By integrating genome data from 15 globally representative poultry breeds, Chinese scholars built the first high-quality pan-genome assembly for poultry. This work identified genes related to immune pathways located in chromatin subtelomeric regions and microchromosomes, shedding light on poultry evolution [3]. Furthermore, in 2023, researchers identified 10 chicken microchromosomes with high guanine-cytosine content and highly methylated tandem repeats, resembling the W chromosome, highlighting unique genetic adaptations [4]. Pedigree analysis also reveals genetic connections among Chinese poultry breeds. For instance, an analysis of five gamecock breeds and nine indigenous chicken breeds demonstrated that southern Chinese domestic chickens played a significant role in the domestication of gamecocks [5]. Gene expression in poultry is regulated by numerous unknown transcription factors. By analyzing 377 whole-genome sequencing datasets from 23 adult chicken tissues, researchers predicted approximately 1.2 million enhancer gene pairs and 7,662 super-enhancers, providing a valuable resource for future research [6].

The combination of host genetics and microorganisms significantly impacts poultry performance. For example, a study analyzing genome, microbial composition, and residual feed intake in 206 male yellow-feather dwarf broilers found that host genetics contributed 39%, while intestinal microorganisms in different regions had varying effects: duodenum (14%), cecum (28%), feces (10%), and jejunum and ileum (0%) [7]. Similarly, in female Rhode Island Red chickens, feed conversion efficiency was influenced by genetics (28%) and the intestinal microbiome, with regional contributions from the jejunum (3%), ileum (15%), feces (10%), and others (duodenum and cecum) showing no effect. Residual feed intake was influenced by both genetics (48%) and gut microbes, with contributions from the jejunum (20%), cecum (11%), feces (10%), and other regions (duodenum and ileum) [8]. These findings suggest that host genetics may influence poultry performance through the gut microbiome. The genomic catalog of intestinal microbes provides basic information for analyzing the mechanism of microbial effect on poultry production performance. Advances in gut microbiome research have further enriched the field. A comprehensive chicken gut microbiome catalog has been established, including 18,201 bacterial genomes, 225 archaeal metagenome-assembled genomes, and 33,411 viral genomes. Researchers also identified 812 hypothetical species and 240 hypothetical bacterial genera, providing foundational data for analyzing microbial effects on poultry production performance [9].

In summary, significant progress has been made in building rich genome and microbiome databases. In the future, it will be essential to continuously expand the genome and microbiome databases, while identifying potential targets to further enhance poultry production performance.

Guangming white-feather broiler, yellow-feathered broilers, Jinghong laying layers and Zhongxing ducks.

High production performance is a crucial economic indicator in poultry farming. High-performing poultry breeds have been developed by identifying and selecting key gene loci. Many studies continue to explore critical targets for regulating production performance. To investigate the mechanisms underlying high meat production, a study compared the genomes of high-performance chickens and local breeds. The analysis identified 83 differentially expressed genes, primarily associated with muscle development, with the myosin heavy polypeptide 1 (MHY1) gene being the most representative [10]. However, high growth performance in white-feather broilers is often accompanied by excessive abdominal fat deposition, which limits improvements in feed efficiency. By integrating genomics, epigenomics, 3D genomics, and transcriptomics, researchers constructed a comprehensive gene regulatory network. This revealed that the rs734209466 variant promotes the transcription of insulin like growth factor binding protein (IGFBP) 2 and IGFBP5 by binding to the transcription factor interferon regulatory factor 4 (IRF4), thereby influencing preadipocyte proliferation and differentiation [11]. Muscle lipid content is another key factor, significantly affecting the taste and nutritional value of meat. Using Jingxin yellow-feather broilers as breeding material, researchers bred a high intramuscular fat line to enhance meat quality [12]. Similarly, laying rate is a critical economic trait in poultry. By integrating multi-omics data from various tissues of Hy-Line Brown laying hens with differing laying rates, several candidate genes were identified. These include tissue factor pathway inhibitor 2 (TFPI2) (promoting gonadotropin-releasing hormone secretion in hypothalamic neurons), follicle stimulating hormone beta (FSHβ) and luteinizing hormone beta (LHβ) (stimulating pituitary cell secretion), osteocrin (OSTN) (enhancing granulosa cell proliferation and steroid hormone synthesis), apolipoprotein A4 (APOA4) in the liver, and angiopoietin like 2 (ANGPTL2) in adipose tissue [13].

Three specialized lines were bred: a meat line (At 10 weeks of age, male body weight increased about 300 g; female body weight increased about 120 g), an egg-laying line (To improve egg production rate and egg quality), and a disease-resistant line (enhanced resistance to salmonella by reducing the heterophil-to-lymphocyte ratio) [20].

A precise nutrition standard tailored to the age and physiological state of Lueyang black-boned chickens was established, significantly enhancing their production efficiency.

Based on the natural living habits of Lueyang black-boned chickens in mountainous regions, a breeding system was adopted that involves cage rearing during the brooding period and free-range rearing during the growing period. This approach respects the animals’ natural behaviors while improving growth efficiency.

Based on the disease challenges faced by Lueyang black-boned chickens, the mortality rate was significantly reduced through the implementation of an individualized standard plan, which included provenance purification, tailored vaccination schedules, and strict feeding management.

Collaboration with food scientists to create new products that leverage the unique flavor and nutritional value of Lueyang black-boned chicken.

Incorporation of high-quality Chinese herbs from the Qinling Mountains into feed to produce functional poultry products.

Over more than a decade of systematic breeding of Lueyang black-boned chickens, coupled with the formulation of specialized feeding management programs and the development of distinctive poultry products, the breeding population has grown from 2.03 million birds in 2010 to 2.95 million birds in 2024 [21,22].

The digestion and absorption efficiency of feed nutrients is the most intuitive index to evaluate the digestion and absorption function of livestock and poultry, which can be determined by digestion test and metabolism test [26]. In addition, the digestion and absorption function of livestock and poultry can also be evaluated by measuring key factors in the process of digestion and absorption, such as digestive enzymes and transporters [27]. For example, our research examined the developmental characteristics of digestive and absorptive capacity in Arbor Acres broilers [28].

Physical barriers ensure the digestion and absorption of nutrients in the alimentary tract, maintain the permeability of the alimentary tract, and prevent harmful substances or pathogenic microorganisms from entering the body. Physical barriers, including villi, crypts, and tight junctions, maintain gut permeability and nutrient absorption while preventing pathogen entry [29]. Our studies found that accessible fiber, acting as a microbial substrate, regulates the mucosal barrier through short-chain fatty acids and bile acids [30]. Additionally, Chinese herbs, such as astragalus polysaccharide, enhance barrier function by increasing the abundance of Parabacteroides in the gut [31].

The specific chemical barrier of the digestive tract not only maintains the homeostasis of flora and prevents harmful microorganisms from contacting the intestinal epithelium, but also plays a signal regulation role through the specific binding of microbial metabolites to specific sites to maintain the health of the gut and the host. The digestive tract chemical barrier mainly includes the internal acid-base environment, volatile fatty acids, digestive enzymes, bile acids and other epithelial cell secretions or microbial metabolites [32]. For example, injecting Lactobacillus plantarum (isolated from Chinese sauerkraut) into Arbor Acres broilers embryos promoted beneficial gut microbiota and short-chain fatty acid production, improving poultry performance [33].

Stable gastrointestinal microbiota is of great significance to inhibit the colonization of pathogens in the intestine, improve livestock performance and feed use efficiency [34].

Probiotics and prebiotics help establish healthy gut microbiota. Our lab found that oregano extract supplementation improved broiler productivity by improving beneficial microorganisms growth [35]. Similarly, folic acid supplementation influenced microbial regulation of lipid metabolism, enhancing poultry performance [36,37]. Besides, recent studies have focused on the establishment and differentiation of microbiota-host-gut types, and microbial colonization is affected by diet, age, and gut location, as well as their interactions [38]. Among them, the temporal and spatial abundance of some specific microbial taxa is related to feed efficiency traits of livestock and poultry [39,40], which can enable the host to effectively use dietary proteins and carbohydrates, thereby improving feed use efficiency [41]. Regulation of microbial-host interactions may be considered in future work as a nutritional strategy to improve feed efficiency in livestock and poultry.

The mucosal immune system is the site where the intestine contacts foreign antigens, initially forms immune responses, and performs local non-specific immune functions. Secretory immunoglobulin A (sIgA) plays an important role in intestinal mucosal immunity, including immune rejection, antigen presentation, and interaction with the intestinal symbiont [42,43]. In addition, the expression of intestinal cytokines is also an important indicator. In particular, the levels of pro-inflammatory factors TNF-α, IL -1β, IL-6, IFN-γ and anti-inflammatory factor IL-10 were detected.

Poultry feed represents a significant portion of farming costs, with traditional feed sources primarily relying on external procurement. However, in Poultry-Crop Integrating systems, by-products from the planting stage, such as straw, corn cobs, and soybean stalks, can be easily processed and used as poultry feed [68]. This approach not only reduces farming costs but also alleviates the burden of agricultural waste disposal [69]. For example, corn straw can be crushed and mixed with other feed ingredients to serve as coarse feed for chickens and ducks; while rice bran can be incorporated into poultry diets. This method effectively utilizes waste from the planting stage, creating a closed-loop resource cycle.

Poultry farming in China is categorized into intensive farming and ecological farming. Intensive farming is efficient for collecting poultry waste, making centralized disposal easier compared to ecological farming. Currently, intensive poultry enterprises in China have begun returning treated poultry manure to fields. However, the proportion of manure being recycled back into fields and the efficiency of this process remain low.

Ecological free-range farming is a poultry farming method that integrates the concept of Poultry-Crop Integrating Systems. The “rice-duck co-culture” model is a successful example promoted in rural China [70]. In this model, poultry are allowed to roam freely in planting areas, where they can forage on insects, weeds, and crop residues while their manure is directly deposited in the fields, serving as natural fertilizer [71]. For example, in orchards, chickens peck at insect eggs and weeds on the ground, thereby reducing the need for pesticide, while their manure enriches the soil. In rice paddies, ducks can eat pests and weeds, decreasing the reliance on pesticides and herbicides, while their droppings act as fertilizer, promoting rice growth. This “pastoral” free-range model not only reduces feed consumption but also promotes soil fertility cycling [72]. This approach reduces the reliance on chemical fertilizers and pesticides, while significantly enhancing both crop yield and quality [73].

The processing of poultry products generates various by-products, such as feathers, fat, and blood, which can be effectively utilized as feed raw materials to enhance the efficiency of resource utilization. However, the current reuse of these by-products remains insufficient. The primary challenges include a lack of recognition of their value and the absence of specialized recycling channels.

Poultry manure is an efficient organic fertilizer that, when proper treated, can be directly returned to the fields. This enhances soil structure, increases organic matter content, and improves soil fertility. The nutrient content, particularly nitrogen, in poultry manure significantly promotes crop growth [74]. However, applying untreated poultry manure directly can lead to environmental pollution and the spread of pathogens, necessitating treatment through composting or fermentation to produce harmless organic fertilizer. In practice, farms typically send collected poultry manure to composting facilities for fermentation. High-temperature fermentation kills pathogens and weed seeds while decomposing organic matter, forming stable humus. This treated organic fertilizer not only provides nutrients for crops but also improves soil structure and increases the soil’s ability to retain water and nutrients [75].