Lactic Acid Bacteria Influence Silage Fermentation Characteristics and Bacterial Community Composition of Oat in Cold Region

DOI: https://doi.org/10.21203/rs.3.rs-743017/v1

Abstract

Background: Lactic acid bacteria have been proposed for the control of undesirable fermentation and subsequently aerobic deterioration due to their ability to produce antimicrobial metabolites in silage mass. To investigate the effect of specific LAB on silage fermentation characteristics and bacterial community composition of oat in cold region, silages were treated without additives (CK) or with three LAB strains (LB, Lactobacillus buchneri; nLP, low temperature tolerant Lactobacillus planrtarum; pLP, phenyllactic acid-producing Lactobacillus plantarum), and then stored at ambient temperature (< 20 ℃) for 30, 60 and 90 days.

Results: Compared with CK, inoculation of LAB decreased final pH value, butyric acid content, ammonia-N of total N and dry matter loss of silage. Treatments with nLP and pLP increased (P < 0.05) lactic acid content, whereas LB increased (P < 0.05) acetic acid content of silage. Lactobacillus and Leuconstoc dominated in the silages with relative abundance of 68.29~96.63%. A prolonged storage period enhanced growth of Leuconstoc in pLP treated silage. In addition, pLP increased (P < 0.05) aerobic stability of silage as compared with nLP.

Conclusions: In conclusion, inoculation of LAB improved silage fermentation and/or delayed aerobic deterioration by shifting bacterial community composition during ensiling. Phenyllactic acid-producing Lactobacillus plantarum as an inoculant exhibited potential for high quality silage production.

Background

Ensiling is an important technique for preserving fresh forage. However, the heavy distribution of undesirable microorganisms such as aerobic bacteria, yeasts and molds during ensiling and after exposure to air is a concerned issue in the world. Microbial additives have been applied to specifically elevate dominance of bacterial genera such as Lactobacillus, Pediococcus and Leuconstoc for optimizing silage fermentation process. Lactic acid bacteria (LAB) have been included in microbial additives, due to their active antagonistic metabolites including organic acids, fatty acids, ethonal hydrogen peroxide, acetoin, diacetyl, cyclic dipeptides, bacteriocins, or bacteriocin-like inhibitory substances during silage fermentation [1]. However, lower ambient temperature can undesirably delay or stop production of lactic and acetic acids during ensiling in cold region [2]. Recently, some specific LAB strains were used as inoculants for functional preservation of silage nutrients. For example, species of Lactobacillus buchneri (L. buchneri) and/or low temperature tolerant Lactobacillus plantarum (L. plantarum) is combined in microbial inoculants for functionally advancing silage fermentation process and reducing aerobic spoilage initiated by lactate-assimilating yeasts in cold region [3].

Phenyllactic acid, as an eco-friendly antimicrobial agent with high stability under low temperature condition [4], can inhibit the growth of pathogenic bacteria, yeasts and molds in foods [5]. Phenyllactic acid is also investigated for animal feeding and disease prevention as an alternative to the use of antibiotic substances [6]. Some species of LAB such as L. plantarum, L. casei and P. acidlactici can produce phenyllactic acid [7]. Ström [8] firstly isolated a L. plantarum strain (MiLAB 393) from grass silage that produces broad-spectrum antifungal compounds, active against food- and feed-borne filamentous fungi and yeasts in a dual-culture agar plate assay. In our laboratory, a LAB strain L. plantarum was isolated from natural fermented-oat silage on the Qinghai Tibetan Plateau, and exhibited high phenyllactic acid-producing ability of 94.2 mg/mL in MRS broth incubated at 28 ℃ for 24 h. However, little information is how the strain affects quality of silage.

In addition, amounts of fresh oat were left on the land due to the unstable weather conditions on the Qinghai Tibetan Plateau. The ambient temperature falls to < 15 ℃, which usually results in unfinished fermentation during ensiling and rapid deterioration after exposure to air. Hence, the objective of the present study was to compare the effects of specific LAB including L. buchneri, low temperature tolerant L. plantarum and phenyllactic acid-producing L. plantarum on the fermentation characteristics, bacterial community composition and aerobic stability of oat silage stored on the Qinghai Tibetan Plateau. Our hypothesis was that the three LAB strains could functionally improve silage quality of oat under low storage temperature (< 20 ℃) condition.

Results And Discussion

The chemical compositions and number of LAB and yeasts of fresh forage were shown in Table 1. The additive, storage period and their interaction significantly (P < 0.05) affected the DM loss and WSC of silages. The contents WSC of silages tended to decrease and DM loss tended to increase with storage period (P < 0.05). The DM content of fresh forage was 24.55%. The WSC content (8.91 %DM) of fresh forage was sufficient for an adequate fermentation process during ensiling. Inoculations of functional LAB treatments decreased DM loss as compared with the control silage in our study, that because LAB causing reduction of DM loss in silage fermentation [9]. The significant higher DM loss reported in LB silage than nLP and pLP silages was due to the production of carbon dioxide by LB (L. buchneri) through heterofermentative fermentation, resulting in considerable DM losses [9]. However, the epiphytic LAB count (2.81 lg cfu/g of FM) on the plants was below the minimum requirement (5.0 lg cfu/g FM) for high quality silage. In addition, high yeasts count (4.71 lg cfu/g of FM) distributed on the plants may increase potential for more DM loss during ensiling. As speculated, the control silage showed poor fermentation with pH of 4.45~4.55, butyric acid of 0.13~0.16 %DM and ammonia-N of 14.3~18.72 %TN (Table 2). The counts of LAB and yeasts of fresh forage in our study were lower than the results of Wang [10] who reported that the LAB and yeasts counts of fresh oat were 5.61 and 8.45 lg cfu/g of FM, respectively. A similar situation was also observed by Chen [3], who reported that both forages growing at different geographic locations but with similar maturity stage had inconsistent microbial composition and structure on the plants, which were caused by ambient temperature differences [11].

The additive, storage period and their interaction significantly (P < 0.05) affected the lactic acid, ammonia-N and aerobic stability of silages (Table 2). In the present study, inoculations of functional LAB increased lactic acid content and decreased pH value, butyric acid content and ammonia-N of total N of silages. The fermentation quality of nLP silage was the best, mainly reflected in that nLP silage had the lowest pH (< 4.2) and ammonia-N (10.25~12.13 %TN), and the highest LA content (> 3 %DM). This indicated that nLP strain could better play its role in low temperature environment than other LAB strains [3]. Inoculation of LB increased acetic acid content of silage. Similar result on oat silage was from Gomes [12]. Moreover, the concentration of lactic acid occurred highest and changed little in nLP-inoculated silage. This was probably because of the metabolism of exogenous strains of L. plantarum, functionally capable of quickly production of lactic acid under low temperature condition [3]. 

In the present study, LB (L. buchneri) silage had the highest (P < 0.05) aerobic stability (> 170 h) than other silages. The use of L. buchneri to improve aerobic stability has proved valuable, due to its production of acetic acid [13]. A similar situation was found by Kleinschmit and Kung [14] who evaluated 43 studies that inoculated L. buchneri in different forages to ensilage and reported that inoculant improved the aerobic stability of silages. In fact, the aerobic stability of pLP inoculated silages also exhibited higher stability than control and nLP inoculated silages (Table 2). This may be due to the fact that production of phenyllactic acid (14.4~16.8 ‰DM) and acetic acid (0.36~0.38 %DM) during ensiling could damage the membrane integrity, interrupted the outer membrane permeability, and then interact with microbial genomic DNA in the manner of intercalation [5, 15].

Phenyllactic acid has recently been proposed for their activities against bacteria, yeasts and molds in foods [5] and animal diet [6] for their very low toxicity for animal and humans. In addition, phenyllactic acid could be produced at a low-cost by effectively fermentation modes through lactic acid bacteria [16]. In our study, a high phenyllactic acid content (14.4~16.8 ‰DM) was detected in pLP silage, but not in the other silages. This indicated that the phenyllactic acid produced by pLP strain could be effectively used as an antifungal compound to delay the growth of a variety of fungal contaminants and also to extend the self life of feed stuffs [17]. At the same time, Phenyllactic acid-producing LAB exhibited potential for enhancing quality of fermented-products. Compared with LB and control, the inoculation of pLP did shift fermentation characteristics with high lactic acid (2.43~2.86 %DM) and low butyric acid (0.05~0.06 %DM) of silage. However, the pLP inoculated silage showed higher (< 0.05) ammonia-N of total N and numbers of yeasts and lower LAB of than nLP inoculated silage. This may be due to the fact that low temperature tolerant L. plantarum could robust for rapid pH reduction to inhibit plant inherent proteolysis and undesirable microorganisms such as Clostridia [3]. 

It is well known that natural fermentation of forages depends on epiphytic microflora especially count of LAB in an anaerobic environment [18]. In addition, various bacterial communities and successions have been found in different pre- and post-silage forages [19]. Therefore, bacterial community composition plays a vital role in silage fermentation, and knowing community composition is a necessary condition to understand the complex process of ensiling [20]. Next generation sequencing could help us better understanding on the silage fermentation pattern. In the present study, the bacterial alpha diversity indices of OTU and Chao 1 increased as the storage period prolonged (Fig.1). This may be due to the higher silage pH of > 4.2, which exert a limited effect on most undesirable acid tolerant microbes in silage [10]. The main microorganisms of fresh oat were uncultured bacterium (37.13%), Pantoea (33.12%) and Pseudomonas (19.55%), which differs from previous results showing that Enterobacter, Pantoea and Serraia were the predominant genera in fresh soybeans [21], and Agrobacterium, Microbacterium and Sphingobacterium were dominated the microbial composition in fresh whole crop corn [20]. Previous studies have illustrated that colonization of plant surfaces by bacteria depends on many factors, including material species, climate, period of duration, geographical location, solar radiation intensity and the type of fertilizer used [10, 12, 22].

Over the 30-90 d of ensiling, the bacterial communities in the silages were highly dominated by the genera belonging to LAB while undesirable microbial communities were extensively inhibited (Fig.2). Genera of Lactobacillus and Leuconostoc dominated in the silages, with relative abundance of 68.29~96.63%. Similar observation was reported by Xu [20], who found that most of the undesirable microorganisms were inhibited after fermentation, and Lactobacillus (> 98%) was the dominant genera in corn silages stored for 90 days. Lactobacillus is a rod-shaped LAB that can convert plant carbohydrates into LA to decline pH value of silage. In our study, nLP silages had higher relative abundance of Lactobacillus than other silages. This is the main reason why nLP silages had the highest LA content and the lowest pH than other group silages (Table 2). Compared with control, inoculations of functional LAB increased the relative abundance of Lactobacillus by 21.62~75.88%, but decreased that of Leuconotoc by 16.88~75.05% in silages. The pLP inoculated silage showed low relative abundance of Lactobacillus and high relative abundance of Leuconostoc in relative to LB and nLP inoculated silages. A prolonged storage period reduced the positive effects from LAB inoculation on increase in relative abundance of Lactobacillus and decrease in relative abundance of Leuconstoc in silage, which increased potential for aerobic deterioration [23]. 

Conclusions

Inoculation of specific LAB could improve fermentation quality and shift bacterial community composition of oat silage. Both L. buchneri and pheneyllactic acid-produced L. plantarum increased aerobic stability of silage. In particular, phenyllactic acid-produced L. plantrarum, as a silage inoculant, enriched Leuconstoc and Lactobacillus during ensiling.

Methods

Materials and silage preparation

Experiment was conducted at the Hongyuan experimental base of Sichuan Academy of Grassland Sciences (44°53'N, 7°41'E, altitude 3500 m), which locates on the Qinghai Tibetan Plateau in P. R. China. Oat at milk stage was harvested as ensiling material at September 10, 2020. The harvested oat was chopped using a chopper, and randomly divided into thirty-six 10-kg piles to obtain nine replications per treatment. The treatments were as follows: control without additives (CK); LB, L. buchneri isolated from natural-fermented silage; nLP, low temperature tolerant L. plantarum isolated from natural fermented-reed canary grass silage [3]; pLP, phenyllactic acid-producing L. plantarum isolated from natural fermented-oat silage and preserved at China General Microbiological Cultural Collection Center (No.14117). To reduce negative effects from addition amounts, each LAB was applied at a rate of 106 cfu/g of fresh matter (FM). Each LAB was separately diluted in sterilized water, and sprayed uniformly onto the forage using a hand sprayer, which was constantly hand mixed and yield applying amount of 4 L inoculant-diluted solution/t of fresh forages. The same amount of water was added to the CK treatment. And, the treated forage from each pile was packed in a 20 L plastic silo equipped with a lid that only enabled gas release. The density of all silages was about 500 ± 25 kg/m3 on FM basis. Three of silage silos with same treatment were sampled after 30, 60 and 90 days of ensiling at ambient temperature of < 20 ℃. Samples from the fresh forage and the silages were subject to analysis of chemical composition, aerobic stability, microbial population and/or bacterial community. 

Chemical analysis

Samples were dried at 65 ℃ for a constant weight to determine dry matter (DM) content, and then ground through 0.20 mm sieve for water soluble carbohydrate (WSC) analysis by the method of McDonald [24]. The DM loss was calculated by formula as follows: DM loss (%) = 100 × [1 - (pre-ensiled forage weight / silage weight at opening)]. 

Fresh sample of 20 g was mixed with 180 mL ultrapure water for 3 min in a stomacher blender. The pH of filtrate was determined by pH meter. Filtrate of about 10 mL was subjected to centrifugation (4500×g, 15 min, 4 °C), and the supernatant was analyzed for lactic acid, acetic acid, propionic acid and butyric acid using high performance liquid chromatography [25]. Identification and quantification of phenyllactic acid was determined by the method of Jung [5]. Ammonia nitrogen was determined by methods of Broderick & Kang [26].

Microbial population analysis

Microbial population on fresh samples was determined by the method of Cai [27]. Ten grams of each fresh sample were put into a sterile glass bottle, suspended in 90 mL of sterile water, and homogenized for 2 h in a laboratory blender (LB20ES, Shanghai Prime Science Co., Ltd, Shanghai, China). Serial dilutions were made. The number of LAB were counted on MRS agar (GCM188, Land Bridge Technology Co., Ltd, Beijing, China), incubated at 37 °C for 48 h. Yeasts were counted on malt extract agar with 1.5 mg/L Tetracycline (CM173, Land Bridge Technology Co., Ltd, Beijing, China), incubated at 30 °C for 48 h. Yeasts were distinguished from molds by colony appearance and observation of cell morphology.

Bacterial community analysis

The extraction of bacterial DNA from fresh sample was determined by the method of Li [25]. In brief, Phusion®High-Fidelity PCR Master Mix (New England Biolabs) was used to carry out PCR reactions, following the manufacturer’s instructions. The primer 515 F and 907 R was chosen to amplify the V4-V5 region of 16S rRNA gene. The PCR amplicons were then sequenced by using an Illumina MiSeq PE2500 platform at Novogene Company (Beijing, China). After sequencing, paired reads were merged using FLASH (V 1.2.7), and filtered by QIIME. The uparse method was employed to assign operational taxonomic units (OTUs) to the 16S rRNA at a cutoff level of 3% on the Usearch software platform (version 7.1). Based on OTUs results, the alpha indices were calculated with QIIME (Version 1.7.0) and displayed with R software (Version 2.15.3).

Aerobic stability

The aerobic stability of silage was measured by the method of Kung [13]. At silo opening, approximately 5.0 kg of silage from each silo was returned to clean buckets without packing under air-controlled temperature of 25 ± 0.5 °C. A thermocouple probe was placed in the geometric center of each silage mass, and temperatures were recorded by a data logger (YA204R, YADU Electronic Technology Co., Ltd, Shanghai, China) every 30 minutes. Silos were covered with 2 layers of cheesecloth and exposed to air. Aerobic stability was determined as the number of hours before the temperature of the silage mass increased 2 °C above ambient temperature of each silage mass.

Statistical analysis

Data was analyzed as a 4 × 3 factorial arrangement in a completely randomized design. The model included the fixed effects of additive (A), storage period (S), and their interaction (A × S). Data were analyzed using the Fit Model procedure of JMP (SAS Institute Inc., Cary, NC), and differences are reported as significant when P ≤ 0.05. Means were separated by Tukey’s test (P ≤ 0.05). 

Abbreviations

A: additive; A×S: Interaction between additive and storage period; CK: Control without additives; DM: Dry matter; FM: Fresh matter; nd: No detected; LAB: Lactic acid bacteria; LB: Lactobacillus buchneri; Nlp: Low temperature tolerant Lactobacillus planrtarum; pLP: phenyllactic acid-producing Lactobacillus plantarum; S: Storage period; SEM: Standard error of mean; WSC: Water soluble carbohydrate;

Declarations

Acknowledgments

Not applicable.

Funding

This work was supported by Sichuan Operating expenses for basic scientific research (2020), Guizhou Talent Base of Grassland Ecological Animal Husbandry (RCJD2018-13) and Guizhou University Laboratory Open Project (SYSKF2021-017). 

Availability of data and materials

Not applicable.

Authors’ contributions

PL and CC designed the experiments and revised the manuscript. QMC, CLY and YLC performed the experiments. QMC and CLY wrote the manuscript. PL and QMC carried out the data analysis. All authors reviewed and considered the manuscript.

Ethics approval and consent to participate

Not applicable.

Consent for publication

Not applicable.

Competing interests

The authors declare that they have no competing interests.

Publisher’s Note

Springer Nature remains neutral regarding jurisdictional claims in published maps and institutional affiliations.

Author details

1College of Animal Science, Guizhou University, Guiyang 550025, China. 2Sichuan Academy of Grassland Sciences, Chengdu 611731, China.

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Tables

Table 1  The chemical and microbial compositions of fresh forage

Item

Fresh forage

CK

 

LB

 

nLP

 

pLP

SEM

P-value (just for silages)

30 d

60 d

90 d

 

30 d

60 d

90 d

 

30 d

60 d

90 d

 

30 d

60 d

90 d

A

S

A×S

DM, %

24.55

25.46

26.59

25.72

 

26.12

27.75

25.27

 

25.29

26.18

26.44

 

26.38

26.00

26.82

0.72

0.197

0.241

0.508

DM loss, %

_

3.17c

3.48b

3.86a

 

2.65d

2.82d

3.41bc

 

1.81g

1.96fg

2.08f

 

2.21e

2.34de

2.58d

0.26

<0.001

<0.001

<0.001

WSC, %DM

8.91

2.18b

1.98bc

0.17d

 

2.15b

1.87c

0.20d

 

3.19a

2.28b

2.16b

 

3.21a

2.19b

0.32d

1.02

<0.001

<0.001

<0.001

LAB, lg cfu/g of FM

2.81

5.55d

5.43d

5.58d

 

8.12b

9.42a

9.66a

 

9.45a

9.88a

9.52a

 

6.89c

7.45c

7.16c

0.54

<0.001

0.137

<0.001

Yeasts, lg cfu/g of FM

4.17

3.1

3.36

3.48

 

<1.0

<1.0

<1.0

 

<1.0

<1.0

<1.0

 

2.22

2.14

2.10

A, additive; A×S, interaction between additive and storage period; CK, control without additives; DM, dry matter; LAB, lactic acid bacteria; LB, Lactobacillus buchneri; nLP, low temperature tolerant Lactobacillus plantarum; pLP, phenyllactic acid-producing Lactobacillus plantarum; S, storage period; SEM, standard error of mean; WSC, water soluble carbohydrates. Means in rows with unlike superscripts differed at level of < 0.05. 

 

Table 2  The fermentation quality and aerobic stability of silages after30, 60 and 90 days of ensiling

Item

CK

 

LB

 

nLP

 

pLP

SEM

P-value

30 d

60 d

90 d

 

30 d

60 d

90 d

 

30 d

60 d

90 d

 

30 d

60 d

90 d

A

S

A×S

pH

4.55a

4.45b

4.51ab

 

4.41bc

4.34c

4.38bc

 

4.18d

4.19d

4.14d

 

4.42bc

4.41bc

4.44b

0.06

<0.001

0.056

0.115

Phenyllactic acid, ‰DM

<0.1

nd

nd

 

nd

nd

nd

 

nd

nd

nd

 

16.8

14.4

15.1

Lactic acid, % DM

2.02e 

1.88e

1.89e

 

2.26cd 

2.22cd

2.23cd

 

3.02a

3.19a

3.06a

 

2.86b

2.49c

2.43cd

0.39

<0.001

<0.001

<0.001

Acetic acid, % DM

0.24

0.28

0.32

 

0.71

0.79

0.80

 

0.17

0.18

0.16

 

0.36

0.38

0.37

0.14

0.008

0.195

0.466

Propionic acid, % DM

nd

nd

0.14

 

0.25

0.20

0.22

 

nd

nd

0.05

 

nd

0.15

0.17

0.01

Butyric acid, % DM

0.16

0.14

0.13

 

0.10

0.08

0.09

 

0.08

0.09

0.09

 

0.06

0.06

0.05

0.01

<0.001

0.216

0.179

Ammonia-N, %TN

14.3c

18.72a

18.5a

 

12.61d

14.27c

15.07b

 

10.25e

11.48e

12.13e

 

12.31d

13.42c

14.97b

1.04

<0.001

<0.001

<0.001

Aerobic stability, h

86e

84e

98d

 

171a

179a

184a

 

96d

100d

98d

 

118c

122c

142b

8.41

<0.001

<0.001

<0.001

A, additive; A×S, interaction between additive and storage period; CK, control without additives; DM, dry matter; LB, Lactobacillus buchneri; nd, no detected; nLP, low temperature tolerant Lactobacillus plantarum; pLP, phenyllactic acid-producing Lactobacillus plantarum; S, storage period; SEM, standard error of mean; TN, total nitrogen. Means in rows with unlike superscripts differed at level of < 0.05.