Effect of alfalfa microbiota on fermentation quality and bacterial community succession in fresh or sterile Napier grass silages

Abstract

The aim of this study was to reveal the reconstitution dynamics of alfalfa microbiota and their contribution to the fermentation quality of Napier grass silages. Napier grass was harvested at approximately 20% dry matter content, chopped to a theoretical length of cut of 2 to 3 cm, and ensiled in laboratory polyethylene plastic bags (400 × 250 mm) for 30 d. The Napier grass was treated with the following: natural fermentation and distilled water (NG), inoculum of alfalfa microbiota (AM), gamma-ray irradiation and distilled water (IR), and gamma-ray radiation and alfalfa microbiota (IR+AM). Three milliliters of inoculum (containing 8.93 log cfu/mL lactic acid bacteria, 9.76 log cfu/mL Enterobacteriaceae, 5.94 log cfu/mL yeast, and 6.53 log cfu/mL mold) eluted from equivalent fresh alfalfa (450 g) was added to each silo of AM and IR+AM treatments, and 3 mL of distilled water was added to the silo of the NG and IR treatments. Three triplicate silos per treatment were opened on d 1, 3, 5, 7, 14, and 30 for sampling and analysis of fermentation quality and bacterial community. Relative to the NG silages, IR+AM silages exhibited a higher lactic acid concentration. The higher acetic acid concentration in NG than in IR+AM silages after 7 d of ensiling was attributed to the dominant genus of Leuconostoc (64.29–49.04%). Adding alfalfa microbiota to sterile Napier grass could increase ammonia-N concentration compared with NG and IR silages after 3 d of ensiling. Leuconostoc was the most predominant genus in NG silages, followed by Lactobacillus. Pediococcus had a greater relative abundance than the indigenous microorganisms and was exclusively found in AM and IR+AM silages, whereas Lactobacillus exhibited a slight increase after 30 d of ensiling (relative abundance in each silage: 6.29 vs. 3.82%, respectively). Lactobacillus was the predominant genus in IR silages since the onset of the ensiling. These results suggest that alfalfa microbiota affected bacterial community succession in Napier grass silages, which in turn affected the fermentation products. Adding alfalfa microbiota to sterile Napier grass could decrease acetic acid concentration compared with NG silages; however, it increased ammonia-N concentration compared with IR silages after 3 d of ensiling.