Impact of Dietary or Drinking Water Ruminococcus sp. Supplementation and/or Heat Stress on Growth, Histopathology, and Bursal Gene Expression of Broilers.

Adel Hassan Saad,Hanan A Ghoneim,Mohamed M Abdel-Daim,Walied Abdo,Nagah Arafat,Sabreen Ezzat Fadl,Ghadeer M Albadrani,Mohamed S Ahmed,Mohamed Aboubakr

doi:10.3389/fvets.2021.663577

Abstract

This research was conducted to evaluate the impact of dietary or drinking water Ruminococcus sp. supplementation and/or heat stress (HS) on the growth, serum biochemistry, tissue antioxidant, phagocytic assay, histopathology, and bursa gene expression of broilers. Day-old broiler chicks were allotted into six groups according to HS and/or Ruminococcus with or without enzyme supplementation. The first group was the control one, with a formulated diet and normal environmental temperature but without any supplement. The second group fed on Ruminococcus-supplemented diet (1 kg/kg diet). The third group fed on a formulated diet without supplement, and Ruminococcus and digestive enzymes were given in drinking water (0.1 ml/L). The fourth one was the heat stress group, with a normal formulated diet. The fifth and the sixth groups served as second and third groups, respectively, but with heat stress. The results of this experiment indicated that thermal temperature negatively affected the parameters of growth performance, serum biochemical, tissue antioxidants, and phagocytic assay. Moreover, heat stress led to pathological lesions in the internal organs and affected the expression of some genes related to heat stress, including proapoptotic genes such as caspase8 and bax, inflammatory genes such as NF-κβ1, and heat shock protein such as HSP 70 in the bursal tissue. These bad effects and abnormalities were mitigated by Ruminococcus alone or with enzyme supplementation, which improved all the above-mentioned parameters.

Highlights

Poultry is widely produced and consumed meat worldwide
Dietary supplementation of digestive enzymes and/or Ruminococcus sp. significantly (P ≤ 0.05) increased the BW and total weight gain and decreased the feed conversion ratio (FCR) compared to the control group (Table 3)
Body weight, weight gain, and FCR were improved significantly in heat stress groups that were supplemented with digestive enzymes and/or Ruminococcus sp

Summary

Introduction

Poultry is widely produced and consumed meat worldwide. Its request is expected to continue elevating to meet the animal protein requirement for the ever-growing human population. Microorganisms are heavily populated in the GIT and closely and intensively interact with the host and ingested feed These microorganisms are exogenous and enter the GIT of the bird immediately after hatching; thereafter, it becomes a warm shelter for a complex microbiome consisting primarily of anaerobic bacteria. This intestinal microbiota benefits the host through the supply of nutrients from otherwise poorly used food substrates and regulation of the digestive and immune system function [7]. It is noteworthy that HS markedly alters the intestinal microbiota by lowering the content of beneficial bacteria like Lactobacilli and Bifidobacteria and increasing the pathogenic bacteria such as coliform and Clostridium [14, 15]

Methods

Results

Discussion

Conclusion