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Fermentation profile and dynamics of bacterial communities in vetch-oat ensiled with a novel spray-dried inoculant

Published online by Cambridge University Press:  05 February 2024

J. E. Blajman*
Affiliation:
Instituto de Investigación de la Cadena Láctea (CONICET-INTA), Ruta 34 Km. 227, CP 2300 Rafaela, Santa Fe, Argentina
M. S. Lingua
Affiliation:
Instituto de Investigación de la Cadena Láctea (CONICET-INTA), Ruta 34 Km. 227, CP 2300 Rafaela, Santa Fe, Argentina
J. M. Irazoqui
Affiliation:
Instituto de Investigación de la Cadena Láctea (CONICET-INTA), Ruta 34 Km. 227, CP 2300 Rafaela, Santa Fe, Argentina
G. M. Santiago
Affiliation:
Instituto de Investigación de la Cadena Láctea (CONICET-INTA), Ruta 34 Km. 227, CP 2300 Rafaela, Santa Fe, Argentina
M. F. Eberhardt
Affiliation:
Instituto de Investigación de la Cadena Láctea (CONICET-INTA), Ruta 34 Km. 227, CP 2300 Rafaela, Santa Fe, Argentina
A. F. Amadio
Affiliation:
Instituto de Investigación de la Cadena Láctea (CONICET-INTA), Ruta 34 Km. 227, CP 2300 Rafaela, Santa Fe, Argentina
G. H. Peralta
Affiliation:
Instituto de Lactología Industrial (CONICET-UNL), Santiago del Estero 2829, CP 3000 Santa Fe, Argentina
M. C. Gaggiotti
Affiliation:
Instituto de Investigación de la Cadena Láctea (CONICET-INTA), Ruta 34 Km. 227, CP 2300 Rafaela, Santa Fe, Argentina
*
Corresponding author: J. E. Blajman; Email: [email protected]
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Abstract

This study aimed to examine and compare the effectiveness of a novel spray-dried inoculant and a commercial freeze-dried additive on the fermentation quality, aerobic stability and bacterial population of vetch-oat silage. An entirely random design used a 3 × 4 factorial arrangement of treatments, with and without lactic acid bacteria (LAB) inoculants and four fermentation periods. Physicochemical parameters, microbiological counts and 16S rRNA gene sequencing analysis on Nanopore MinION were conducted to characterize the ensiling process. Both LAB inoculants increased dry matter, crude protein, lactic, acetic and propionic acid contents, while reducing pH, neutral detergent fibre, ammonia nitrogen/total nitrogen and ethanol concentrations compared to the control group. Overall, the native inoculant decreased the cell load of coliforms, yeasts and moulds. In addition, bio-inoculants enhanced the aerobic stability of vetch-oat intercrops. After ensiling, bacterial alpha diversity decreased noticeably; inoculation reduced the number of observed operational taxonomic units and the Shannon and Simpson indices. Notably, the relative abundance of Lactobacillus in the control group was lower than in treated silages, while the relative values of Staphylococcus increased sharply in the uninoculated group. In conclusion, the native strains showed promise for usage as a bio-inoculant in the ensiling of vetch-oat at a mixture rate of 1:1, producing an immediate impact as well as a favourable effect on the post-opening phase. This represents the first report on 16S rRNA gene-based nanopore metagenomics applied to the bacterial analysis of vetch-oat silage, providing a microbiological insight where native and commercial strains dominate the natural epiphytic community.

Type
Crops and Soils Research Paper
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press

Introduction

Forage preservation as silage is essential for the sustainable development of livestock systems. Certain annual legumes and winter grain cereals have historically been combined to promote crop productivity and optimize resource utilization (Kchaou et al., Reference Kchaou, Benyoussef, Jebari, Harbaoui and Berndtsson2022). As legume herbage, vetch species have a rich nutritional profile, a versatile growth habit and environmental benefits (Copani et al., Reference Copani, Niderkorn, Anglard, Quereuil and Ginane2016). Yet, due to their high buffering capacity and low concentration of water-soluble carbohydrates (WSC), legumes can be difficult to ensile (McDonald et al., Reference McDonald, Henderson and Heron1991). In fact, Markovíc et al. (Reference Marković, Vasić, Petrović, Milenković, Bekčić, Lazarević and Babić2022) stated that pure stands of vetch had a sugar content of about 47 g/kg DM and a buffer capacity value of 100 mEq/100 g DM. Moreover, vetch monocultures often yield poorly and hinder harvest because they normally sprawl on the soil surface (Wang et al., Reference Wang, Chen, Yang, Zeng, Hu and Zang2021a). Caballero et al. (Reference Caballero, Goicoechea and Hernaiz1995) reported that vetch-oat mixtures outyielded the vetch monocrop by more than 30% and attributed this improvement to enhanced resource utilization and improved soil fertility derived from the biological nitrogen fixation by the legume (Rivest et al., Reference Rivest, Lorente, Olivier and Messier2013). On the other hand, small grain cereals, such as oats, provide both high yields and high WSC levels but produce forage crops with relatively low protein content. Hence, simultaneous cultivation of cereal forages with crops presents a viable strategy for enhancing the protein content of the overall ration. In particular, Lithourgidis et al. (Reference Lithourgidis, Vasilakoglou, Dhima, Dordas and Yiakoulaki2006) found that oat monocultures had a crude protein concentration around 80 g/kg DM, whereas vetch-oat mixtures exhibited a crude protein content between 90 and 120 g/kg DM. Based on the aforementioned advantages, the practice of intercropping oat with vetch emerges as a suitable and beneficial approach not only in Argentina but also in other countries.

The demand for silage additives, integral to sustainable agriculture, is on the rise due to the increasing consumption of silage across the globe. According to research and analysis by Mordor Intelligence, the European silage inoculant market is expected to attain a compound annual growth rate (CAGR) of 3.5% during the period 2023–2028, while the North American silage inoculant market is anticipated to achieve a CAGR of 4.8% during the same period (Mordor Intelligence Report, 2023). This market is characterized by a high concentration, with a few major firms holding a significant market share, particularly in Argentina, where foreign-manufactured products dominate. In this context, most formulations are supplied as freeze-dried cultures or as water-soluble concentrates, while spray drying represents a profitable alternative for producing large amounts of dried cells in a continuous process (Wang et al., Reference Wang, Fu and Chen2022a). The development of innovative products based on spray-dried native strains, better suited to the fermentative process of local forages, is expected to be a key factor in promoting the adoption of silage additives, potentially contributing to the enhancement of our economy.

Among fermentation stimulants, the addition of homofermentative lactic acid bacteria (LAB) is aimed at ensuring a rapid decrease in pH and lactic acid accumulation in the early stages of ensiling. This improves DM recovery, reduces proteolysis, and inhibits the proliferation of unwanted microorganisms such as the Enterobactericeae family, acetic acid bacteria, spore-forming organisms (Bacillus and Clostridium) and Listeria (Pahlow et al., Reference Pahlow, Muck, Driehuis, Elferink and Spoelstra2003; Muck, Reference Muck2013). Contrarily, heterofermentative LAB can produce more acetic and propionic acids, which inhibit the growth of yeasts and moulds, increasing the aerobic stability of the silage (Gomes et al., Reference Gomes, Jacovaci, Bolson, Nussio, Jobim and Daniel2019).

Though previous studies have explored the impact of additives on the ensiling characteristics and aerobic stability of vetch-oat mixed silage (Chen et al., Reference Chen, Guo, Yuan, Zhang, Li and Shao2016; Markovíc et al., Reference Marković, Blagojević, Kostić, Vasić, Anđelković, Petrović and Štrbanović2018), insufficient data are available on the dynamics of microbial populations and their interactions. Monitoring changes in bacterial communities and their progression in vetch-oat silages treated with LAB would be useful to thoroughly understand and improve the ensiling process. Metagenomic approaches involving direct DNA extraction and subsequent analyses are imperative for elucidating microbial communities and discerning functional changes associated with ensiling (Hisham et al., Reference Hisham, Hashim, Mohd Hanafi, Abdul Rahman, Abdul Mutalib, Tan, Nasli and Mohd Yusoff2022). In this sense, targeted amplification of specific regions of the 16S rRNA gene (abbreviated 16S) followed by next-generation sequencing (NGS) offers the opportunity to better understand the processes underlying silage formation and estimate the effects of applied starter cultures on microbial population shifts. Unlike many NGS platforms that require substantial capital investments, extensive protocols and stationary equipment, newer sequencing platforms such as the MinION (Oxford Nanopore Technologies, Oxford, UK; ONT), constitute a simple, affordable and portable third-generation sequencing device with the capacity for generating long reads and data analyses in real time (Leggett and Clark, Reference Leggett and Clark2017).

In the current work, it is hypothesized that the addition of an autochthonous spray-dried LAB inoculant could enhance the physicochemical parameters, microbiological profile and aerobic stability of vetch-oat silages. Consequently, our objective was twofold: (1) to elucidate and compare the impact of the native microencapsulated inoculant with a commercially available additive on the fermentation process and after silo opening, and (2) to acquire comprehensive insights into the bacterial communities within vetch-oat silages by utilizing 16S gene data.

Materials and methods

Native bacterial inoculant

Native strains Lactiplantibacillus plantarum Hv75 (formerly known as Lactobacillus plantarum), Pediococcus acidilactici 3903 and Lentilactobacillus buchneri B463 (formerly known as Lactobacillus buchneri) had previously been isolated and characterized in vitro as potential silage inoculants (Cristiani, Reference Cristiani2015; Burns et al., Reference Burns, Borgo, Binetti, Puntillo, Bergamini, Páez, Mazzoni, Reinheimer and Vinderola2018). These bacteria were stored at −70°C and kept in the culture collection of the National Institute of Agricultural Technology (INTA, Rafaela, Santa Fe, Argentina). When required, fresh overnight cultures were obtained by incubating the strains for 18 h at 37°C in an aerobic environment in MRS broth (Neogen, Lansing, MI, USA) after two successive transfers from frozen stocks.

Bacterial biomass was produced in a batch fermentation process and subsequently microencapsulated by spray-drying, as previously described by Blajman et al. (Reference Blajman, Signorini, Vinderola, Lingua, Romero, Páez, Casas, Bergamini, Giménez and Gaggiotti2022). Cell viability was assessed using plate counts (incubation for 72 h at 37°C, under aerobic conditions on MRS agar) and expressed as log10 cfu/ml before and after the spray-drying. Residual moisture and production yield were evaluated for the spray-dried powders. Residual moisture (% w/w) was determined in triplicate at 101 ± 1°C (FIL-IDF, 1993). Yield was expressed as the percentage of mass recovered after drying in relation to total solids before drying (Blajman et al., Reference Blajman, Vinderola, Cuatrin, Lingua and Páez2020a).

LAB-scale silage preparation and treatments

Hairy vetch (Vicia villosa var. Itacuá) and oat (Avena strigosa Schreb. var. Massa) were intercropped at a seeding rate of 20 kg/ha for each individual species within the mixture, in the experimental field of INTA (Lat.: 31°10′S; Long.: 61°32′W; Height above sea level: 100 m). The crops were sown on 29 March 2021, and harvested on 22 July 2021. Intercrops were harvested by cutting them at a height of approximately 5 cm above the ground, and field-wilted for 3 days to attain a target DM level of ~496 g/kg. Then, the vetch-oat mixture underwent chopping into particles of approximately 20 mm in length using a precision forage harvester (Class Jaguar 950, Claas, Harsewinkel, Germany) and samples were taken to analyse its chemical composition. The proportion of vetch and oat in the intercrops, on a fresh matter (FM) basis, was 1:1, with oat at the soft-dough stage and vetch at the vegetative stage. A factorial design comprising a 3 × 4 arrangement of treatments was used, involving bacterial inoculants and four fermentation periods (0, 3, 30, 60 days), in an entirely randomized design, with three replicates assigned each treatment and sampling date. Vetch-oat forage was ensiled without microbial inoculant as control; with a native inoculant containing L. plantarum Hv75, P. acidilactici 3903, and L. buchneri B463; or with a commercial inoculant containing Enterococcus faecium M74, L. plantarum CH6072, and Lactococcus lactis SR3.54 (SiloSolve® MC, Chr. Hansen A/S, Hørsholm, Denmark). The plant material was ensiled in 36 polyethylene containers (10 l capacity) and compacted with 278 kg DM/m3. Before undergoing ensiling, triplicate samples representing the fresh material were randomly obtained for subsequent chemical analyses.

Spray-dried L. plantarum Hv75, P. acidilactici 3903, and L. buchneri B463 were applied in the same proportion at a theoretical rate of 2 × 106 cfu/g of cropped forage. The LAB were resuspended in double distilled water and applied uniformly onto the mixture, using a hand sprayer (1.5 l) at the rate of 4 ml/kg of forage. The commercial inoculant was used according to manufacturer's recommendations; freeze-dried powders were diluted in double distilled water and applied at 2 ml/kg of fresh forage using a sprayer, resulting in a final expected dose of approximately 1.5 × 105 cfu/g of cropped forage. An equal amount of double distilled water was evenly sprayed onto the vetch-oat forage without microbial inoculant. Bucket silos were compacted, immediately sealed with fitted lids equipped with rubber O-rings, and stored at room temperature (24 ± 3°C) for 60 days. Triplicate micro-silos were opened at each time point during the anaerobic fermentation process and subsamples were collected for analyses of fermentation profile and microbiological counts.

Microbiological and physicochemical analyses

Microbiological analyses and pH determinations were conducted at 0, 3, 30 and 60 days of storage. For microbial population analysis, eight grams of each sample were mixed with 72 ml of 2% sodium citrate and homogenized for 5 min using a stomacher (Seward Stomacher 80, Lab system, London, UK). The suspension was serially diluted (10−2 to 10−7), and 100-ml aliquots of each dilution were spread on agar media. Coliforms were counted by pour plating on Violet Red Bile Agar (Neogen, Lansing, MI, USA) after aerobic incubation at 35°C for 48 h on a heating incubator (DHP-9052 Arcano, Shanghai, China). Total LAB were counted on MRS agar (37°C, 72 h, aerobiosis), while yeasts and moulds were enumerated on Sabouraud Dextrose agar (Neogen, Lansing, MI, USA) supplemented with Chloramphenicol at 100 μg/ml (Genbiotech, Buenos Aires, Argentina) (25°C, 72 and 120 h, respectively, under aerobiosis). These chemical parameters were assessed for each replicate silo, according to standardized protocols (Jaurena, Reference Jaurena2009): DM at 65°C, not corrected for volatile compounds loss (g/kg DM; Association of Official Analytical Chemists 1990, method numbers 130.15 and 167.03), crude protein ( = Total Nitrogen × 6.25) determined by Kjeldahl (g/kg CP; AOAC 1998, method number 976.05), neutral detergent fibre analysed with added heat stable α-amylase and sodium sulphite (g/kg NDF; AOAC 1990, method number 942.05) by using an ANKOM fibre analyser (Model 220, Ankom Corp., Macedon, NY, USA), acid detergent fibre performed in ANKOM Fiber Analyzer 220 (g/kg ADF; AOAC 1990, method number 973.18), acid detergent lignin using sulphuric acid and ANKOM Fiber Analyzer 220 (g/kg ADL; AOAC 1990, method number 973.18), ether extract using the Soxhlet extraction method with petroleum-ether (g/kg EE; AOAC 1999, method number 920.39) and ammonia nitrogen/total nitrogen (NH3-N/NT; Blain and Urtinette, Reference Blain and Urtinette1954). The quantification of organic acids, carbohydrates and ethanol was conducted by HPLC at the same time points. Eight grams of each sample were mixed with 72 ml of sterile double distilled water, homogenized for 10 min in a stomacher (Seward Stomacher 80, Lab system, London, UK) and centrifuged (Sorvall RC-5C, Du Pont Company, Sorval Instruments, Wilmington, DE, USA) at 6000 × g and 4°C for 10 min. Chromatographic separation was carried out following the methodology described by Vénica et al. (Reference Vénica, Perotti and Bergamini2014).

Aerobic stability

To assess the strains' ability to control aerobic deterioration, silages underwent an aerobic stability test at room temperature during 4 days at the conclusion of the ensiling period. Two kilograms of thoroughly mixed silage from the central portion of each bucket silo (devoid of observable spoilage) were placed into clean plastic bags (inside an expanded polystyrene box covered with 2 layers of cheesecloth to prevent drying). Temperature sensors (Thermobutton, Akribis S.R.L., Buenos Aires, Argentina) were positioned at the centre of each silage mass, and temperature data were recorded every 30 min for 4 days (He et al., Reference He, Zhou, Xing, Pian, Chen and Zhang2020). Two supplementary sensors were positioned in the room to record ambient temperature. Aerobic stability was characterized as the duration (in hours) the silage remained stable before the temperature exceeded the ambient temperature by more than 2°C (Reich and Kung, Reference Reich and Kung2010).

Metaprofiling of the bacterial community by nanopore sequencing

Bacteria DNA extraction

DNA isolation from silage samples was conducted in duplicate for the raw forage (day 0), after 30, and 60 days of fermentation, and for vetch-oat samples subjected to aerobic stability evaluation. Ten grams of each sample were placed into a sterile plastic bag followed by homogenization with 100 ml of PBS (pH 7.4) for 10 min using a stomacher (Seward Stomacher 80, Lab system, London, UK). The mixture underwent filtration using four layers of cheesecloth, and the resulting liquid was then centrifuged (5000 rpm, 20 min, 4°C) (Sorvall Legend X1R, ThermoFisher Scientific, Waltham, MA, USA). The precipitate was resuspended in 1 ml of sterile PBS and centrifuged (12 000 rpm, 10 min, 4°C) (Sorvall Legend X1R, ThermoFisher Scientific, Waltham, MA, USA) to collect the microbial pellet (Yang et al., Reference Yang, Zhao, Wang, Fan, Wang and Feng2021). Total DNA was extracted using a ZymoBIOMICS™ DNA Miniprep kit (catalogue no. ZR D4300, Zymo Research Corp., Irvine, CA, USA) following the manufacturer's instructions. DNA integrity was confirmed through 1% agarose gel electrophoresis at constant voltage (100 V) for 1.5 h. DNA quantification was performed using a NanoDrop Lite spectrophotometer (Thermo Scientific, Waltham, MA, USA) and a DeNovix-QFX fluorometer (DeNovix, Wilmington, DE, USA) with the DeNovix dsDNA Broad Range Assay kit (DeNovix, Wilmington, DE, USA). Total DNA samples were frozen at −20°C until further use.

16S rRNA gene sequencing

The PCR was performed using the 16S barcoding kit 1–24 (SQK-16S024; Oxford Nanopore Technologies, Oxford, UK). Each reaction was conducted in a final volume of 50 μl, including 12.5 μl of barcoded primers and 30 to 180 ng mould DNA. The Q5 Hot Start High-Fidelity 2 × Master Mix (New England Biolabs Inc., Ipswich, MA, USA) was used. Amplification was carried out in an Eppendorf Mastercycler (Eppendorf, Hamburg, Germany) with the following programme: initial denaturation at 95°C for 3 min, 35 cycles of denaturation at 95°C for 20 s, annealing at 55°C for 20 s, and elongation at 72°C for 90 s. A final extension was performed at 72°C for 2 min. All reactions were verified for successful amplification and contamination using gel electrophoresis (1% agarose gels stained with gel red, 100 V for 1.5 h). The PCR products were purified using the AMPure XP PCR Purification Kit (Beckman Coulter Genomics, Danvers, MA, USA) and quantified with a DeNovix-QFX fluorometer (DeNovix, Wilmington, DE, USA) using the Qubit 1 × dsDNA HS (High Sensitivity) Assay Kit (Thermo Fisher Scientific, Waltham, MA, USA).

Barcoded fragments were combined in equimolar amounts, totalling 200 ng, and rapid adaptors were added for library preparation. The mixture was placed onto R9.4 flow cells (FLO-MIN106; Oxford Nanopore Technologies, Oxford, UK; ONT) following the manufacturer's specifications. Sequencing was carried out using the MinION Mk1C instrument (Oxford Nanopore Technologies, Oxford, UK; ONT) and data acquisition was conducted using MINKNOW version 22.10.7.

Bioinformatics analysis

All reads were subjected to basecalling using Guppy (v 6.1.5) with the super accurate model. The resulting reads were filtered, wherein reads with an average quality score over 12 and length between 1400 and 1700 bp were retained. Reads were subsequently clustered together using isONClust (Sahlin and Medvedev, Reference Sahlin and Medvedev2020), with a minimum mapped fraction of read set at 0.9 and a minimum fraction of shared minimizers at 0.9. Also, singletons were discarded to prevent the presence of spurious operational taxonomic units (OTUs). A consensus sequence for each cluster was generated using the single-project optimization approach (SPOA v 4.0.9; Vaser et al., Reference Vaser, Sović, Nagarajan and Šikić2017) and refined with Medaka (v 1.6.1) utilizing the super accurate model. Taxonomic classification of the resulting OTUs was achieved through the utilization of Kraken2 (v 2.0.8; Wood et al., Reference Wood, Lu and Langmead2019) against the SILVA database (release 138.1; Quast et al., Reference Quast, Pruesse, Yilmaz, Gerken, Schweer, Yarza, Peplies and Glöckner2012).

All 16S rRNA amplicon gene libraries from the current study have been deposited in the National Centre for Biotechnology Information Sequence Read Archive, under the BioProject accession number PRJNA1012711.

Statistical analysis

Silage fermentation was analysed to investigate the primary effects of days, inoculation, and their interactions in a fully randomized design model. Data processing was conducted using the statistical software InfoStat (Grupo InfoStat, FCA, Universidad Nacional de Córdoba, Córdoba, Argentina). The homogeneity of variance was assessed through the Levene Test, and normality was confirmed using the Kolmogorov–Smirnov Test. For certain variables that deviated from a normal distribution and/or homoscedasticity, the analysis was performed using the Generalized Linear Model (GLM) approach with a gamma distribution and a log link function. For variables exhibiting normal distribution, a two-way analysis of variance was used, followed by the Tukey post hoc test. Aerobic stability was evaluated using Kaplan–Meier analysis, which calculated time required to surpass the 2°C threshold above the ambient temperature.

R software v 4.2.2 (R Foundation, Vienna, Austria) was employed to assess bacterial diversity and composition through the treatments. Rarefaction curves were created with the ‘rarecurve’ function in the Vegan package in R. Alpha and beta diversity indices were computed using the Vegan (Oksanen et al., Reference Oksanen, Blanchet, Kindt, Legendre, Minchin, O'hara, Simpson, Solymos, Stevens and Wagner2012) and phyloseq (McMurdie and Holmes, Reference McMurdie and Holmes2013) packages. Beta diversity comparisons were determined through a permutational analysis of variance with the ‘adonis’ function (Martinez Arbizu, Reference Martinez Arbizu2020). Differences in alpha diversity and bacterial composition were also estimated using a two-way analysis of variance or GLM for gamma distribution and a log link function.

Statistical significance was established at P ≤ 0.05. Results are expressed as mean ± standard error of the mean (s.e.m.).

Results

Native bacterial inoculant

The biomass production of the multispecies inoculant was satisfactory, reaching 9.83 log10 cfu/ml during the stationary phase. The cell count of the suspension before spray-drying was 9.93 log10 cfu/ml, while the count after the dehydration process in the reconstituted powder was 9.09 log10 cfu/ml. Dehydration at these spray-drying conditions allowed to obtain a moisture content below <4% and a drying yield >70%.

Microbiological and physicochemical analyses

The nutrient composition of wilted substrates prior to ensiling is presented in Table 1. During fermentation, silage pH was influenced by inoculation and ensiling time, and there was an inoculation × time interaction (P < 0.001). The rate of pH decline was faster in the silage treated with the novel LAB and in the silage with the commercial inoculant than in the control silage. At day 30, pH values were 5.01, 4.06 and 4.37 for control, native and commercial inoculant bucket silos, respectively (P < 0.001). Meanwhile, at day 60, the pH levels recorded were 4.65, 4.09 and 4.22, respectively (P < 0.001). An interaction between inoculation and the day of conservation was observed for DM content, which was lower in the silage without additives at the end of the fermentation period (P = 0.008). Specifically, at day 60, DM levels dropped to 50.28, 47.04 and 44.34 g/kg for the commercial inoculant, the novel inoculant, and the control, respectively (P < 0.05). The application of additives determined higher amounts of CP and lower concentrations of NDF than the control silage (P < 0.05). Regarding NH3-N, an inoculation × time of storage interaction existed because its content markedly increased with time in untreated vetch-oat silage (P < 0.001). The highest concentration of NH3-N, 64.6 g/kg of total N, was observed at day 60 for the control group. In the silage containing the novel inoculant, the concentration was 23 g/kg of total N. Meanwhile, the content for the silage inoculated with the commercial bacteria was 42.9 g/kg of total N (P < 0.001). The variables ADF, ADL and EE were unaffected by the inoculants (P > 0.05). Although an effect inoculation × time was found for ADF and EE (P < 0.05), all groups behaved similarly over time, and the interactions observed were of no practical significance (Table 2).

Table 1. Chemical composition of vetch-oat forage before ensiling (g/kg of DM ± s.e.m.)

Note: Values are means (±s.e.m.) of three repetitions.

Table 2. Effect of time and inoculation on fermentation parameters and microbiological composition of vetch-oat silage (g/kg of DM ± s.e.m., unless otherwise stated)

Abbreviations: TN, total nitrogen; cfu, colony-forming units; s.e.m., standard error of means; T, effect of time; I, effect of inoculation; T × I, interaction effect of time and inoculation; ND, not detected.

Note: Values are means (±s.e.m.) of three repetitions.

Inoculation, ensiling time, and their interaction significantly influenced total LAB, yeasts, and moulds populations (P < 0.05). The count of LAB was notably greater (P < 0.05) in inoculated samples compared to uninoculated ones at day 30 of fermentation, but there was a reduction in total LAB counts with prolonged storage time. On the other hand, after 60 days, there was a sustained lower cell load of yeasts and moulds in native inoculant micro-silos compared to control and commercial inoculant samples (P < 0.001). The coliform counts were lower in the native inoculant forage (P = 0.011) (Table 2).

Ethanol, lactic, acetic and propionic acids were influenced by inoculation, ensiling time and their interaction (P < 0.05). The highest lactic acid concentration was observed at day 60, reaching 104.5 and 76.5 g/kg of DM for the silages inoculated with the novel and the commercial bacteria, respectively. In contrast, the lactic acid concentration for the control silage was 57.6 g/kg of DM at day 60 (P < 0.05). At day 30, the concentration of acetic acid was higher in the native and commercial inoculated silages (6.55 and 6.76 g/kg of DM) compared to the control (4.81 g/kg of DM) (P < 0.05). However, there was a subsequent decrease in acetic acid concentration in the silage treated with the commercial inoculant at the end of the fermentation period (5.34 g/kg of DM). The concentration of propionic acid was higher in the silage with the novel inoculant, followed by the silage with the commercial inoculant, reaching 1.57 and 1.07 g/kg of DM at day 60, respectively. Also, the concentration detected in the control silage was 0.871 g/kg of DM (P < 0.05). A higher ethanol content (7.82 g/kg of DM) was observed in the control compared to the treated groups at day 60 (P < 0.001). The concentration of ethanol in native and commercial inoculated silages increased from day 3 to a maximum value of 5.41 and 4.56 g/kg of DM at day 30, eventually decreasing to a concentration of 3.28 and 2.36 g/kg of DM at day 60, respectively. Butyric acid was not found in any of the samples (Table 2).

It should be noted that in the chromatograms with IR detector, two peaks with retention times similar to those of glucose and fructose were observed. It is crucial to emphasize that sucrose undergoes hydrolysis during the analysis because of the chromatographic conditions used, which involve high temperature and low pH. Consequently, the results for glucose and fructose are derived from the hydrolysis of sucrose. In the present study, no significant differences among groups in the level of glucose and fructose (P > 0.05) were observed (Table 2).

Figure 1 illustrates the temperatures in the silages during the aerobic stability test. The control silage remained stable for approximately 47 h, whereas the silages with the commercial and novel inoculants exhibited stability for at least 4 days, at which point the experiment was concluded. The highest temperature recorded in the control silage was 33.5°C. Towards the end of the assessment period, the temperature in the uninoculated silage had risen to 10°C above the ambient temperature.

Figure 1. Effects of inoculants application on temperature of vetch-oat silage during aerobic exposure.

Bacterial community analysis

The complete 16S was PCR amplified, sequenced, and analysed to trace the dynamic changes in the bacterial community composition of vetch-oat silages. The sequencing analysis on Nanopore MinION generated a total of 36 95 255 raw reads after basecalling, with an average of 153 969 reads per sample. After quality and length filtering, 21 60 827 sequence reads (58.04%) were retained with an average of 90 034 sequence reads per sample. High-quality reads were clustered into 174 OTUs. The rarefaction curves reached or nearly reached a plateau for most samples, indicating that the sequencing depth was sufficient to describe bacterial profiles during plant ensiling (figure not shown).

For beta diversity analysis, UniFrac matrices (both weighted and unweighted) were constructed. Non-metrix Multidimensional Scaling (NMDS) plots were used to visualize bacterial beta diversity patterns (Fig. 2). The main factor influencing the differentiation of the groups was time (P < 0.001) for both weighted and unweighted UniFrac measurements. Conversely, NMDS displayed no clustering of samples based on LAB inoculation (P = 0.320 for weighted, and P = 0.103 for unweighted distances). Interestingly, we observed two major clusters based on the days that had elapsed: bacterial communities of day 0 were clustered into one distinct group, whereas bacterial communities of day 30, day 60, and from the aerobic stability test were clustered into another group, in both naturally fermented and inoculated silages. The former cluster consisted of control and inoculated samples before fermentation.

Figure 2. Beta diversity NMDS plots of Unifrac distances. The NMDS plots report the distances between different vetch-oat silages using unweighted and weighted Unifrac. Symbols represent different sampling times: day 0 (circles), day 30 (triangles), day 60 (squares) and aerobic exposure (AE, plus signs). Colours represent different treatments: control (C, green), native inoculant (NI, light blue) and commercial inoculant (CI, pink).

The bacterial alpha diversity of vetch-oat silages is shown in Table 3. The number of OTUs detected ranged from 34 to 133. The Shannon index varied from 1.21 to 3.23, and the Simpson index ranged from 0.61 to 0.92. Alpha diversity indices were significantly higher at day 0 compared with other ensiling times and after aerobic exposure (P < 0.001). Besides, inoculation significantly reduced the number of observed OTUs, as well as the Shannon and Simpson indices (P < 0.05). In terms of the Shannon and Simpson diversity metrics, an inoculation × time interaction was identified (P < 0.001). The Shannon diversity index behaved in a similar manner in both supplemented silages until aerobic exposure, where a lower community diversity was identified in the silage treated with the commercial inoculant (P = 0.012). Conversely, the Simpson diversity parameter decreased up to day 30 and then remained relatively stable in the native and commercial inoculated samples (P > 0.05).

Table 3. Alpha diversity analysis of vetch-oat silages bacterial communities: observed operational taxonomic units (OTUs), Shannon and Simpson indices

Abbreviations: R, biological replicate; OTUs, operational taxonomic units; T, effect of time; I, effect of inoculation; T × I, interaction effect of time and inoculation.

Figure 3 illustrates the dynamic changes in the bacterial community composition at the genus level, according to the distribution of OTUs. In the fresh materials, the predominant genera present were Pseudomonas (40.6 ± 3.46%), followed by Stenotrophomonas (10.9 ± 7.62%), Rhizobium (10.6 ± 0.67%), Enterobacteriaceae (8.1 ± 4.59%) and Pectobacterium (7.3 ± 4.44%). The microbial community at day 0 also included Methylobacterium, Lactobacillus, Chloroplast, Staphylococcus, Mesorhizobium and Comamonas (1–5%). A smaller number of OTUs (<1% abundance) were associated with the genera Ensifer, Microbacterium, Pseudorhizobium, Siphonobacter and the Rhizobiaceae family (Fig. 3).

Figure 3. Effects of microbial inoculants on the relative abundance of bacterial community at the genus level in vetch-oat silages. The x – axis represents the name of the sample, the y – axis represents the abundance of the species. Coloured columns indicate different genera, and the length of the columns represents the proportion of the genera. C, control; NI, native inoculant; CI, commercial inoculant; AE, aerobic exposure.

After 30 days of fermentation, the abundance of Pseudomonas decreased in all cases when compared to fresh forage (P < 0.001), whereas Lactobacillus became the predominant genus in silages (P < 0.001). Moreover, significant differences were observed between inoculated and control silages (P < 0.001), with the relative values of Lactobacillus estimated at 84.2 ± 0.06% in control samples, 96.8 ± 0.44% in native inoculant forage, and 97.1 ± 0.36% in commercial inoculant samples. The relative abundance of Staphylococcus for the novel and commercial inoculant (1.7 ± 0.42% and 1.4 ± 0.35%, respectively) was significantly lower than in the control sample (13.1 ± 6.31%) (P < 0.001). As shown in Fig. 3, at this sampling time, the bacterial community revealed the presence of Rhizobium, with no differences between groups (P > 0.05) and an average content of 1.3 ± 0.03%. In the control, the differentiated bacteria included the genus Methylobacterium (0.41 ± 0.00%), Chloroplast (0.26 ± 0.00%), and Pseudomonas (0.13 ± 0.00%) (P < 0.05), but at a low frequency (Fig. 3).

At day 60, the abundance of Lactobacillus in native and commercial inoculant silages (97.0 ± 0.11% and 97.5 ± 0.53%, respectively) consistently exceeded that in the control silage (76.1 ± 13.03%) (P < 0.001). The difference between control and inoculated groups was also statistically significant for Staphylococcus (P < 0.001). This genus comprised 7.2 ± 0.70% in untreated silages, 1.2 ± 0.01% in the native inoculant forage, and 0.8 ± 0.32% in commercial inoculant samples. A small number of OTUs were associated with genus Rhizobium, totalling 6.5 ± 5.17%, 1.1 ± 0.09% and 1.4 ± 0.04% of all OTUs, respectively. As observed, the amount was significantly lower in treated silages than in the control silage (P < 0.001). The control silage displayed a more complex bacterial community composition: Methylobacterium accounted for 4.4 ± 3.98%, and Pseudomonas for 1.3 ± 1.20% of the genera present, with P < 0.05 when the relative abundances were compared to inoculated silages. Furthermore, Stenotrophomonas, Chloroplast, Microbacterium, Rhizobiaceae and Ensifer had a minor but significant representation in the control group (0.4–1.4%) (P < 0.05). The genera Mesorhizobium, Pectobacterium and Pseudorhizobium were also detected, with no significant differences among groups (P > 0.05) (Fig. 3).

After 4 days of aerobic exposure, Lactobacillus predominated in all samples, covering 92.1 ± 4.17% and 97.8 ± 0.16% of the total sequences in the native and commercial inoculant forage, respectively. It should be noticed that the relative abundance of Lactobacillus in the control (80.0 ± 0.01%) was lower than that in the treated silages (P < 0.001), whereas the relative values of Staphylococcus increased sharply in the uninoculated group when exposed to air (17.2 ± 0.48%) (P < 0.001). The genus Rhizobium remained comparatively stable in all groups, accounted for an average of 1.5 ± 0.27% of the microbiota (P > 0.05). The genera Pseudomonas and Methylobacterium were significantly lower in the commercial treated silage (P < 0.05) (Fig. 3).

Discussion

Most researchers agree that intercrops use natural resources more efficiently than pure stands (Erol et al., Reference Erol, Kaplan and Kizilsimsek2009; Baxevanos et al., Reference Baxevanos, Tsialtas, Voulgari, Pankou, Vlachostergios and Lithourgidis2020). In mixed crops, companion cereals serve as structural support for vetch growth, increase light interception, and simplify mechanical harvesting, while the vetch component is intended to improve yield and protein content of the final forage (Wang et al., Reference Wang, Chen, Yang, Zeng, Hu and Zang2021a). Further advantages gained include increase in soil organic matter, leading to better crops and soil nutrient status, improved water conservation, and reduced soil erosion (Kumar et al., Reference Kumar, Singh, Meena, Kumar, Ram, Kumar and Meena2022). In this study, intercropped vetch-oat silages were inoculated with either a native or a commercial inoculant. Both LAB inoculants influenced ensiling characteristics, aerobic stability, and bacterial community composition.

Silage pH is one key aspect that affects the end-point of fermentation and the quality of ensiled forage. In this experiment, the low final pH in the additives-treated silages indicated good fermentation attributes (Chen et al., Reference Chen, Guo, Yuan, Zhang, Li and Shao2016). After 60 days, the DM content was higher for both inoculated micro-silos, suggesting fewer nutrient losses caused by secondary fermentation. The feeding value regarding CP concentration improved with the addition of microbial inoculants. Similarly, both additives limited the formation of NH3-N/NT compared to the control. This may be due to the addition of LAB inoculants during ensiling, which ensured faster acidification, consequently restricting protein degradation and deamination processes caused by plant enzymes or proteolytic microorganisms (Wróbel et al., Reference Wróbel, Nowak, Fabiszewska, Paszkiewicz-Jasińska and Przystupa2023). In high forage diets, the content of NDF has a major impact on DM intake and ration digestibility. As the NDF content in rations increases, the consumption of lactating dairy cattle and beef cattle decreases. In the current research, the NDF levels of the treated silages were lower than those in the untreated silage, potentially due to increased acid hydrolysis of hemicellulose. Conversely, the levels of ADF, ADL and EE in the inoculated silages were similar to the control. However, it is important to note that these findings are specific to silos that were opened within a 60-day fermentation period.

As expected, silages inoculated with LAB demonstrated higher fermentation efficiency in converting WSC into lactic acid compared to those relying on epiphytic LAB. This positive effect of additives on increasing lactic acid content was in line with the observed decline in pH. Conversely, in the control group, spontaneous fermentation generated more ethanol. The rise in ethanol levels was probably counterbalanced by the application of these bio-inoculants (Gallo et al., Reference Gallo, Fancello, Ghilardelli, Zara, Froldi and Spanghero2021; Blajman et al., Reference Blajman, Signorini, Vinderola, Lingua, Romero, Páez, Casas, Bergamini, Giménez and Gaggiotti2022). In this research, ethanol concentrations decreased by day 60 in all groups. A plausible explanation is that certain microorganisms could utilize ethanol as carbon source. Schweiger et al. (Reference Schweiger, Volland and Deppenmeier2007) described that some acetic acid bacteria in silages could oxidize ethanol to acetic acid using membrane-bound dehydrogenases. Additionally, the possible volatilization of ethanol is another factor that may hinder its detection (Ávila et al., Reference Ávila, Pinto, Figueiredo and Schwan2009). Even in carefully sealed silos, there is some mass exchange between the silage and the environment. Moreover, some ethanol probably evaporated when silage samples were collected for analysis. This finding is in line with Pedroso et al. (Reference Pedroso, Nussio, Paziani, Loures, Igarasi, Coelho, Packer, Horii and Gomes2005), who noted that ethanol concentration suffered 50% reduction from the 120th to the 180th day in sugar cane silages, presumably due to the evaporation of alcohols. Both inoculated silages exhibited higher ratios of lactic /acetic acid compared to the control, indicating a shift towards homolactic fermentation. However, the addition of obligate heterofermentative L. buchneri B463 and facultative heterofermentative L. plantarum Hv75 and P. acidilactici 3903 resulted in higher levels of acetic and propionic acids in the silage containing the novel inoculant. This could be due to L. buchneri's capability to degrade lactic acid into acetic acid and 1,2-propanediol, subsequently generating propionic acid (Oude Elferink et al., Reference Oude Elferink, Krooneman, Gottschal, Spoelstra, Faber and Driehuis2001; Drouin et al., Reference Drouin, Tremblay, Renaud and Apper2021). Moreover, facultative heterofermentative LAB has both aldolase and phosphoketolase enzymes. Species in this group produce equimolar amounts of lactic and acetic acids when the substrate is a pentose, and lactic acid, ethanol, and CO2 with hexose substrates (Pessione, Reference Pessione2012). The main WSC in most silage fermentations are the hexoses fructose and glucose; however, alternative sugars for the silage microbiota may be pentoses, which are produced when matrix polysaccharides are hydrolysed (Rooke and Hatfield, Reference Rooke and Hatfield2003). Despite not being quantified in this study, xylose and arabinose can serve as important substrates for LAB in both forages (Wang et al., Reference Wang, Li, Dong, Chen, Yuan and Shao2018; Liu et al., Reference Liu, Si, Sun, Wang, Liu, Du, Gentu and Jia2023). Regardless of the differences in the concentration of acetic and propionic acids between the treated and control samples, they fell within the expected values for vetch-oat silage (Chen et al., Reference Chen, Guo, Yuan, Zhang, Li and Shao2016; Ju et al., Reference Ju, Zhao, Qin and Jiao2016).

Remarkably, increased total LAB numbers were observed in inoculated samples after 30 days of fermentation. This confirmed that the bio-inoculants established a beneficial symbiotic relationship with the host (Wang et al., Reference Wang, Li, Dong, Chen, Yuan and Shao2018). By contrast, the count of coliforms, yeasts and moulds was significantly lower in samples with the autochthonous spray-dried inoculant. Reduced deleterious microbial growth in silage could be a consequence of successful L. buchneri development, leading to an increased production of acetic and propionic acids. These compounds exert inhibitory action against yeasts and moulds by penetrating their membrane in their undissociated form at the low pH of the silage, releasing hydrogen ions into the cytosol, causing the organism to expend ATP to maintain cellular homoeostasis, ultimately disrupting cellular metabolism (Romero et al., Reference Romero, Zhao, Balseca-Paredes, Tiezzi, Gutierrez-Rodriguez and Castillo2017). On the other hand, the decrease in coliform counts observed with our native inoculant may be attributed to the inhibitory pH of the medium, the enhanced antimicrobial activities of organic acids at low pH, or both (Queiroz et al., Reference Queiroz, Ogunade, Weinberg and Adesogan2018).

It is important to emphasize that both biological inoculants provided substantial benefits by enhancing the aerobic stability of vetch-oat intercrops. The treated silages exhibited aerobic stability, as indicated by a temperature increase of no more than 2°C above the ambient temperature for 96 h. Regarding the native inoculant, enhanced aerobic stability can be elucidated by a reduced growth rate of undesirable microorganisms that initiate the deterioration process. Yeasts and moulds have long been recognized as responsible for the aerobic deterioration of silages, and it has been shown that silages containing more than 1 × 105 cfu/g of yeasts spoil as soon as oxygen becomes available (Mcdonald et al., Reference McDonald, Henderson and Heron1991). In the case of the commercial formulation, the ability of the strains to compete and reduce harmful bacteria within the silage could be associated with prolonged stability. Even though yeasts, moulds and acetic acid bacteria are commonly associated with aerobic spoilage, other bacterial populations like enterobacteria, Listeria and Bacillus spp. can also proliferate in silages exposed to air (Li and Nishino, Reference Li and Nishino2013; Queiroz et al., Reference Queiroz, Ogunade, Weinberg and Adesogan2018).

The fermentation of silages occurs through the activity of a complex microbial community, influenced by environmental factors and management practices, including the application of inoculants (Borreani et al., Reference Borreani, Tabacco, Schmidt, Holmes and Muck2018; Blajman et al., Reference Blajman, Vinderola, Páez and Signorini2020b). In this study, MinION nanopore sequencing was used to metabarcode silage bacterial communities in vetch-oat silages. This approach allowed an in-depth description of bacterial diversity at a reasonable cost.

The phylogenetic composition, as assessed by the weighted and unweighted Unifrac metrics, indicated substantial temporal changes during the fermentation, but no clear differences within treatments. Conventionally, anaerobic fermentation begins with the activity of unwanted microorganisms present in raw materials, gradually being replaced by LAB. Therefore, the fresh material remained distinctly separated from the cluster of silages, consistent with similar studies (Franco et al., Reference Franco, Tapio, Huuskonen and Rinne2022). Alpha diversity estimates for both the fresh material and experimental silages indicated higher bacterial community diversity at day 0 for all evaluated indices. This aligns with findings reported by Xiao et al. (Reference Xiao, Sun, Wang, Wang, Xin, Xu and Du2022), who, when investigating oat silage, observed increased bacterial diversity in raw material compared to terminal silage. The higher diversity at the beginning may be explained by the inability of some epiphytic microorganisms to thrive in anaerobic and acidic silage environments (Franco et al., Reference Franco, Tapio, Huuskonen and Rinne2022). On the other hand, inoculation let to an abrupt reduction in the alpha diversity of the bacterial community compared to the control. This reduction is consistent with the results by Chen et al. (Reference Chen, Bai, You, Xiao, Li and Cai2020), who reported decreased bacterial diversity indices in oat silage inoculated with LAB. The decline in diversity could be attributed to the high abundance of Lactobacillus species, as a more dominant bacterial genus tends to result in a less diverse microbial community (Ogunade et al., Reference Ogunade, Jiang, Kim, Cervantes, Arriola, Vyas, Weinberg, Jeong and Adesogan2017).

The analysis of bacterial abundance revealed that Pseudomonas was the predominant genus in fresh samples, followed by Stenotrophomonas, Rhizobium, Enterobacteriaceae and Pectobacterium. Pseudomonas and Enterobacteriaceae are considered undesirable in silage, as they may be linked to the production of biogenic amines, which can reduce the protein content and nutritional value (Dunière et al., Reference Dunière, Sindou, Chaucheyras-Durand, Chevallier and Thévenot-Sergentet2013; Queiroz et al., Reference Queiroz, Ogunade, Weinberg and Adesogan2018). Stenotrophomonas, in close association with plants, can utilize a variety of sugars and produce acid (Palleroni and Bradbury, Reference Palleroni and Bradbury1993). These genera were also present in previous reports on microbial community composition of corn stover and corn-alfalfa mixtures at early stages of ensiling (Xu et al., Reference Xu, He, Zhang and Kong2017; Wang et al., Reference Wang, Gao, Franco, Hannaway, Ke, Ding, Yu and Guo2021b). On the other hand, Rhizobium plays a beneficial role in nitrogen fixation for legumes, while Pectobacterium encompasses necrotrophic bacterial plant pathogens responsible for various diseases (Li et al., Reference Li, Ma, Liang, Tian, Yin, Xie and Xie2018). The functions of these genera during ensiling are not well-documented in the literature, and further research is needed to understand their roles (Zeng et al., Reference Zeng, Li, Guan, Yang, Liu, Liu, Du, Li, Xiao, Wang, Zhang, Huang, Xiang, Peng and Yan2020; Wang et al., Reference Wang, Wang, Li, Dong, Zhao, Nazar, Kaka and Shao2023).

At day 30 and 60, the bacterial community changed and was heavily dominated by Lactobacillus. The dominance of LAB after ensiling aligns with previous research findings (Chen et al., Reference Chen, Bai, You, Xiao, Li and Cai2020; Wang et al., Reference Wang, Shao, Li, Zhao and Dong2022b; Xiao et al., Reference Xiao, Sun, Wang, Wang, Xin, Xu and Du2022). Nevertheless, the abundance of this genus in untreated silage was lower than that in inoculated samples. These results suggested that both inoculants had the ability to affect the microbial ecology throughout the ensiling process. Uninoculated silage was characterized by the emergence of Staphylococcus. This observation is consistent with the results of Li and Nishino (Reference Li and Nishino2013), who detected Staphylococcus sciuri when Italian ryegrass silage spoiled, indicating that Staphylococcus can be detrimental to silage. Also, it is noteworthy that the genus composition of the control group exhibited diversity, with several taxa present at low relative abundances after 30 days of ensiling. These included Chloroplast, Methylobacterium and Pseudomonas -related OTUs. Methylobacterium, a strictly aerobic and neutrophilic genus, has been identified in studies of alfalfa (Ogunade et al., Reference Ogunade, Jiang, Cervantes, Kim, Oliveira, Vyas, Weinberg, Jeong and Adesogan2018) and the fermentation of fresh tea leaves (Lin et al., Reference Lin, Lin, Awasthi, Wang and Xu2021). Its abundance has been positively correlated with pH value and reduced in silages treated with microbial additives (Ogunade et al., Reference Ogunade, Jiang, Cervantes, Kim, Oliveira, Vyas, Weinberg, Jeong and Adesogan2018). By day 60, Rhizobium, Methylobacterium, Pseudomonas and Stenotrophomonas abundances were higher in the control samples. Moreover, the proportions of Rhizobiaceae, Ensifer, Microbacterium and Chloroplast became more prominent in the control group compared to the treated groups. The role of these genera in silage fermentation has not been extensively studied (Wang et al., Reference Wang, Gao, Wu and Yu2020; da Silva et al., Reference da Silva, Liu, Mellinger, Gressley, Stypinski, Moyer and Kung2022; Feng et al., Reference Feng, Shi, Chen, Degen, Qi, Yang and Zhou2022). In agricultural settings, most of the biologically fixed nitrogen derives from symbioses involving leguminous plants and bacteria from the Rhizobiaceae family. Within this family, Ensifer contains ecologically important nitrogen-fixing symbionts as well as nonsymbiotic species (Fagorzi et al., Reference Fagorzi, Ilie, Decorosi, Cangioli, Viti, Mengoni and DiCenzo2020). Additionally, Ensifer has been demonstrated to enhance photosynthesis and the growth activity of plants (Toyama et al., Reference Toyama, Mori, Tanaka, Ike and Morikawa2022). Regarding Microbacterium, members of this genus have been associated with an increase in nitrogen uptake, nitrogen accumulation and oat aerial biomass (Cerecetto et al., Reference Cerecetto, Leoni, Jurburg, Kampouris, Smalla and Babin2023). Finally, the detected Chloroplast presumably belonged to the plant sample fraction, since plant chloroplast 16S rRNA genes exhibit similarities to bacterial 16S rRNA genes (Sun et al., Reference Sun, Qiu, Zhang, Dai, Dong and Song2008), and certain methodologies have even been designed to prevent their amplification (Hanshew et al., Reference Hanshew, Mason, Raffa and Currie2013).

Following a four-day period of exposure to aerobic conditions, the presence of Lactobacillus remained prominent in all groups. However, the inoculation of LAB resulted in a higher relative abundance of this genus compared to the control samples. Specific patterns were visible between treatments, with the most noticeable difference being the increased abundance of Staphylococcus in the untreated group. Infections due to Staphylococcus are of major importance to veterinary and human medicine (Bennett et al., Reference Bennett, Walsh and Gould2013). Contaminated silage can serve as a reservoir for pathogenic bacteria, posing risks to dairy cattle health, dairy product safety and quality, as well as overall animal and human well-being (Queiroz et al., Reference Queiroz, Ogunade, Weinberg and Adesogan2018).

Conclusions

Both the spray-dried native inoculant and the lyophilized commercial additive showed positive effects on the fermentation process and the post-opening phase of vetch-oat silages compared to the control. In this work, we introduced competitive strains that optimized the pH decline and lactate production, controlled the development of undesirable microorganisms, improved some nutritional and chemical silage quality parameters, and enhanced aerobic stability compared to the control group. Through metaprofiling, we observed that the native bio-inoculant contributed to the dominance of Lactobacillus over other bacteria and reduced the risk of potential pathogens from the Staphylococcus genus entering the food chain. In conclusion, the findings of this study support and promote the use of these novel strains in the ensiling of vetch-oat at a 1:1 mixture rate. Further research is required to assess their performance when inoculated in other forage crops.

Acknowledgments

The authors would like to express their gratitude to Dr Miguel Taverna for the provision of the forage crops used in this study.

Authors’ contributions

JEB, MCG and AFA formulated and designed the study. JEB, GMS, MFE and GHP conducted sample analysis and data gathering. JMI performed statistical analyses. MSL contributed to interpretation of the data. JEB wrote the article. MCG and AFA critically reviewed and revised the article.

Funding statement

This research received financial support from the National Institute of Agricultural Technology (2019-PE-E7-I147-001, 2019-PE-E7-I150-001, 2019-PE-E1-I007-001, 2023-PD-L01-I098, 2023-PE-L04-I120), the Ministry of Production, Science and Technology of Santa Fe (PEICID-2021-060), and the National Scientific and Technical Research Council (PIBBA-28720210100116CO).

Competing interests

The authors state that they do not have any competing financial interests or personal relationships that might have influenced the work reported in this paper.

Ethical standards

Not applicable.

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Figure 0

Table 1. Chemical composition of vetch-oat forage before ensiling (g/kg of DM ± s.e.m.)

Figure 1

Table 2. Effect of time and inoculation on fermentation parameters and microbiological composition of vetch-oat silage (g/kg of DM ± s.e.m., unless otherwise stated)

Figure 2

Figure 1. Effects of inoculants application on temperature of vetch-oat silage during aerobic exposure.

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Figure 2. Beta diversity NMDS plots of Unifrac distances. The NMDS plots report the distances between different vetch-oat silages using unweighted and weighted Unifrac. Symbols represent different sampling times: day 0 (circles), day 30 (triangles), day 60 (squares) and aerobic exposure (AE, plus signs). Colours represent different treatments: control (C, green), native inoculant (NI, light blue) and commercial inoculant (CI, pink).

Figure 4

Table 3. Alpha diversity analysis of vetch-oat silages bacterial communities: observed operational taxonomic units (OTUs), Shannon and Simpson indices

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Figure 3. Effects of microbial inoculants on the relative abundance of bacterial community at the genus level in vetch-oat silages. The x – axis represents the name of the sample, the y – axis represents the abundance of the species. Coloured columns indicate different genera, and the length of the columns represents the proportion of the genera. C, control; NI, native inoculant; CI, commercial inoculant; AE, aerobic exposure.