Enhanced lignin degradation by Irpex lacteus through expanded sterilization further improved the fermentation quality and microbial community during the silage preservation process

IF 4.3 3区 生物学 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Bioresources and Bioprocessing Pub Date : 2024-01-22 DOI:10.1186/s40643-024-00730-2
Xiaohui Cao, Rui Cai, Sasa Zuo, Dongze Niu, Fuyu Yang, Chuncheng Xu
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Abstract

Traditional autoclaving, slow degradation rate and preservation of biomass treated by fungi are the main factors restricting biological treatment. In our previous studies, strains with high efficiency and selective lignin degradation ability were obtained. To further solve the limiting factors of biological treatment, this paper proposed a composite treatment technology, which could replace autoclaves for fungal treatment and improve the preservation and utilization of fungal-pretreated straw. The autoclaved and expanded buckwheat straw were, respectively, degraded by Irpex lacteus for 14 days (CIL, EIL), followed by ensiling of raw materials (CK) and biodegraded straw of CIL and EIL samples with Lactobacillus plantarum for different days, respectively (CP, CIP, EIP). An expansion led to lactic acid bacteria, mold, and yeast of the samples below the detection line, and aerobic bacteria was significantly reduced, indicating a positive sterilization effect. Expansion before I. lacteus significantly enhanced lignin selective degradation by about 6%, and the absolute content of natural detergent solute was about 5% higher than that of the CIL. Moreover, EIL decreased pH by producing higher organic acids. The combination treatment created favorable conditions for ensiling. During ensiling, EIP silage produced high lactic acid about 26.83 g/kg DM and the highest acetic acid about 22.35 g/kg DM, and the pH value could be stable at 4.50. Expansion before I. lacteus optimized the microbial community for ensiling, resulting in EIP silage co-dominated by Lactobacillus, Pediococcus and Weissella, whereas only Lactobacillus was always dominant in CP and CIP silage. Clavispora gradually replaced Irpex in EIP silage, which potentially promoted lactic acid bacteria growth and acetic acid production. In vitro gas production (IVGP) in EIL was increased by 30% relative to CK and was higher than 24% in CIL. The role of expansion was more significant after ensiling, the IVGP in EIP was increased by 22% relative to CP, while that in CIP silage was only increased by 9%. Silage of fungal-treated samples reduced methane emissions by 28% to 31%. The study demonstrated that expansion provides advantages for fungal colonization and delignification, and further improves the microbial community and fermentation quality for silage, enhancing the nutrition and utilization value. This has practical application value for scaling up biological treatment and preserving the fungal-treated lignocellulose.

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在青贮饲料保存过程中,通过扩大灭菌范围提高乳酸伊氏菌对木质素的降解,进一步改善发酵质量和微生物群落
传统的高压灭菌法、降解速度慢以及用真菌处理生物质的保存问题是制约生物处理的主要因素。在以往的研究中,我们获得了具有高效率和选择性木质素降解能力的菌株。为进一步解决生物处理的限制因素,本文提出了一种复合处理技术,该技术可替代高压蒸汽灭菌法进行真菌处理,提高真菌处理后秸秆的保存和利用率。分别对蒸压和膨化后的荞麦秸秆进行为期 14 天的乳酸杆菌降解(CIL、EIL),然后用植物乳杆菌对 CIL 和 EIL 样品的原料(CK)和生物降解秸秆分别进行不同天数的腐熟(CP、CIP、EIP)。膨化导致样品中的乳酸菌、霉菌和酵母菌低于检测线,而需氧菌显著减少,表明杀菌效果良好。在乳酸杆菌之前进行扩增,木质素的选择性降解明显提高了约 6%,天然去污溶质的绝对含量比 CIL 提高了约 5%。此外,EIL 还能产生更多的有机酸,从而降低 pH 值。综合处理为青贮创造了有利条件。在腌制过程中,EIP 青贮产生了较高的乳酸(约 26.83 克/千克 DM)和最高的乙酸(约 22.35 克/千克 DM),pH 值可稳定在 4.50。乳酸杆菌的扩增优化了青贮微生物群落,使 EIP 青贮饲料以乳酸杆菌、木薯球菌和魏氏菌共同为主,而在 CP 和 CIP 青贮饲料中,只有乳酸杆菌始终占优势。Clavispora 逐渐取代了 EIP 青贮饲料中的 Irpex,这可能会促进乳酸菌的生长和醋酸的产生。EIL 的体外产气量(IVGP)比 CK 增加了 30%,高于 CIL 的 24%。青贮后,膨胀的作用更为显著,EIP 的体外产气量比 CP 提高了 22%,而 CIP 青贮的体外产气量仅提高了 9%。经过真菌处理的青贮样品甲烷排放量减少了 28% 至 31%。研究表明,膨化为真菌定殖和脱木质提供了优势,并进一步改善了青贮饲料的微生物群落和发酵质量,提高了营养和利用价值。这对扩大生物处理规模和保存真菌处理过的木质纤维素具有实际应用价值。 图文摘要
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来源期刊
Bioresources and Bioprocessing
Bioresources and Bioprocessing BIOTECHNOLOGY & APPLIED MICROBIOLOGY-
CiteScore
7.20
自引率
8.70%
发文量
118
审稿时长
13 weeks
期刊介绍: Bioresources and Bioprocessing (BIOB) is a peer-reviewed open access journal published under the brand SpringerOpen. BIOB aims at providing an international academic platform for exchanging views on and promoting research to support bioresource development, processing and utilization in a sustainable manner. As an application-oriented research journal, BIOB covers not only the application and management of bioresource technology but also the design and development of bioprocesses that will lead to new and sustainable production processes. BIOB publishes original and review articles on most topics relating to bioresource and bioprocess engineering, including: -Biochemical and microbiological engineering -Biocatalysis and biotransformation -Biosynthesis and metabolic engineering -Bioprocess and biosystems engineering -Bioenergy and biorefinery -Cell culture and biomedical engineering -Food, agricultural and marine biotechnology -Bioseparation and biopurification engineering -Bioremediation and environmental biotechnology
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