Search Results (160)

Winter wheat (Triticum aestivum L.) silage has high feeding value and has become an important roughage resource in China. To recognize the optimal fermentation time of the silage product, this study systematically evaluated the temporal dynamics of microbial communities and metabolic profiles in whole winter wheat silage at days 7, 14, 30, 50, and 70. The dry matter (DM) content slightly fluctuated with the extension of fermentation time, with 28.14% at 70 days of ensiling. The organic matter and neutral detergent fiber content gradually decreased with the extension of fermentation time. A significant decrease in pH was observed at days 30, 50, and 70 compared to days 7 and 14 (p < 0.05), with the lowest pH value of 4.4 recorded at day 70. The contents of lactic acid, acetic acid, butyric acid, and total volatile fatty acids gradually increased with the extension of fermentation time, reaching a maximum at 70 days of ensiling. The dominant bacteria were Proteobacteria and Firmicutes at the phylum level, and the predominant bacteria were Hafnia-Obesumbacterium, Enterobacter, and Lactobacillus at the genus level. The relative abundance of Hafnia-Obesumbacterium and Lactobacillus fluctuated slightly with the duration of fermentation, reaching a minimum for the former and a maximum for Lactobacillus at 50 days of ensiling. By day 70, Sporolactobacillus emerged as a distinct silage biomarker. The dominant fungi was Ascomycota at the phylum level, and the predominant fungi were Fusarium and an unidentified fungus at the genus level. The correlation analysis revealed significant pH–organic acid–microbe interactions, with pH negatively correlating with organic acids but positively with specific bacteria, while organic acids showed complex microbial associations. Collectively, under natural fermentation conditions, the optimal fermentation period for wheat silage exceeds 70 days, and Sporolactobacillus shows potential as a microbial inoculant for whole winter wheat silage. These findings provide a theoretical foundation for optimizing whole winter wheat silage utilization and enhancing fermentation quality. Full article

Against the backdrop of the green circular economy, the exploration of reliable and sustainable applications of lignocellulosic biomass (LCBM) has emerged as a critical research frontier. The utilization of LCBM as a ruminant roughage source offers a promising strategy to address two pressing issues: the “human-animal competition for food” dilemma and the environmental degradation resulting from improper LCBM disposal. However, the high degree of lignification in LCBM significantly restricts its utilization efficiency in ruminant diets. In recent years, microbial pretreatment has gained considerable attention as a viable approach to reduce lignification prior to LCBM application as ruminant feed. White-rot fungi (WRF) have emerged as particularly noteworthy among various microbial agents due to their environmentally benign characteristics and unique lignin degradation selectivity. WRF demonstrates remarkable efficacy in enzymatically breaking down the rigid lignocellulosic matrix (comprising lignin, cellulose, and hemicellulose) within LCBM cell walls, thereby reducing lignin content—a largely indigestible component for ruminants—while simultaneously enhancing the nutritional profile through increased protein availability and improved digestibility. Solid-state fermentation mediated by WRF enhances LCBM utilization rates and optimizes its nutritional value for ruminant consumption, thereby contributing to the advancement of sustainable livestock production, agroforestry systems, and global environmental conservation efforts. This review systematically examines recent technological advancements in WRF-mediated solid-state fermentation of LCBM, evaluates its outcomes of nutritional enhancement and animal utilization efficiency, and critically assesses current limitations and future prospects of this innovative approach within the framework of circular bioeconomy principles. Full article

Understanding the influence of the sheep breed and roughage source on the composition of rumen bacteria and methanogens is essential for optimizing roughage efficiency. The experiment employed a 2 × 2 factorial design. Twenty-four Dumont and Mongolian sheep (initial body weight of 18.94 ± 1.01 kg) were randomly assigned by breed to two dietary treatment groups (AH: alfalfa hay; CS: corn straw); the experiment lasted 90 days. The results showed that sheep fed alfalfa hay diets had a higher feed intake and weight gain, and Dumont sheep had a higher feed intake than Mongolian sheep (p < 0.05). The diversity and composition of ruminal bacteria and methanogens differed between Dumont and Mongolian sheep fed either AH or CS diets. The taxonomic analysis revealed a distinct clustering pattern based on the roughage source, but not on the breed. When fed a corn straw diet, the bacterial Chao1 index of Dumont sheep increased (p < 0.05), while the diversity and richness of methanogens in Mongolian sheep increased (p < 0.05). Additionally, we have identified unique biomarkers for the rumen bacteria and methanogens of Dumont and Mongolian sheep in response to different roughage sources. The results suggest that the differences in the microbiota of the sheep were associated with the roughage source and breed. The higher growth performance of Dumont sheep might be attributed to the increase in bacterial diversity and the decrease in methanogenic bacteria diversity. Full article

The objective of this study is to investigate the degradation characteristics of oat grass in the rumen of Mindong goats and changes in microbial community attached to the grass surface. Four healthy male goats, aged 14 months, with permanent rumen fistula, in eastern Fujian, were selected as experimental animals. The rumen degradation rate of oat grass was measured at 4, 12, 24, 36, 48, and 72 h using the nylon bag method. Surface physical structure changes in oat grass were observed using scanning electron microscopy (SEM), cellulase activity was measured, and bacterial composition was analyzed using high-throughput 16S rRNA gene sequencing technology. The findings of this study indicate that oat grass had effective degradation rates (ED) of 47.94%, 48.69%, 38.41%, and 30.24% for dry matter (DM), crude protein (CP), neutral detergent fiber (NDF), and acidic detergent fiber (ADF), respectively. The SEM was used to investigate the degradation process of oat grass in the rumen. After 24 h, extensive degradation of non-lignified tissue was observed, resulting in the formation of cavities. At 36 h, significant shedding was observed, and by 72 h, only the epidermis and thick-walled tissue, which exhibited resistance to degradation, remained intact. Surface-attached microorganisms produced β-GC, EG, CBH, and NEX enzymes. The activity of these enzymes exhibited a significant increase between 4 and 12 h and showed a positive correlation with the degradation rate of nutrients. However, the extent of correlation varied. Prevotella and Treponema were identified as key genera involved in the degradation of roughage, with their abundance decreasing over time. Principle Coordinate Analysis (PCOA) revealed no significant differences in the rumen microbial structure across different time points. However, Non-Metric Multidimensional Scaling (NMDS) indicated a discernible diversity order among the samples. According to the Spearman correlation coefficient test, Ruminococcus, Fibrobacter, and Saccharoferments exhibited the closest relationship with nutrient degradation rate and surface enzyme activity, displaying a significant positive correlation. In summary, this study delineates a time-resolved correlative framework linking microbial succession to structural and enzymatic dynamics during oat grass degradation. Full article

Utilizing straw feed is an effective strategy to optimize straw resource utilization by incorporating microbial degradation agents to expedite lignocellulose breakdown and enhance feed efficiency. Lignocellulose-degrading species and microbial communities are present in various Earth ecosystems, including the rumen of ruminants, insect digestive tracts, forest soil, and microbial populations in papermaking processes. The rumen of ruminants harbors a diverse range of microbial species, making it a promising source of lignocellulose-degrading microorganisms. Exploring alternative systems like insect intestines and forest soil is essential for future research. Current studies primarily rely on traditional microbial isolation techniques to identify lignocellulose-degrading strains, underscoring the necessity to transition to utilizing microbial culturomics and genome-editing technologies for discovering and manipulating cellulose-degrading microbes. This review provides an overview of lignocellulose-degrading microbial communities from diverse environments, encompassing bacterial and fungal populations. It also delves into the use of metagenomic, metatranscriptomic, and metaproteomic approaches to pinpoint highly efficient cellulase genes, along with the application of genome-editing tools for engineering lignocellulose-degrading microorganisms. The primary objective of this review is to offer insights for further exploration of potential lignocellulose-degrading microbial resources and high-performance cellulase genes to enhance roughage utilization in ruminant rumen ecosystems. Full article

The objective of this study is to isolate, identify, and describe rumen yeast strains and assess their probiotic potentials and effects on ruminal fermentation in vitro. Yeasts were isolated from ruminal fluids, yielding 59 strains from nine distinct species. A number of tests were conducted to assess their anaerobic traits, growth rate, acid tolerance, and lactate utilization ability, and a second screening in fresh ruminal fluid to evaluate in vitro pH and acid accumulation was conducted. The probiotic yeast Candida rugosa (NJ-5) was selected for in vitro culture studies on rumen fermentation. Finally, Candida rugosa (NJ-5) with good probiotic characteristics was chosen to investigate its effects on ruminal fermentation in vitro. The batch culture technique was used to explore the effects of Candida rugosa (NJ-5) yeast culture on rumen fermentation parameters. By altering the fermentation substrate to a concentrate-to-roughage ratio of 70:30, which simulated a high-concentration diet. The CON, LYC, MYC, and HYC groups were supplemented with 0%, 1%, 2%, and 5% Candida rugosa (NJ-5) yeast culture (dry matter basis), respectively. The pH value and volatile fatty acid (VFA) contents were determined at 6, 12, and 24 h after fermentation. The results showed that adding Candida rugosa (NJ-5) yeast culture successfully modulated in vitro rumen fermentation. Compared to the CON group, HYC had a significantly mitigated reduction in pH in fermentation, resulting in a significant increase in total VFAs and acetate levels (p < 0.05). Additionally, 16S rRNA sequencing revealed that Candida rugosa (NJ-5) yeast culture supplementation did not significantly alter ruminal bacterial alpha diversity (p > 0.05). At the phylum and genus taxonomic levels, Candida rugosa (NJ-5) yeast culture addition increased the relative abundance of several functionally important bacterial groups in the rumen microbial community. Compared to the CON group, the HYC group concurrently had an increased abundance of Desulfobacterota, Christensenellaceae_R-7_group, F082, and Ruminococcus (p < 0.05) but a significantly reduced abundance of Cyanobacteria, Bdellovibrionota, Succinivibrionaceae_UCG-002, Enterobacter, and Succinivibrio (p < 0.05). The in vitro fermentation experiment demonstrated that the optimal dry matter supplementation of Candida rugosa (NJ-5) into the basal diet was 5%, which could be effective for maintaining ruminal fermentation stability when ruminants were fed a high-concentrate diet. This study provides empirical support for the use of yeast as a nutritional supplement in ruminant livestock management, as well as a theoretical underpinning for further animal research. Full article

Due to its superior drought tolerance, high biomass yield, and stress resistance, sweet sorghum (Sorghum bicolor L.) has emerged as an ideal candidate for sustainable forage production in arid, semi-arid, and mildly saline–alkaline regions. This study aimed to evaluate the effects of replacing corn silage (CS) with either forage sorghum silage (FSS) or sugar sweet sorghum silage (SSS) on goat meat quality, the rumen microbial community, and meat composition. Thirty 3-month-old Boer goats (average body weight: 13.44 ± 1.67 kg) were randomly assigned to five dietary treatments; the control group contained 50% corn silage (CON), while the experimental groups contained 50% FSS (group I), 70% FSS (group II), 50% SSS (group III), or 70% SSS (group V), with each group receiving the same concentrate diet but different roughage sources. The results showed that compared to the CON group (50% CS), the experimental groups had a significantly increased average daily weight gain (ADG) (p < 0.05) and slaughter rate (SR). It is noteworthy that group III (50% SSS) showed a significant increase of 12.4% in SR (p < 0.01). Analysis of the silage characteristics and changes in the rumen microbial community revealed that feeding SSS and FSS increased the relative abundance of Ruminococcus in the rumen, further enhanced the degradation and conversion of silage neutral detergent fiber (NDF), and promoted the synthesis of fatty acids and amino acids. Specifically, FSS significantly increased the amino acid content in the meat, while SSS effectively improved the crude protein (CP) and crude fat (CF) contents. In conclusion, replacing 50% CS with FSS or SSS can effectively improve the meat quality and growth performance of Boer goats. Full article

Under long-term ecological stress, the Tarim wapiti (Cervus elaphus yarkandensis) has evolved unique adaptations in digestive physiology and energy metabolism. A multi-omics comparison of three Tarim wapiti and five Karakul sheep was used to examine the synergistic mechanism between rumen bacteria, short-chain fatty acids, and host epithelial regulation in order to clarify the mechanism of high roughage digestion efficiency in Tarim wapiti. Metagenomic sequencing (Illumina NovaSeq 6000) and gas chromatography revealed that Tarim wapiti exhibited significantly higher acetate and total VFA (TVFA) concentrations compared to Karakul sheep (p < 0.01), accompanied by lower ruminal pH and propionate levels. Core microbiota analysis identified Bacteroidetes (relative abundance: 52.3% vs. 48.1%), Prevotellaceae (22.7% vs. 19.4%), and Prevotella (18.9% vs. 15.6%) as dominant taxa in both species, with significant enrichment of Bacteroidetes in wapiti (p < 0.01). Functional annotation (PICRUSt2) demonstrated enhanced glycan biosynthesis (KEGG ko00511), DNA replication/repair (ko03430), and glycoside hydrolases (GH20, GH33, GH92, GH97) in wapiti (FDR < 0.05). Transcriptomic profiling (RNA-Seq) of rumen epithelium showed upregulated expression of SCFA transporters (PAT1: 2.1-fold, DRA: 1.8-fold, AE2: 2.3-fold; p < 0.01) and pH regulators (Na⁺/K⁺ ATPase: 1.7-fold; p < 0.05) in wapiti. Integrated analysis revealed coordinated microbial–host interactions through three key modules: (1) Bacteroidetes-driven polysaccharide degradation, (2) GHs-mediated fiber fermentation, and (3) epithelial transporters facilitating short-chain fatty acids absorption. These evolutionary adaptations, particularly the Bacteroidetes–short-chain fatty acids–transporter axis, likely underpin the wapiti’s superior roughage utilization efficiency, providing molecular insights for improving ruminant feeding strategies in an arid environment. Full article

Ruminal methanogenesis represents considerable energy loss within the fermentative processes mediated by microbial populations, by means of which up to 12% of gross energy intake is driven away from microbial protein synthesis (MPS). This review explores the relationship between methane (CH₄) synthesis and emission with MPS in beef cattle, focusing on the nutritional, biochemical, and microbial factors modulating these processes. The synthesis of CH₄ by ruminal archaea is essential for maintaining redox balance during the fermentation of carbohydrates. This process diverts metabolic H₂ from energy-efficient pathways like propionate synthesis, which could otherwise enhance microbial growth. Dietary factors, including carbohydrate fermentability, N synchronization, and passage rate, modulate MPS. Diets based on roughage might enhance CH₄ synthesis while impairing MPS efficiency by reducing diet digestibility and promoting microbial shifts towards methanogenic populations. Potential mitigation strategies, including plant secondary metabolites, CH₄ inhibitors, and controlled forage-to-concentrate ratios, demonstrate the potential to reduce CH₄ emissions while enhancing nutrient utilization. This review underscores the need for integrated approaches combining dietary strategies, advanced feed additives, and improved prediction models to optimize ruminal fermentation, enhance MPS, and reduce the environmental footprint of beef cattle systems. Full article

This study aims to assess how the supply of straw feed in China has changed over time and how this affects cattle and sheep farming. This paper takes the 31 provinces (autonomous regions and municipalities directly under the Central Government) in China as basic units. Based on the grass-to-grain ratios of different crops, the analysis includes estimating the theoretical supply of straw feed, evaluating its livestock carrying capacity, and examining the spatial distribution of supply and demand. From 1978 to 2023, the adaptability of the supply and demand of crop straws has shown a significant upward trend, but the overall adaptability is still low. Differences in the spatial layout of agriculture and animal husbandry have led to the emergence of advantageous areas for the allocation of the supply and demand of straw feeds, which are shifting from the east to the west and from the south to the north and concentrating from the planting areas to the livestock breeding areas. This study finds that climate warming has shifted the centroid of theoretical straw supply northward, resulting in higher straw–livestock compatibility in agriculturally developed regions but lower compatibility in unbalanced agro-pastoral zones, primarily due to high transport costs for straw and roughage, which constrain sustainable agro-pastoral circular development. Therefore, it is recommended that all countries (regions) actively implement the “Straw-to-Meat” policy in agriculturally advanced zones, while proactively adapting to climate warming by optimizing agro-pastoral spatial planning and exploring alternatives to roughage or expanding feed grain cultivation. Full article

In this study, Candida utilis, Lactobacillus plantarum, and non-starch polysaccharide enzymes (cellulase, laccase, β-glucanase, xylanase, and mannanase) were employed to examine the effects of various microorganism–enzyme combinations on the nutritional composition, fiber structure, and fermentation quality of corn stover and wheat straw. Furthermore, the synergistic effects of these treatments were assessed through the use of in vitro rumen fermentation. The results showed that the microorganism–enzyme combinations significantly increased the crude protein content (p < 0.05), while reducing the acid detergent fiber and neutral detergent fiber levels (p < 0.05) in both substrates. The fermentation broth pH decreased (p = 0.06 for corn stover; p < 0.05 for wheat straw) as a result of the treatments, with a significant increase in the lactate concentration (p < 0.05). The reducing sugar levels varied across the treatments (p < 0.05). Mycotoxin analysis revealed trace amounts of zearalenone, well below the Chinese feed hygiene standard. Scanning electron microscopy showed structural modifications, including fiber breakage and surface wrinkling, in the treated substrates. In vitro rumen fermentation demonstrated significant changes in the NH₃-N production and volatile fatty acid profiles (p < 0.05). In conclusion, the addition of different microorganism–enzyme combinations can effectively improve the nutritional composition, fiber structure, and fermentation quality of corn stover and wheat straw. Among the treatments, the T3 group (25% each of C. utilis, L. plantarum, cellulase, and laccase, with a total addition ratio of 0.3% w/w) exhibited the most pronounced improvement in nutritional value for both corn stover and wheat straw. These findings suggest that microorganism–enzyme combinations effectively enhance the nutritional and fermentative quality of agricultural residues. Full article

The objective of this study was to evaluate the nutritive value of three sugarcane genotypes treated with 1.5% CaO and stored for three different periods. A split-plot design was used for the experiment. The treatments consisted of a 3 × 3 factorial design, involving three genotypes (IAC-862480, SP-791011, and CTC-3) and three storage periods (24, 48, and 72 h). No significant effect of genotype (p > 0.05) was observed on ether extract (EE), hemicellulose, or total carbohydrate contents. However, significant genotype effects (p < 0.05) were noted for dry matter (DM), crude protein (CP), acid detergent fiber (ADF), cellulose, lignin, non-fibrous carbohydrates (NFC), and total digestible nutrients (TDN) contents. Furthermore, significant genotype effects (p < 0.05) were observed for in vitro DM digestibility (IVDMD), as well as the A + B1, B2, and C carbohydrate fractions. No significant effect of storage time (p > 0.05) was found on DM, organic matter, CP, EE, lignin, IVDMD, or C fraction contents. In contrast, storage time had a significant effect (p < 0.05) on ADF, hemicellulose, cellulose, NFC, total carbohydrates, TDN, A + B1, and B2 contents. Calcium oxide was effective in preserving the nutritional characteristics of sugarcane for up to 72 h of storage. The genotypes SP-791011 and IAC-862480 exhibited higher nutritional value. Further experiments are needed to determine the safe amount of this feed component that can be ingested by ruminants. Full article

Neem cake (Azadirachta indica) is a versatile plant with potential benefits for ruminant animals due to its effects on rumen modulation. This study aimed to evaluate the effects of increasing levels of neem cake and monensin on in vitro ruminal fermentation in cattle diets. Six treatments were tested: neem cake at 0, 240, 480, 720, and 960 mg/kg dry matter (DM) and monensin at 30 mg/kg DM. The basal diet consisted of a diet with a 15:85 roughage-to-concentrate ratio. Parameters evaluated included gas production kinetics, CH₄ and CO₂ emissions, pH, volatile fatty acids (VFAs), ammonia-N (NH₃-N), and organic matter digestibility. Neem cake increased ruminal pH compared to monensin (p < 0.01). The total VFAs increased linearly with neem cake inclusion (p < 0.01). The acetate proportion increased quadratically (p = 0.06). Propionate decreased linearly (p = 0.02), while branched-chain VFAs (BCVFAs) increased linearly (p = 0.09). The neem cake addition increased the NH₃-N concentration quadratically (p < 0.01). CH₄ and CO₂ concentrations were higher with neem cake compared to monensin (p < 0.05). Neem cake shows potential to reduce rumen acidosis and enhance fiber digestion, making it useful during the adaptation period for finishing diets in feedlots and for grazing animals. However, it was not effective in reducing greenhouse gas emissions in this in vitro system. Full article

Reed straw is a potential roughage resource that limits its application in livestock production due to its higher fiber content. Inferior jujube is widely used as a non-conventional feed in livestock production due to its high nutritional value. In this study, a two-factor experimental design was used to investigate the effects of fermentation with Composite A (BA) and Composite B (BB) under the condition that the dry matter ratio of reed straw to residual red dates was 1:1, and mixed microstorage was fermented for different times (0 d, 30 d, and 60 d) with the effects of nutrient indexes, fermentation quality, and microbial community dynamics changes. A control group (CON) was set up, six replicates were set up for each treatment, and the amount of bacteria added was 1% of the dry matter basis. The results showed that compared with the control group, both composite bacterial liquids could effectively reduce the nutrient loss of micro-silage feeds, in which with the addition of composite bacterium B (BB) treatment group at the end of fermentation, the crude protein (CP) content increased by 1.91%, and the neutral detergent fiber (NDF) and the acid detergent fiber (ADF) were reduced by 11.32% and 10.61%, respectively. The volatile fatty acid content was significantly higher than that of the control group, which was 26.41 μg·mL⁻¹. The BB group had the highest abundance of Lacticaseibacillus during the fermentation process, which could produce a large amount of lactic acid and lower the pH to improve the quality of feed fermentation. In addition, the differences in the indexes were smaller in the BB group compared with the BA group, but the fermentation effect of the BB group was better than that of the BA group. Full article

Maternal metabolic intensity significantly increases during late gestation and lactation, placing significant stress on cells and tissues. This heightened metabolic demand can lead to inflammatory responses and metabolic disorders, adversely affecting the health of both the mother and her offspring. Diet plays a key role in modulating host health by influencing the gastrointestinal microbiome. This study examined the impact of two roughage sources, corn straw (CS), and alfalfa hay (AH), on ewes and their offspring during late gestation and lactation, with a focus on metabolism, immunity, and the microbiome. Thirty-six multiparous Inner Mongolia cashmere goats, approximately 60 days pregnant, were assigned to CS and AH groups. Samples were collected from the ewes on day 140 of gestation (G140) and day 28 of lactation (L28) for analysis. The results showed that ewes fed AH had reduced body weight loss during lactation (p < 0.05), and increased serum metabolic factors levels (p < 0.05). Additionally, ewes in the AH group exhibited a reduced inflammatory response during both gestation and lactation compared to those in the CS group, as evidenced by a significant decrease in TNF-α and LPS levels and a notable increase in IL-10 (p < 0.05). The rumen microbiomes of ewes in the AH and CS groups exhibited stark differences, with specific microbial markers identified at G140 and L28. Correlation analysis revealed associations between microbiome, volatile fatty acids, cytokines, and metabolic markers. The analysis of the lambs demonstrated that their immune status and microbial composition were significantly influenced by the immune health and microbial community structure of the ewe. Moreover, microbial and immune-related components from the ewes were transmitted to the lambs, further shaping their immune development and rumen microbiota. Overall, different roughage sources during late gestation and lactation had minimal impact on the growth performance of ewes and lambs, given that both diets were iso-nitrogen and iso-energetic. However, ewes fed AH exhibited significant improvements in immune function and overall health for both them and their lambs. Full article