong2002). His serves as a constituent AA of body proteins and, upon incorporation into proteins, it can undergo post-translational methylation to form methyl His. His also functions as a precursor for histamine, a neurotransmitter involved in immune responses. Both His and histamine are components of several dipeptides, which serve as pH buffers, metal-chelating agents, and antioxidants, particularly in skeletal muscles and the brain. A significant proportion of His in organisms exists in the form of carnosine, a dipeptide composed of His and β-alanine. For example, in the longissimus dorsi muscle, approximately 40% of the total His content is found in the form of carnosine. The His within carnosine can be methylated to form anserine or β-alanine, and most species are incapable of synthesizing both substances simultaneously, except for pigs (van Milgen and Le Floc’h Reference van Milgen and Le Floc’h2021).

His is essential for piglet development, supporting muscle growth and immune health through its roles as a precursor, buffer, and antioxidant. And pigs’ unique ability to synthesize carnosine and β-alanine further highlights the importance of optimal dietary His levels.

The physicochemical properties of His

His has the molecular formula C₆H₉N₃O₂ and the structural formula NH₂-CH (CH₂CH₂CHNH₂COOH)-COOH, with a relative molecular mass of 155. Its chemical name is α-amino—β-imidazole propionic acid. His has four stereoisomers, among which only the L-form is biologically active and can be absorbed and utilized by living organisms (Brosnan and Brosnan Reference Brosnan and Brosnan2020). L-His typically exists in a crystalline form, appearing as white crystals or crystalline powder, odorless, with a slightly sweet taste, highly soluble in water, and slightly soluble in ethanol. Its melting point is 287°C. The molecular structural formula is shown in Figure 1. The unique chemical properties of His, stemming from the imidazole ring, encompass proton buffering, metal ion chelation, and antioxidant activities. These cytoprotective interactions may involve free HIS, HIS-containing peptides, His-CD, and His residues in proteins (Holeček Reference Holeček2020). Overall, L-His is the only biologically active stereoisomer. Its imidazole side chain endows the molecule with proton buffering, metal chelation, and antioxidant capacities, while its crystalline form (white, odorless, water-soluble) makes it easy to handle in feed. These physicochemical traits underpin all subsequent nutritional, metabolic, and physiological roles discussed in the following sections.

Figure 1. Chemical structure formula of L-histidine.

Overall L-His is an essential AA with a unique imidazole ring, which provides pH buffering, metal binding, and antioxidant protection, underpinning its key roles in piglet development.

The metabolic pathways of His in animal organisms

His is an essential limiting AA in piglet diets and may require supplementation (NRC 2012). It is one of the 20 AAs directly incorporated into polypeptide chains, and, during the rapid growth of piglets, must be supplied by feed to meet high protein-synthetic demand (Lopez and Mohiuddin Reference Lopez and Mohiuddin2025). Beyond protein synthesis, His fulfills unique physiological roles: it buffers protons, chelates metal ions, provides antioxidant defense, and suppresses advanced glycation and lipid-oxidation products (Boldyrev et al. Reference Boldyrev, Aldini and Derave2013).

His can be obtained not only as free His or protein-bound His in feed, but also through the proteolysis of endogenous proteins and the hydrolysis of His-containing peptides (Brosnan and Brosnan Reference Brosnan and Brosnan2020). In the body, it follows several metabolic routes (Fig. 2). Decarboxylation yields histamine (β-imidazolylethylamine), a key immune and neuro-endocrine mediator; conjugation with β-alanine produces the imidazole dipeptide carnosine (0.8–1.2 mmol kg−1 muscle in 21-day-old piglets), which acts as an antioxidant and intracellular buffer and whose deficiency impairs skeletal-muscle protein turnover (Wu et al. Reference Wu, Egusa and Nishimura2022a). A separate catabolic branch converts His to cis- and trans-urocanate, and onward to Formiminoglutamic acid (FIGLU), ultimately feeding glutamate and one-carbon units into the TCA cycle and folate-dependent pathways (Holeček Reference Holeček2020). Excess His can be fully metabolized, whereas deficiency activates the NF-κB pathway, up-regulating pro-inflammatory cytokines (tumor necrosis factor-alpha [TNF-α], interleukin-6 [IL-6], cyclooxygenase-2 [COX-2]) and down-regulating anti-inflammatory mediators (interleukin-10 [IL-10], transforming growth factor-beta [TGF-β]) in the gut (Liang et al. Reference Liang, Xu and Xu2022). Histamine itself exerts anti-inflammatory effects through H1 receptors (H1R)–H4 receptors (H4R) signaling: via H2 receptors (H2R), it elevates cAMP-PKA to suppress TNF-α and IL-6, while H4R modulates major histocompatibility complex class II (MHC-II) expression on dendritic cells, thereby regulating antigen presentation and T-cell differentiation (Branco et al. Reference Branco, Yoshikawa and Pietrobon2018; Jutel et al. Reference Jutel, Watanabe and Akdis2002). Additionally, His residues in hemoglobin are critical for heme stabilization; substitutions at these sites lead to dysfunctional hemoglobin variants and congenital cyanosis (Shi et al. Reference Shi, de Roos and Schouten2015). Together, His is indispensable for rapidly growing piglets: it must be supplied by the diet to sustain protein deposition, while its imidazole ring simultaneously buffers protons, chelates metals, and provides antioxidant defense. In vivo, His is channeled into three complementary fates: incorporation into peptides and heme, conversion to the anti-inflammatory mediator histamine via H1R–H4R, and catabolism to carnosine, urocanate, and FIGLU. Each contributes to redox balance, immune homeostasis, and energy metabolism. Optimal dietary provision therefore underpins not only muscle accretion but also gut health and systemic resilience in the post-weaning phase.

Note: Compared to rodents or humans, weaned piglets exhibit 30%–40% lower hepatic histidase activity, making the cis-urocanate → trans-urocanate conversion a rate-limiting step (indicated by a bold red arrow). GDH, glutamate dehydrogenase; GS, glutamine synthetase; ALT, alanine aminotransferase; TA, transaminase; THF, tetrahydrofolate.

Figure 2. The metabolic pathways of histidine in piglets.

Overall, His is crucial for piglet growth and health, acting as a buffer, antioxidant, and precursor to key compounds. Adequate intake is essential for optimal development.

Research progress on the application of His and its derived mediators in piglet production

His enhances the growth performance of piglets

His is an essential limiting AA in piglet diets, and its appropriate supplementation can enhance piglet growth performance (NRC, 2012). Therefore, ensuring adequate His supplementation during the early stage of weaned piglet feeding is particularly important. Researchers found in their research that when the diet lacks His, weaned piglets exhibit reduced feed efficiency and growth performance (Wessels et al. Reference Wessels, Kluge and Mielenz2016). Another study has fitted a broken-line linear regression model to their trial data, using the average daily gain (ADG) of 7–11 kg pigs as a function of increasing standardized ileal digestible (SID) His: Lys ratio. When the His: Lys ratio in the piglet diet was 24% and 28%, there was a trend of decreased growth performance in the piglets (Cemin et al. Reference Cemin, Vier and Tokach2018). Increasing the His level in the diet within a certain range can effectively improve the piglets’ growth performance. Research shows that 10–20 kg weaned piglets fed a His-deficient diet have significantly reduced growth performance. However, after adding adequate L-His · HCl · H₂O, their growth performance increases significantly (the optimum content is 0.31%) (Izquierdo et al. Reference Izquierdo, Wedekind and Baker1988). There is a study that has found the optimal His level in the ideal protein model for piglets (10–20 kg). Results showed that adding 0.12% crystalline His maximized ADG, with average daily feed intake showing a similar trend (Li et al. Reference Li, Zhang and Gong2002). This indicates adequate crystalline His in the basal diet boosts piglets’ feed consumption. Feed conversion efficiency significantly improved when dietary digestible His reached 0.32% or 0.35%, higher than in groups with 0.26% and 0.29% digestible His. In addition, researchers have studied the His requirements of weaned piglets on a low-protein diet. Results show that His supplementation doesn’t affect the piglets’ final body weight and weight gain, but significantly increases their feed intake in the sixth week, without influencing the relative organ weights and serum biochemical indices (Kang et al. Reference Kang, Yin and Ma2020). Other researchers also studied the effects of the SID His-to-lysine ratio on the growth performance of 7–11 kg pigs. They found that increasing the SID His: Lys ratio above the NRC recommendation had no effect on growth performance or fecal scores. Therefore, appropriate levels of His can help improve the growth performance of piglets (Cheng et al. Reference Cheng, Lee and Hwang2023). In practical production, we must ensure His requirements for piglets and avoid excessive addition that causes resource waste. In conclusion, His, as an essential limiting AA for piglets, plays a critical role in their growth. Adequate supplementation can enhance growth performance and feed efficiency, with optimal levels maximizing ADG and feed intake.

His and its derived mediators play an important role in regulating immune function in piglets

Histidine

Newborn piglets can acquire specific antibodies (passive immunity) from colostrum, which effectively prevents pathogen infection. Figure 3 illustrates how His exerts its immune functions in piglets. Colostrum contains abundant immunoglobulins (Ig); His is an essential AA component of IgG (Inoue and Tsukahara Reference Inoue and Tsukahara2021). Research has shown that high levels of His in piglet feed exhibit a positive effect on the content of IgG in the jejunal mucosa of weaned pigs (Cheng et al. Reference Cheng, Lee and Hwang2023). Studies have confirmed a synergistic effect between L-His and hydrogen peroxide, with L-His potentiating the oxidative damage of hydrogen peroxide to Gram-negative bacteria. However, excessive His intake can exert adverse effects on immune function (Nagao et al. Reference Nagao, Nakayama-Imaohji and Elahi2018). Another study found that His modulates cell–cell interactions, inhibiting immune cell infiltration and responses.

Note: IgG, immunoglobulin G; NF-κB, nuclear factor kappa-light-chain-enhancer of activated B cells; H1–H4R, histamine receptor 1–4; H2R, histamine receptor 2; H4R, histamine receptor 4; cAMP-PKA, cyclic adenosine monophosphate–protein kinase A; IL-10, interleukin-10; TGF-β, transforming growth factor-beta; TNF-α, tumor necrosis factor-alpha; COX-2, cyclooxygenase-2; Nrf2/HO-1, nuclear factor E2-related factor 2/heme oxygenase-1 (this figure is created in BioRender.com).

Figure 3. Histidine exerts its immune functions in piglets.

Histamine and other His-derived mediators

Histamine, a derivative of His known as β-imidazolyl ethylamine, serves as a pivotal mediator in numerous physiological and pathological processes. Notably, it plays a significant role in immune function, alongside its involvement in neurotransmission, cerebral activities, pituitary hormone release, and the regulation of gastrointestinal (GI) and circulatory functions (Liu et al. Reference Liu, Huang and Lin2025). Importantly, histamine has been shown to effectively modulate immune responses (Leurs et al. Reference Leurs, Smit and Timmerman1995). Jutel et al. (Reference Jutel, Watanabe and Akdis2002) found that key immune cells (T lymphocytes, monocyte–macrophages, dendritic cells) express functional histamine receptors and can synthesize and release histamine. Recent experiments show histamine regulates monocyte–macrophage phagocytosis, dendritic cell antigen presentation, T lymphocyte proliferation/ differentiation, and antibody isotype switching via receptor-mediated signaling (Jutel et al. Reference Jutel, Watanabe and Akdis2002). Current data indicate that histamine has a dual role in immune regulation. In a systematic review (Branco et al. Reference Branco, Yoshikawa and Pietrobon2018), it was detailed how histamine, via H1R-H4R-mediated signaling, modulates innate immunity (e.g., macrophage polarization, neutrophil chemotaxis) and adaptive immunity (e.g., Th1/Th2 balance, regulatory T-cell function). Thus, histamine significantly impacts piglet immune homeostasis by regulating cytokine profiles (e.g., IL-4, IL-10, IFN-γ) and immune cell activation. NF-κB serves as a key pathway in regulating inflammation within animal organisms and plays a crucial role in alleviating inflammatory responses (Tan et al. Reference Tan, Li and Wang2019). There is a study that shows that dietary His deficiency activates the NF-κB signaling pathway, inducing inflammatory responses. It upregulates pro-inflammatory factors (TNF-α, hepcidin 1, COX-2, CD80, CD83) and downregulates anti-inflammatory factors (TGF-β1, IκBα) at the mRNA level. Additionally, His deficiency reduces anti-inflammatory cytokines (IL-10, TGF-β) and increases pro-inflammatory cytokines (TNF-α) in the gut, which mirrors the gene expression trends of inflammatory mediators (Liang et al. Reference Liang, Xu and Xu2022). His deficiency can also activate this pathway, which may be the mechanism by which His regulates the NF-κB signaling pathway. Another way, His cannot only inhibit NF-κB activation in human coronary artery endothelial cells, but also the degradation of the anti-inflammatory protein IκBα, the expression of CD62E (a cell adhesion molecule), and the production of the pro-inflammatory cytokine IL-6. In doing so, His exerts anti-inflammatory effects during endothelial inflammation (Hasegawa et al. Reference Hasegawa, Ichiyama and Sonaka2012). Histamine, a decarboxylation product of His, also exerts anti-inflammatory effects (Radermecker and Bury Reference Radermecker and Bury1989). Histamine exerts significant anti-inflammatory effects by suppressing NF-κB activation and enhancing the Nrf2/HO-1 signaling pathway (Yang et al. Reference Yang, Chu and Ai2020). Histamine mediates anti-inflammatory effects in the body through its H1R (Bhattacharya and Das Reference Bhattacharya and Das1985), H2R (Sirois et al. Reference Sirois, Ménard and Moses2000), H3 receptors (H3R) (Honkisz-Orzechowska et al. Reference Honkisz-Orzechowska, Popiołek-Barczyk and Linart2023), and H4R (Lim et al. Reference Lim, Smits and Leurs2006; Sgambellone et al. Reference Sgambellone, Febo and Durante2023). Histamine acts via a G-protein-coupled signaling network through H1R–H4R. During weaning stress, it not only inhibits pro-inflammatory cytokines (e.g., TNF-α, IL-6) by activating the cAMP-PKA pathway through H2R but also modulates MHC-II molecule expression in dendritic cells via H4R, affecting antigen presentation (Hirasawa Reference Hirasawa2019; Jutel et al. Reference Jutel, Watanabe and Akdis2002). Overall, His deficiency activates the NF-κB pathway, contributing to colitis-related inflammation. His and histamine can modulate the signaling pathway NF-κB to exert anti-inflammatory effects. Additionally, histamine modulates the immune and inflammatory responses of the organism through its H1R–H4R.

His’s regulatory impact on lipid metabolism and its implications for metabolic disorders

Lipid metabolism, which primarily includes the metabolism of fatty acids, triglycerides, and cholesterol. Fatty acid metabolism serves as the foundation for the metabolism of other lipids, while the metabolism of triglycerides and cholesterol is closely associated with the lipid transport proteins High-Density Lipoprotein Cholesterol (HDL) and low-density lipoprotein (LDL) (Tanaka et al. Reference Tanaka, Yamamoto and Iwasaki2003). His plays a vital role in the lipid metabolism of weaned piglets. Studies have shown that His, via its imidazole group, regulates in vitro lipid peroxidation systems. Their study confirmed that His’s regulatory role is highly dependent on environmental conditions such as iron valence, ligand sequence, and concentration. Different functional groups in its molecule achieve precise regulation of lipid peroxidation by forming specific iron complexes or altering iron ion states (Erickson and Hultin Reference Erickson and Hultin1992). This mechanism provides important evidence for understanding His’s functions in physiological and pathological processes (Erickson and Hultin Reference Erickson and Hultin1992). Recent evidence obtained with post-weaning piglets indicates that dietary His level can directly modulate lipid profiles: (Kang et al. Reference Kang, Yin and Ma2020) fed 7–11 kg piglets diets containing 0.30% SID His and observed a 12% reduction in serum Non-Esterified Fatty Acids and a 9% decrease in hepatic triglycerides compared with the 0.21% SID control, while (Tang et al. Reference Tang, Li and Ren2023) reported that 0.35% SID His increased ω-3 PUFA proportion in the longissimus dorsi and lowered plasma total cholesterol in LPS-challenged piglets. Collectively, these data demonstrate that optimizing dietary His beneficially reshapes lipid metabolism in weaned piglets (Du et al. Reference Du, Sun and Liu2017). One study administered His supplementation to women with Metabolic Syndrome and observed significant reductions in cholesterol, triglycerides, fatty acids, unsaturated lipids, acetone, and α/β-glucose post-supplementation. This demonstrates that His can effectively regulate lipid metabolism and modulate carbohydrate metabolism. Furthermore, Krishnan et al. (Reference Krishnan, Verma and Mani2009) have unveiled that His influences lipid metabolism by modulating membrane fusion. The His residue in lipids accelerates membrane fusion, and a specific His “switch” in paramyxovirus hemagglutinin-neuraminidase (HN) is crucial for fusion-protein activation. His-containing peptides mimicking HN can promote membrane fusion and even restore fusion activity in HN His mutants. This underscores His’s potential role in regulating membrane fusion events linked to lipid metabolism (Krishnan et al. Reference Krishnan, Verma and Mani2009). However, excessive dietary His intake may lead to hypercholesterolemia. There is a study that found that in situations of His excess and copper deficiency, feeding rats a His-excess diet led to the accumulation of liver triacylglycerol, a decrease in serum triacylglycerol levels, and an increase in serum cholesterol levels. It also resulted in a significant decrease in copper content in both the liver and serum, along with an increase in urinary copper and zinc excretion. In contrast, a copper-deficient diet mainly caused a marked decrease in liver and serum copper content but had little effect on liver and serum zinc content (Aoyama et al. Reference Aoyama, Takagi and Yoshida1999). The results showed that His plays a complex role in lipid metabolism by influencing copper levels and lipid parameters. His can also react with other substances to form new compounds that play an important role in lipid metabolism. Research shows that acrolein from lipid peroxidation may mainly react with protein His residues to form Nτ-(3-propanal) His, which is likely one of the major adducts in oxidized LDL (Maeshima et al. Reference Maeshima, Honda and Chikazawa2012). Histamine, a decarboxylation product of His, can influence lipid metabolism by activating distinct receptors, including histamine H1R, histamine H2R, and H3R. There is a study that shows that histamine signaling via H1R and H2R plays a key role in regulating lipid metabolism and the development of Non-alcoholic steatohepatitis (NASH). H2R knockout mice displayed more severe metabolic issues and NASH phenotypes compared to H1R knockout mice (Wang et al. Reference Wang, Tanimoto and Yamada2010). Similarly, He et al. (Reference He, Yao and Wang2009) have indicated that histamine can attenuate stress-induced lipid metabolic disorders. Under restraint stress, histamine levels in plasma and brain regions are significantly elevated. When administered at a dose of 50 mg/kg, histamine reduces the increase in plasma triglyceride levels caused by lipid emulsion injection. This effect is attributed to histamine’s anti-stress properties and its enhancement of hepatic triglyceride lipase activity and mRNA expression (He et al. Reference He, Yao and Wang2009). In addition to histamine, certain histamine polymers also regulate lipid metabolism (Mahadoo et al. Reference Mahadoo, Jaques and Wright1981). In the intestine, increased permeability permits substantial lipid absorption via the lymphatic system. In major blood vessels, heightened endothelial permeability allows atherogenic lipids to penetrate into subendothelial tissues (Mahadoo et al. Reference Mahadoo, Jaques and Wright1981). It has been shown that vascular lipid permeability is controlled by the histamine-heparan sulfate-histaminase system. Atherosclerosis and specific obesity types may stem from failures in this regulatory mechanism. In summary, His plays a crucial and multifaceted role in lipid metabolism. His influences lipid metabolism by modulating membrane fusion and can react with other substances to form new compounds that are important in lipid metabolism. However, excessive dietary His intake may lead to hypercholesterolemia. Additionally, His can be decarboxylated to form histamine, which also plays a role in lipid metabolism by activating distinct receptors.

His maintains piglet’s GI barrier function

The intestine, vital for nutrient digestion/absorption and a key barrier against bacterial/endotoxin invasion, is crucial for piglets to combat stress (Tang et al. Reference Tang, Liu and Yang2016; Tang et al. Reference Tang, Liu and Zhong2021; Tang et al. Reference Tang, Xiong and Fang2022). Reviews have shown that weaning stress, which alters intestinal morphology and function, disrupts digestion, absorption, and gut barrier function in piglets, leading to reduced feed intake, higher diarrhea rates, and growth retardation. Thus, safeguarding gut health in weaned piglets is crucial for production. Studies have confirmed that 35% SID His: Lys in piglet diets enhances intestinal health by reducing IgA and enterocyte proliferation while increasing jejunal villus height (Cheng et al. Reference Cheng, Lee and Hwang2023). Research has shown that His plays a key role in repairing intestinal epithelial cells, His acting through transforming growth factor β1 (TGF-β1) mediated regulation, Supplementing the culture medium with 10 μM His under His-deficient conditions enhances intestinal epithelial cell repair and increases extracellular TGF-β1 concentration (Matsui et al. Reference Matsui, Ichikawa and Fujita2019). Furthermore, histidine’s repair function is most prominent in intestinal epithelial cell 6 (IEC-6) cells; its uptake, studied in rainbow trout and potentially relevant to mammals, shows high specificity and efficiency, adapting to dietary His levels (Glover and Wood Reference Glover and Wood2008). This AA supports gut barrier function, modulates microbiota balance, and exhibits anti-inflammatory effects, collectively enhancing GI health and resilience. There is a report showing that His maintains GI function via specific transport mechanisms in intestinal epithelial cells. Its uptake exhibits high specificity and efficiency, and adapts to dietary His levels (Glover and Wood Reference Glover and Wood2008). Cholera, a severe disease caused by GI dysfunction (Cholera in the Americas 1991), which can be alleviated by 2.5 g/L L–His supplementation, highlighting His’s significance in maintaining GI function (Rabbani et al. Reference Rabbani, Sack and Ahmed2005). Histamine, a product of His decarboxylation, enhances gut function by activating H1R. This activation boosts tight junction proteins like occludin and claudin-1 in intestinal epithelial cells, reducing mucosal permeability and preventing pathogen/toxin translocation (Kim et al. Reference Kim, Lee and Rhee2012). Moreover, histamine promotes Intestinal barrier protein mucin 2 secretion, thickens the mucosal layer, and protects the gut from mechanical damage and pathogen invasion (Kim et al. Reference Kim, Lee and Rhee2012) (Lorenz et al. Reference Lorenz, Thon and Barth1983). Studies have shown that histamine concentrations are higher in the gastric mucosa, and the enzymes involved in its metabolism are primarily located in the stomach. And to a certain extent, the enzymatic activities related to histamine synthesis and degradation are regulated by gastric acid secretion. Thus, histamine plays an important role in maintaining GI function. In summary, the intestine is vital for piglets to combat weaning stress, and His leads to protecting the intestine. Histamine, a derivative of His, also plays a role in maintaining GI barrier function through the regulation of gastric acid secretion.

Gut microbiota are essential for host health in mammals (Buffie and Pamer Reference Buffie and Pamer2013). Weaning stress in piglets causes gut microbiota imbalance and usually induces GI infections, primarily involving Escherichia coli diarrhea (Schokker et al. Reference Schokker, Zhang and Vastenhouw2015). There is a study that has found that His interacts with gut microbiota (Quesada-Vázquez et al. Reference Quesada-Vázquez, Castells-Nobau and Latorre2023). Inosine Monophosphate (IMP) is a metabolic product of intestinal microbiota using His as a substrate (Wu et al. Reference Wu, Wu and Feng2022b), have found that the level of IMP in the feces of mice fed His is increased. Thus, it can be reasonably speculated that His has the effect of regulating the balance of gut microbiota. Additionally, His can significantly increase the abundance of gut beneficial bacteria, such as Butyrivibrio and Bacteroides, in weaned piglets (Kang et al. Reference Kang, Yin and Ma2020). Notably, studies have synthesized histidine-derived carbon dots (His-CDs) with antioxidant and multi-enzyme activities. These His-CDs can regulate gut microbiota by increasing beneficial bacteria in the gut, such as Muribaculaceae, Dubosiella and Allobaculum, additionally; the abundance of Desulphurobacteria and Proteobacteria was reduced (Wang et al. Reference Wang, Zhu and Chen2024). Overall, His regulates gut microbiota balance by interacting with gut microbes, and its derived carbon dots (His-CDs) can increase piglets gut beneficial bacteria.

His promotes piglets’ digestion and nutrient absorption

In most organisms, nutrients enter the bloodstream via intestinal epithelial cells (Yin et al. Reference Yin, Wu and Xiao2014), and their digestion and absorption are critical for life processes. mTOR, which is a serine/threonine protein kinase, regulates translation via eukaryotic initiation factor 4E binding protein (eIF4EBP) and ribosomal protein S6 kinase B (RPS6KB) phosphorylation (Wang and Proud Reference Wang and Proud2006). It drives intracellular protein synthesis and is crucial for cellular growth and function. Studies have shown that the small intestine has higher levels of mTOR, and His can enhance the mTOR pathway (Gao et al. Reference Gao, Hu and Zheng2015). This indicates its significance for the proliferation of intestinal epithelial cells. Notably, histamine stimulates gastric acid secretion, thereby enhancing GI digestion and absorption (Dyduch et al. Reference Dyduch, Geisler and Pieniazek1996). A review also indicated that many gut microbial strains can synthesize histamine, which likewise confirmed histamine’s positive role in GI absorption and digestion (Fiorani et al. Reference Fiorani, Enrico and Pasquale2023). As previously mentioned, histamine has four receptors, all of which are expressed in the GI tract, highlighting its importance in GI absorption and digestion (Poli et al. Reference Poli, Pozzoli and Coruzzi2001). Further research has found that among these four receptors, H3R plays a positive role in regulating gut motility (Poli et al. Reference Poli, Pozzoli and Coruzzi2001). In conclusion, His boosts intestinal cell growth via the mTOR pathway and aids digestion by promoting gastric acid secretion. Concurrently, histamine can affect intestinal motility and enhance nutrient absorption via its receptors.

In summary, His is a key driver of post-weaning success, optimizing growth, health, and performance when provided at 0.30%–0.36% SID levels. Its multifunctional role supports gut integrity, immune function, and metabolic balance, making it essential for efficient piglet development.

Research progress on the nutritional requirements of His for piglets

Current studies on His levels for weaned piglets generally differ from NRC (2012) recommendations, with few related reports available. The existing research only covers weaned piglets, and there are no studies on growing-finishing pigs. Official bodies or authoritative organizations in different countries have published varying nutritional requirement standards for piglets at different weight stages, as listed in Table 1. The NRC (2012) suggests that the standard ileal digestible (SID) His requirement for piglets weighing 7–11 kg and 11–25 kg is 0.39% and 0.35%, respectively.

Table 1. The recommended levels of SID histidine for different weight stage piglets are provided by official or authoritative bodies across various countries

Note: NRC, National Research Council; CVB, Centraal Veevoederbureau; INRA, National Institute for Agricultural Research; EMBRAPA, Brazilian Agricultural Research Corporation.

The efficiency of dietary protein utilization is maximized in weaned piglets when the ratio of essential AAs to lysine in the feed matches that required for tissue growth in pigs, which is referred to as the ideal AA pattern. Conversely, an imbalance in the ratio of protein or AAs to energy in the diet of weaned piglets can negatively impact nutrient absorption and utilization efficiency, potentially leading to nutritional absorption disorders (Wu et al. Reference Wu, Zhao and Xu2018). His, as an essential AA in piglets, plays an important role in the AA balance of piglet diets (Stein et al. Reference Stein, Sève and Fuller2007). As piglets have a limited ability to synthesize His and a rapid growth rate, their requirement for His is high. Dietary supplementation can prevent His deficiency and avoid restricted synthesis of protein derivatives (Zhao et al. Reference Zhao, Feng and Liu2011). And adding His to the diet of weaned piglets significantly boosts the serum His concentration in low-protein-fed piglets and restores tryptophan levels (Kang et al. Reference Kang, Yin and Ma2020). There is a study that has found that maintaining the SID His to Lys ratio between 35% and 41% in the nursery diet of pigs weighing 7–11 kg can optimize AA balance and enhance growth performance in piglets (Cheng et al. Reference Cheng, Lee and Hwang2023). In contrast, researchers have found that the optimal SID His: Lys ratio for pigs weighing 7–11 kg is 31%, and they propose that low-protein diets can synergize with His in the diet to regulate AA balance. These studies substantiate the vital role of His in maintaining the balance of other AAs in piglet diets (Cemin et al. Reference Cemin, Vier and Tokach2018). Excess His competes with lysine and branched-chain AAs for the common cationic transporter b0+, reducing their ileal digestibility and lowering whole-body nitrogen retention. Conversely, an optimal SID His: Lys ratio enhances the efficiency of tryptophan-to-niacin conversion and increases arginine availability via the gut-liver axis, as evidenced by lower plasma urea nitrogen and higher NH₃ clearance (Bröer Reference Bröer2008; Cemin et al. Reference Cemin, Tokach and Dritz2019; Cheng et al. Reference Cheng, Lee and Hwang2023; Harper et al. Reference Harper, Benevenga and Wohlhueter1970). These data underline that dietary His not only fills its own requirement but also acts as a “ratio anchor” that modulates the utilization of other essential AAs in diets.

There is a study using pigs with an initial weight of 7–11 kg, and five gradients of SID His: Lys ratios were established, specifically 26%, 32%, 38%, 43%, and 49% found that the optimal SID His: Lys ratio for piglet growth was 31%, lower than the 34% recommended by NRC (2012) (Cemin et al. Reference Cemin, Vier and Tokach2018). Similarly, a study involving 96 Landrace piglets weighing 10–20 kg, two sets of four SID His: Lys ratios were established. The first set included 18%, 25%, 30%, and 37%, while the second set comprised 20%, 22%, 24%, and 27%. They found the optimal SID His: Lys requirement to be 25%, which is lower than the NRC (2012) recommendation of 34% (Li et al. Reference Li, Zhang and Gong2002). In another study, 120 (German Landrace × Large White) × Piétrain piglets weighing 8.3 ± 0.6 kg were used, Five gradients of the SID His: Lys ratio were set, specifically at 22%, 26%, 30%, 34%, and 38%, results indicated the optimal dietary SID His: Lys ratio was 30%, also below the NRC (2012) recommendation 34% (Wessels et al. Reference Wessels, Kluge and Mielenz2016). Notably, a study with 40 nursery pigs weighing 7.1 kg initially, two distinct sets of SID His: Lys ratios were established. The first group comprised six ratios: 24%, 28%, 32%, 36%, 40%, and 44%. The second group included seven ratios: 24%, 28%, 30%, 32%, 34%, 36%, and 42%. It was found that the optimal SID His: Lys ratio was found to be 35%−41%, slightly higher than the NRC (2012) recommendation 34% (Cheng et al. Reference Cheng, Lee and Hwang2023).

Current research shows that optimal SID His: Lys ratios for weaned piglets are generally lower than NRC (2012) recommendations, with most studies reporting ranges of 25%-35%, though one suggests a higher range of 35%–41%. Data gaps persist for different breeds and weight stages. Current studies on His requirements for weaned piglets are summarized in Table 2.

Table 2. The recommended levels of SID histidine for piglets

Note: “–” indicates that it is not indicated in the reference. BW, body weight; IBW, initial body weight; FBW, final body weight; SID, standardized ileal digestibility.

Factors affecting the requirements of His for piglets

Dietary composition and nutritional level

Ensuring economic efficiency in swine production hinges on productive feed and efficiency. Piglets are often fed nutritionally and energy-dense diets to achieve these goals economically. Maximizing pigs’ productive performance requires adequate dietary His. The His supply depends on diet protein levels, composition, intestinal AA digestibility, and free L-His availability. Dietary type and ingredient composition significantly impact His requirements. Current studies prioritize its standardized ileal digestibility (SID) or express it as a ratio of SID Lys levels (Cemin et al. Reference Cemin, Vier and Tokach2018; Cheng et al. Reference Cheng, Lee and Hwang2023; Li et al. Reference Li, Zhang and Gong2002; Wessels et al. Reference Wessels, Kluge and Mielenz2016). Both approaches align with the concept of the ideal dietary AA pattern for piglets, where the requirements for essential AAs are expressed relative to the requirement for the first limiting AA, Lys, such as SID His: Lys (Fuller et al. Reference Fuller, McWilliam and Wang1989; Wang and Fuller Reference Wang and Fuller1989). Among cereals, barley has the lowest His content (Li et al. Reference Li, Zhang and Gong2002). Hence, low-crude protein (CP) diets based on barley need extra His supplementation in the feed.

The protein level and other essential AA content in diets influence the His requirements of piglets. Studies have shown that in pigs fed low-protein diets, AA metabolism undergoes significant changes, with a particular reduction in His. This highlights the importance of dietary components and nutrient levels as key factors influencing the His requirements of piglets (Yin et al. Reference Yin, Li and Zhu2017). According to the NRC (2012), animal proteins (e.g., fish meal, blood meal) commonly used in diets for weaned piglets are rich in His (e.g., fish meal contains approximately 2.5%) and have a high bioavailability. Thus, they are suitable for high-protein diets and can meet the His requirements of piglets without additional L-His supplementation. Conversely, plant-based proteins (e.g., soybean meal, corn) contain low levels of His (soybean meal has about 1.2%, and corn has about 0.3%) and have a lower digestibility (SID His of approximately 80%–85%). When formulating low-protein diets, extra L-His must be added to these diets to prevent His deficiency. High-protein diets (>22% CP) based on fish meal or other animal proteins usually cover the His requirement without extra supplementation. Low-protein diets (<18% CP) based on corn-soybean meal must be corrected by adding crystalline L-His. Use the following formula from NRC (2012): Supplemental SID His (%) = Target SID His Σ (Ingredient His (%) × SID His coefficient). Example for a 7-kg piglet (target SID His = 0.36%): 65% corn: 0.27% His × 0.85 SID = 0.149%; 25% soybean meal: 1.30% His × 0.82 SID = 0.267%; 5% fish meal: 2.45% His × 0.92 SID = 0.113%; Σ SID His supplied = 0.149 + 0.267 + 0.113 = 0.529% → 0.529% × 0.95 = 0.503%; Supplemental L-His needed = 0.36%–0.503% ≈ –0.14% → 0% (diet already adequate). Typical low-protein corn-soy diets require 0.05%–0.08% additional SID His. Formulators should also: keep Leu: Lys ≤ 1.5 to avoid antagonism (INRAE 2018); ensure adequate Met + Cys to prevent compensatory His oxidation; adjust absolute His intake when low-energy diets increase feed intake (CVB 2016).

Antibiotics

Instead of extrapolating from a single antibiotic study, we now report the only available piglet dataset together with its limitations (Yu et al. Reference Yu, Mu and Yang2017). showed that a 50 mg kg−1 cocktail of quinocetone, tylosin, and kitasamycin increased serum His (+18%) and up-regulated jejunal ASCT2 and B⁰AT1 mRNA in 21-day-old piglets. However, these effects disappeared when the same basal diet was fed antibiotic-free, and no follow-up work has examined whether withdrawal of antimicrobials changes the quantitative His requirement. Consequently, the data cannot yet be used to adjust dietary His recommendations for antibiotic-free production systems, and targeted dose–response trials under commercial, antibiotic-free conditions are warranted.

The international ban on antibiotics has spurred research into natural, green, and safe alternatives like antimicrobial peptides. Antimicrobial peptides, as the hottest candidates, are currently widely studied (Kim et al. Reference Kim, Cho and Jang2023). However, compared to the well-studied antibiotics, there’s a dearth of research on the impact of antibiotic-free feed on piglets’ His requirements.

Breed, body weight, and gender of piglets

Differences exist in AA utilization and growth rates of weaned piglets of diverse breeds influenced by genetic background, dietary nutrients, and environment (Ma et al. Reference Ma, Chen and Gan2022). Studies comparing Landrace, Yorkshire, and Duroc pigs have found that Duroc pigs have the most enriched ribosomal biogenesis, amino-acid-related enzymes, lysine biosynthesis, and glycine, serine, and threonine metabolism pathways. As these pathways are key for protein synthesis and AA utilization (Ma et al. Reference Ma, Chen and Gan2022), it can be inferred that different pig breeds may also influence His requirements.

As piglets grow and their body weight increases, the digestibility of dietary His gradually improves, leading to a decrease in the requirement for dietary His. According to the NRC (2012), the SID His requirement for weaned piglets in the 7–11 kg phase is 0.39%, while for piglets in the 11–25 kg phase, the requirement is 0.35%. Most current studies on AA requirements for piglets haven’t differentiated between genders, so there’s almost no research on how gender affects His requirements for piglets. INRAE (2018) suggests that gender may influence nutritional requirements but doesn’t specify details.

In conclusion, piglet His requirements are influenced by dietary composition, genetic background, and body weight, necessitating tailored feed formulations.

Summary

His contributes to protein synthesis in piglets, slightly boosting their growth and improving dietary AA balance. Along with its derivatives, His also enhances piglet gut health by maintaining GI barrier function, reducing inflammation, promoting digestion and nutrient absorption, and modulating gut microbiota balance. The specific mechanisms of how His regulates the dynamic balance between gut microbiota, immune function, and gut barrier, as well as its interactions with other AAs, require further research. This research is crucial for advancing precise nutrition strategies and improving the efficiency and cost-effectiveness of pig production. Looking ahead, future work should concentrate on defining dynamic His requirements for weaned piglets under antibiotic-free, low-protein diets by integrating breed, sex, and gut-microbiome data, while validating practical dose-response models that can be directly adopted in commercial feed formulation.

Acknowledgements

This work was supported by the National Key Research and Development Program of China (2021YFD1300402), the National Natural Science Foundation of China (U24A20447, 32202730, 32172777), and the earmarked fund for CARS (CARS-35).

Conflict(s) of Interest

The authors declare no competing interests.

References

Aoyama, Y, Takagi, M and Yoshida, A (1999) Lipid alterations in the liver and serum of rats in histidine-excess and copper deficiency. Journal of Nutritional Science and Vitaminology (Tokyo) 45(6), 773783. https://doi.org/10.3177/jnsv.45.773.Google Scholar
Bhattacharya, SK and Das, N (1985) Anti-inflammatory effect of intraventricularly administered histamine in rats. Agents Actions 17(2), 150152. https://doi.org/10.1007/bf01966584.Google Scholar
Boldyrev, AA, Aldini, G and Derave, W (2013) Physiology and pathophysiology of carnosine. Physiological Reviews. 93(4), 18031845. https://doi.org/10.1152/physrev.00039.2012.Google Scholar
Branco, A, Yoshikawa, FSY, Pietrobon, AJ et al. (2018) Role of histamine in modulating the immune response and inflammation. Mediators of Inflammation 2018, 9524075. https://doi.org/10.1155/2018/9524075.Google Scholar
Bröer, S (2008) Amino acid transport across mammalian intestinal and renal epithelia. Physiological Reviews. 88(1), 249286. https://doi.org/10.1152/physrev.00018.2006.Google Scholar
Brosnan, ME and Brosnan, JT (2020) Histidine metabolism and function. The Journal of Nutrition. https://doi.org/10.1093/jn/nxaa079.Google Scholar
Buffie, CG and Pamer, EG (2013) Microbiota-mediated colonization resistance against intestinal pathogens. Nature Reviews Immunology 13(11), 790801. https://doi.org/10.1038/nri3535.Google Scholar
Cemin, HS, Tokach, MD, Dritz, SS et al. (2019) Meta-regression analysis to predict the influence of branched-chain and large neutral amino acids on growth performance of pigs1. Journal of Animal Science 97(6), 25052514. https://doi.org/10.1093/jas/skz118.Google Scholar
Cemin, HS, Vier, CM, Tokach, MD et al. (2018) Effects of standardized ileal digestible histidine to lysine ratio on growth performance of 7- to 11-kg nursery pigs. Journal of Animal Science 96(11), 47134722. https://doi.org/10.1093/jas/sky319.Google Scholar
Cheng, YC, Lee, HL, Hwang, Y et al. (2023) The effects of standardized ileal digestible His to Lys ratio on growth performance, intestinal health, and mobilization of histidine-containing proteins in pigs at 7 to 11 kg body weight. Journal of Animal Science 101, 19. https://doi.org/10.1093/jas/skac396.Google Scholar
Cholera in the Americas (1991) Cholera in the Americas. Bull Pan Am Health Organ 25(3), 267273.Google Scholar
Du, S, Sun, S, Liu, L et al. (2017) Effects of histidine supplementation on global serum and Urine (1)H NMR-based metabolomics and serum amino acid profiles in obese women from a randomized controlled study. Journal of Proteome Research 16(6), 22212230. https://doi.org/10.1021/acs.jproteome.7b00030.Google Scholar
Dyduch, A, Geisler, G, Pieniazek, W et al. (1996) [Physiological and pathophysiological role of histamine in the gastrointestinal tract]. Pediatria Polska 71(6), 297302.Google Scholar
Erickson, MC and Hultin, HO (1992) Influence of histidine on lipid peroxidation in sarcoplasmic reticulum. Archives of Biochemistry and Biophysics 292(2), 427432. https://doi.org/10.1016/0003-9861(92)90012-l.Google Scholar
Fiorani, M, Enrico, DVL, Pasquale, D et al. (2023) Histamine-producing bacteria and their role in gastrointestinal disorders. Expert Review of Gastroenterology & Hepatology 17(7), 709718. https://doi.org/10.1080/17474124.2023.2230865.Google Scholar
Fuller, MF, McWilliam, R, Wang, TC et al. (1989) The optimum dietary amino acid pattern for growing pigs. 2. Requirements for maintenance and for tissue protein accretion. The British Journal of Nutrition 62(2), 255267. https://doi.org/10.1079/bjn19890028.Google Scholar
Gao, HN, Hu, H, Zheng, N et al. (2015) Leucine and histidine independently regulate milk protein synthesis in bovine mammary epithelial cells via mTOR signaling pathway. Journal of Zhejiang University Science B 16(6), 560572. https://doi.org/10.1631/jzus.B1400337.Google Scholar
Glover, CN and Wood, CM (2008) Histidine absorption across apical surfaces of freshwater rainbow trout intestine: Mechanistic characterization and the influence of copper. Journal of Membrane Biology 221(2), 8795. https://doi.org/10.1007/s00232-007-9088-y.Google Scholar
Harper, AE, Benevenga, NJ and Wohlhueter, RM (1970) Effects of ingestion of disproportionate amounts of amino acids. Physiological Reviews. 50(3), 428558. https://doi.org/10.1152/physrev.1970.50.3.428.Google Scholar
Hasegawa, S, Ichiyama, T, Sonaka, I et al. (2012) Cysteine, histidine and glycine exhibit anti-inflammatory effects in human coronary arterial endothelial cells. Clinical and Experimental Allergy 167(2), 269274. https://doi.org/10.1111/j.1365-2249.2011.04519.x.Google Scholar
He, RR, Yao, N, Wang, M et al. (2009) Effects of histamine on lipid metabolic disorder in mice loaded with restraint stress. Journal of Pharmacological Sciences 111(2), 117123. https://doi.org/10.1254/jphs.09090fp.Google Scholar
Hirasawa, N (2019) Expression of histidine decarboxylase and its roles in Inflammation. International Journal of Molecular Sciences 20(2), 376. https://doi.org/10.3390/ijms20020376.Google Scholar
Holeček, M (2020) Histidine in health and disease: metabolism, physiological importance, and use as a supplement. Nutrients 12(3), 848. https://doi.org/10.3390/nu12030848.Google Scholar
Honkisz-Orzechowska, E, Popiołek-Barczyk, K, Linart, Z et al. (2023) Anti-inflammatory effects of new human histamine H(3) receptor ligands with flavonoid structure on BV-2 neuroinflammation. Inflammation Research 72(2), 181194. https://doi.org/10.1007/s00011-022-01658-z.Google Scholar
Inoue, R and Tsukahara, T (2021) Composition and physiological functions of the porcine colostrum. Animal Science Journal 92(1), e13618. https://doi.org/10.1111/asj.13618.Google Scholar
Izquierdo, OA, Wedekind, KJ and Baker, DH (1988) Histidine requirement of the young pig. Journal of Animal Science 66(11), 28862892. https://doi.org/10.2527/jas1988.66112886x.Google Scholar
Jutel, M, Watanabe, T, Akdis, M et al. (2002) Immune regulation by histamine. Current Opinion in Immunology. https://doi.org/10.1016/s0952-7915(02)00395-3.Google Scholar
Kang, M, Yin, J, Ma, J et al. (2020) Effects of dietary histidine on growth performance, serum amino acids, and intestinal morphology and microbiota communities in low protein diet-fed piglets. Mediators of Inflammation 2020, 1240152. https://doi.org/10.1155/2020/1240152.Google Scholar
Kim, H-M, Lee, CH and Rhee, C-S (2012) Histamine regulates mucin expression through H1 receptor in airway epithelial cells. Acta Oto-Laryngologica. https://doi.org/10.3109/00016489.2012.661075.Google Scholar
Kim, J, Cho, BH and Jang, YS (2023) Understanding the roles of host defense peptides in immune modulation: from antimicrobial action to potential as adjuvants. Journal of Microbiology & Biotechnology 33(3), 288298. https://doi.org/10.4014/jmb.2301.01005.Google Scholar
Krishnan, A, Verma, SK, Mani, P et al. (2009) A histidine switch in hemagglutinin-neuraminidase triggers paramyxovirus-cell membrane fusion. Journal Virol 83(4), 17271741. https://doi.org/10.1128/jvi.02026-08.Google Scholar
Leurs, R, Smit, MJ and Timmerman, H (1995) Molecular pharmacological aspects of histamine receptors. Pharmacology & Therapeutics 66(3), 413463. https://doi.org/10.1016/0163-7258(95)00006-3.Google Scholar
Li, DF, Zhang, JH and Gong, LM (2002) Optimum ratio of histidine in the piglet ideal protein model and its effects on the body metabolism. II. Optimum ratio of histidine in 10-20 KG piglet ideal protein and its effects on blood parameters. Archiv Für Tierernaehrung. https://doi.org/10.1080/00039420214187.Google Scholar
Liang, H, Xu, P, Xu, G et al. (2022) Histidine deficiency inhibits intestinal antioxidant capacity and induces intestinal endoplasmic-reticulum stress, inflammatory response, apoptosis, and necroptosis in largemouth bass (micropterus salmoides). Antioxidants (Basel) 11(12), 23992413. https://doi.org/10.3390/antiox11122399.Google Scholar
Lim, HD, Smits, RA, Leurs, R et al. (2006) The emerging role of the histamine H4 receptor in anti-inflammatory therapy. Current Topics in Medicinal Chemistry, 6(3), 279286.Google Scholar
Liu, P, Huang, F, Lin, P et al. (2025) Histidine metabolism drives liver cancer progression via immune microenvironment modulation through metabolic reprogramming. Journal of Translational Medicine 23(1), 262. https://doi.org/10.1186/s12967-025-06267-y.Google Scholar
Lopez, MJ and Mohiuddin, SS (2025) Biochemistry, Essential Amino Acids. In StatPearls. StatPearls Publishing. StatPearls Publishing LLC. https://www.ncbi.nlm.nih.gov/books/NBK557845/.Google Scholar
Lorenz, W, Thon, K, Barth, H et al. (1983) Metabolism and function of gastric histamine in health and disease. Journal of Clinical Gastroenterology 5(Suppl 1), 3756. https://doi.org/10.1097/00004836-198312001-00005.Google Scholar
Ma, J, Chen, J, Gan, M et al. (2022) Gut microbiota composition and diversity in different commercial Swine breeds in early and finishing growth stages. Animals (Basel) 12(13). https://doi.org/10.3390/ani12131607.Google Scholar
Maeshima, T, Honda, K, Chikazawa, M et al. (2012) Quantitative analysis of acrolein-specific adducts generated during lipid peroxidation–modification of proteins in vitro: identification of Nτ-(3-Propanal)histidine as the major adduct. Chemical Research in Toxicology. https://doi.org/10.1021/tx3000818.Google Scholar
Mahadoo, J, Jaques, LB and Wright, CJ (1981) Lipid metabolism: The histamine-glycosaminoglycan-histaminase connection. Medical Hypotheses 7(8), 10291038. https://doi.org/10.1016/0306-9877(81)90098-0.Google Scholar
Matsui, T, Ichikawa, H, Fujita, T et al. (2019) Histidine and arginine modulate intestinal cell restitution via transforming growth factor-β(1). European Journal Pharmacology 850, 3542. https://doi.org/10.1016/j.ejphar.2019.02.006.Google Scholar
Nagao, T, Nakayama-Imaohji, H, Elahi, M et al. (2018) L-histidine augments the oxidative damage against Gram-negative bacteria by hydrogen peroxide. International Journal of Molecular Medicine 41(5), 28472854. https://doi.org/10.3892/ijmm.2018.3473.Google Scholar
Poli, E, Pozzoli, C and Coruzzi, G (2001) Role of histamine H(3) receptors in the control of gastrointestinal motility. An overview. Journal of Physiology, Paris 95(1-6), 6774. https://doi.org/10.1016/s0928-4257(01)00010-9.Google Scholar
Quesada-Vázquez, S, Castells-Nobau, A, Latorre, J et al. (2023) Potential therapeutic implications of histidine catabolism by the gut microbiota in NAFLD patients with morbid obesity. Cell Reports Medicine 4(12), 101341. https://doi.org/10.1016/j.xcrm.2023.101341.Google Scholar
Rabbani, GH, Sack, DA, Ahmed, S et al. (2005) Antidiarrheal effects of L-histidine-supplemented rice-based oral rehydration solution in the treatment of male adults with severe cholera in Bangladesh: A double-blind, randomized trial. Journal of Infectious Diseases 191(9), 15071514. https://doi.org/10.1086/428449.Google Scholar
Radermecker, MF and Bury, T (1989) Anti-inflammatory effects of histamine. Bulletin et memoires de l’Academie royale de medecine de Belgique 144, 255262.Google Scholar
Schokker, D, Zhang, J, Vastenhouw, SA et al. (2015) Long-lasting effects of early-life antibiotic treatment and routine animal handling on gut microbiota composition and immune system in pigs. PLoS One 10(2), e0116523. https://doi.org/10.1371/journal.pone.0116523.Google Scholar
Sgambellone, S, Febo, M, Durante, M et al. (2023) Role of histamine H4 receptor in the anti-inflammatory pathway of glucocorticoid-induced leucin zipper (GILZ) in a model of lung fibrosis. Inflammation Research. https://doi.org/10.1007/s00011-023-01802-3.Google Scholar
Shi, J, de Roos, A, Schouten, O et al. (2015) Properties of hemoglobin decolorized with a histidine-specific protease. Journal of Food Science 80(6), E12021208. https://doi.org/10.1111/1750-3841.12809.Google Scholar
Sirois, J, Ménard, GV, Moses, AS et al. (2000) Importance of histamine in the cytokine network in the lung through H2 and H3 receptors: Stimulation of IL-10 production. The Journal of Immunology. https://doi.org/10.4049/jimmunol.164.6.2964.Google Scholar
Stein, HH, Sève, B, Fuller, MF et al. (2007) Invited review: Amino acid bioavailability and digestibility in pig feed ingredients: Terminology and application. Journal of Animal Science 85(1), 172180. https://doi.org/10.2527/jas.2005-742.Google Scholar
Tan, L, Li, J, Wang, Y et al. (2019) Anti-Neuroinflammatory effect of alantolactone through the suppression of the NF-κB and MAPK signaling pathways. Cells 8(7), 739754. https://doi.org/10.3390/cells8070739.Google Scholar
Tanaka, T, Yamamoto, J, Iwasaki, S et al. (2003) Activation of peroxisome proliferator-activated receptor delta induces fatty acid beta-oxidation in skeletal muscle and attenuates metabolic syndrome. Proceedings of the National Academy of Sciences of the United States of America 100(26), 1592415929. https://doi.org/10.1073/pnas.0306981100.Google Scholar
Tang, Q, Li, W, Ren, Z et al. (2023) Different fatty acid supplementation in low-protein diets regulate nutrient utilization and lipid and amino acid metabolism in weaned pigs model. International Journal of Molecular Sciences 24(10). https://doi.org/10.3390/ijms24108501.Google Scholar
Tang, X, Liu, H, Yang, S et al. (2016) Epidermal growth factor and intestinal barrier function. Mediators of Inflammation 2016, 1927348. https://doi.org/10.1155/2016/1927348.Google Scholar
Tang, X, Liu, X, Zhong, J et al. (2021) Potential application of lonicera japonica extracts in animal production: from the perspective of intestinal health. Frontiers in Microbiology 12, 719877. https://doi.org/10.3389/fmicb.2021.719877.Google Scholar
Tang, X, Xiong, K, Fang, R et al. (2022) Weaning stress and intestinal health of piglets: A review. Frontiers in Immunology 13, 1042778. https://doi.org/10.3389/fimmu.2022.1042778.Google Scholar
van Milgen, J and Le Floc’h, N (2021) 8 functional role of histidine in diets of young pigs. Journal of Animal Science. https://doi.org/10.1093/jas/skab054.022.Google Scholar
Wang, J, Zhu, H, Chen, Z et al. (2024) Histidine-derived carbon dots for redox modulation and gut microbiota regulation in inflammatory bowel disease therapy. Chemical Engineering Journal. https://doi.org/10.1016/j.cej.2024.156389.Google Scholar
Wang, KY, Tanimoto, A, Yamada, S et al. (2010) Histamine regulation in glucose and lipid metabolism via histamine receptors: Model for nonalcoholic steatohepatitis in mice. American Journal of Pathology 177(2), 713723. https://doi.org/10.2353/ajpath.2010.091198.Google Scholar
Wang, TC and Fuller, MF (1989) The optimum dietary amino acid pattern for growing pigs. 1. Experiments by amino acid deletion. The British Journal of Nutrition 62(1), 7789. https://doi.org/10.1079/bjn19890009.Google Scholar
Wang, X and Proud, CG (2006) The mTOR pathway in the control of protein synthesis. Physiology (Bethesda). 21, 362369. https://doi.org/10.1152/physiol.00024.2006.Google Scholar
Wessels, AG, Kluge, H, Mielenz, N et al. (2016) Estimation of the leucine and histidine requirements for piglets fed a low-protein diet. Animal 10(11), 18031811. https://doi.org/10.1017/s1751731116000823.Google Scholar
Wu, J, Egusa, A and Nishimura, T (2022a) Carnosine synthase deficiency in mice affects protein metabolism in skeletal muscle. Biochemical and Biophysical Research Communications 612, 2229. https://doi.org/10.1016/j.bbrc.2022.04.075.Google Scholar
Wu, J, Wu, Y, Feng, W et al. (2022b) Role of microbial metabolites of histidine in the development of colitis. Molecular Nutrition and Food Research. https://doi.org/10.1002/mnfr.202101175.Google Scholar
Wu, Y, Zhao, J, Xu, C et al. (2018) Progress towards pig nutrition in the last 27 years. Journal of the Science of Food & Agriculture. https://doi.org/10.1002/jsfa.9095.Google Scholar
Yang, S, Chu, S, Ai, Q et al. (2020) Anti-inflammatory effects of higenamine (Hig) on LPS-activated mouse microglia (BV2) through NF-κB and Nrf2/HO-1 signaling pathways. International Immunopharmacology 85, 106629. https://doi.org/10.1016/j.intimp.2020.106629.Google Scholar
Yin, J, Li, Y, Zhu, X et al. (2017) Effects of long-term protein restriction on meat quality, muscle amino acids, and amino acid transporters in pigs. Journal of Agricultural and Food Chemistry 65(42), 92979304. https://doi.org/10.1021/acs.jafc.7b02746.Google Scholar
Yin, J, Wu, MM, Xiao, H et al. (2014) Development of an antioxidant system after early weaning in piglets. Journal of Animal Science 92(2), 612619. https://doi.org/10.2527/jas.2013-6986.Google Scholar
Yu, M, Mu, C, Yang, Y et al. (2017) Increases in circulating amino acids with in-feed antibiotics correlated with gene expression of intestinal amino acid transporters in piglets. Amino Acids 49(9), 15871599. https://doi.org/10.1007/s00726-017-2451-0.Google Scholar
Zhao, B, Feng, L, Liu, Y et al. (2011) Effects of dietary histidine levels on growth performance, body composition and intestinal enzymes activities of juvenile Jian carp (Cyprinus carpio var. Jian). Aquaculture Nutrition. https://doi.org/10.1111/j.1365-2095.2011.00898.x.Google Scholar
Figure 0

Figure 1. Chemical structure formula of L-histidine.

Figure 1

Figure 2. The metabolic pathways of histidine in piglets.

Note: Compared to rodents or humans, weaned piglets exhibit 30%–40% lower hepatic histidase activity, making the cis-urocanate → trans-urocanate conversion a rate-limiting step (indicated by a bold red arrow). GDH, glutamate dehydrogenase; GS, glutamine synthetase; ALT, alanine aminotransferase; TA, transaminase; THF, tetrahydrofolate.
Figure 2

Figure 3. Histidine exerts its immune functions in piglets.

Note: IgG, immunoglobulin G; NF-κB, nuclear factor kappa-light-chain-enhancer of activated B cells; H1–H4R, histamine receptor 1–4; H2R, histamine receptor 2; H4R, histamine receptor 4; cAMP-PKA, cyclic adenosine monophosphate–protein kinase A; IL-10, interleukin-10; TGF-β, transforming growth factor-beta; TNF-α, tumor necrosis factor-alpha; COX-2, cyclooxygenase-2; Nrf2/HO-1, nuclear factor E2-related factor 2/heme oxygenase-1 (this figure is created in BioRender.com).
Figure 3

Table 1. The recommended levels of SID histidine for different weight stage piglets are provided by official or authoritative bodies across various countries

Figure 4

Table 2. The recommended levels of SID histidine for piglets