Effects of xylanase supplementation on ruminal digestibility in fistulated non-lactating dairy cows fed rice straw

Construction and characterization of a chimeric enzyme of swollenin and xylanase to improve soybean straw hydrolysis

A study was carried out to produce a fusion protein (Swo-Xyn) using the Trichoderma reesei swollenin and Lentinula edodes xylanase and to investigate its characteristics and application in degrading soybean straw. In parallel, L. edodes xylanase (Xyn) alone was used as a control protein in application tests. The Swo-Xyn was recombined, expressed and produced by Pichia pastoris and had the maximum activity at 40 °C and pH 3.0 using xylan as substrate. The Swo-Xyn exhibited preferential hydrolysis of Xylan. The Swo-Xyn had slight low Km value (23.90 vs. 25.36 mg/ml) but significantly low Vmax value (162.4 vs. 227.2 μmol/mg·min) and specific activity (18.82 vs. 38.97 U/mg) relative to the Xyn. The Swo-Xyn activity was enhanced by Zn2+ in dose dependent manners with the peak activity at 30 mM of Zn2+. The Swo-Xyn could tolerate 15% of methanol, ethanol, aceton, and DMSO with >60% residual activity. The Swo-Xyn had the greater tolerance to SDS, EDTA, 2-ME than the Xyn and could be activated by DTT, Triton X-100, and Tween 20. Compared with the Xyn, the hydrolysis and sequent cellulose enzymolysis of soybean straw could be better improved by the Swo-Xyn. The Swo-Xyn should be more useful for improving the utilization of soybean straw.

Effect of Xylanase and Phytase Supplementation on Goat's Performance in Early Lactation

BACKGROUND AND OBJECTIVES

Supplementing diets of dairy animals with phytase and xylanase can enhance phosphorus availability and fiber degradation in the rumen and positively affect animal's health and productivity. In vitro and in vivo trials have been conducted to define the optimal addition level of xylanase and phytase to lactating Baldi goat's rations and investigate effects of these enzymes on animal's nutrients digestibility, blood chemistry, milk production and milk composition.

MATERIALS AND METHODS

In vitro batch culture technique was used to evaluate the effect of phytase and xylanase supplementation at different levels (0, 1, 2 and 3 g kg-1 DM) on rumen fermentation characteristics. Eighteen early lactating Baldi goats were randomly assigned into three groups and fed 4% dry matter according to their body weight. The first group was fed control ration (35% yellow corn, 20% corn stalks, 20% berseem hay, 12.5% soybean meal and 12.5% wheat bran), the second group fed control ration+Penizyme at 2 g kg-1 DM (R1), while the third group fed control ration+Phtase-Plus® at 1 g kg-1 DM (R2).

RESULTS

Xylanase and phytase supplementation increased the in vitro DM and OM degradability and ruminal NH3-N and total volatile fatty acids (TVFA) concentrations, with no effect on total gas production (TGP) volume. All nutrients digestibility (except CP), blood serum glucose concentration, milk production and milk components yields were increased for enzymes supplemented goats than control.

CONCLUSION

Inclusion of xylanase and phytase in lactating goat's rations improved their productive performance with no deleterious effects on their health.

Expression of a Recombinant Lentinula edodes Xylanase by Pichia pastoris and Its Effects on Ruminal Fermentation and Microbial Community in in vitro Incubation of Agricultural Straws

Agricultural straws, such as rice straw, wheat straw, and corn straw, are produced abundantly every year but not utilized efficiently in China. An experiment was conducted to determine the effects of recombinant xylanase on ruminal fermentation and microbial community structure in in vitro incubation of these straws. The recombinant xylanase from Lentinula edodes (rLeXyn11A) was produced in Pichia pastoris. The optimal temperature and pH for rLeXyn11A were 40°C and 4.0, respectively. The rLeXyn11A featured resistance to high temperature and showed broad temperature adaptability (>50% of the maximum activity at 20-80°C). Supplemental rLeXyn11A enhanced the hydrolysis of three agricultural straws. After in vitro ruminal incubation, regardless of agricultural straws, the fiber digestibility, acetate concentration, total volatile fatty acids (VFAs) production, and fermentation liquid microbial protein were increased by rLeXyn11A. Supplemental rLeXyn11A increased the ammonia-N concentration for corn straw and rice straw. High throughput sequencing and real-time PCR data showed that the effects of rLeXyn11A on ruminal microbial community depended on the fermentation substrates. With rice straw, rLeXyn11A increased the relative abundance of fibrolytic bacteria including Firmicutes, Desulfovibrio, Ruminococcaceae and its some genus, and Fibrobacter succinogenes. With wheat straw, rLeXyn11A increased the relative abundance of Ruminococcus_1 and its three representative species F. succinogenes, Ruminococcus flavefaciens, Ruminococcus albus. With corn straw, the fibrolytic bacteria Firmicutes, Christensenellaceae_R_7_group, Saccharofermentans, and Desulfovibrio were increased by rLeXyn11A. This study demonstrates that rLeXyn11A could enhance in vitro ruminal digestion and fermentation of agricultural straws, showing the potential of rLeXyn11A for improving the utilization of agricultural straws in ruminants.