Interdepartmental Microbiology Graduate Program, Iowa State University, Ames, Iowa, USA.
Department of Food Science and Human Nutrition, Iowa State University, Ames, Iowa, USA.
mSphere. 2024 Nov 21;9(11):e0049224. doi: 10.1128/msphere.00492-24. Epub 2024 Oct 18.
In commercial poultry farms, chicks hatch away from their progenitors from which they acquire key host-specific microbiota, like segmented filamentous bacteria (SFB) involved in gut maturation in early life. This study investigated whether providing chicken SFB to newly hatched broilers would increase their gut maturation and resistance to bacteria relevant to broiler and human health. One-day-old Ross308 broilers were orally treated with either phosphate-buffered saline (CON) or layer-derived SFB (D-SFB). On days 5, 10, 17, and 24, feces were collected to detect and enumerate SFB and . On days 8, 15, 22, and 29, birds were euthanized, intestinal samples were collected to detect and enumerate SFB through quantitative PCR (qPCR) and microscopy and expression of genes associated with gut immune function through reverse transcription-qPCR. This study showed that, despite their host specificity, layer SFB can colonize their genetically distinct relative broilers. Ileal SFB colonization was accelerated by a week with the SFB treatment and covered the proximal, medial, and distal sections of the ileum. Colonization of the ileum by SFB in early life highly activated gene expression of intestinal barrier proteins and cytokines, e.g., IL-10 and IFNγ but not IL-17. SFB treatment reduced the level of in the gut and provided superior resistance to intestinal and extraintestinal pathogens as tested . Overall, early gut colonization of SFB is imperative for the maturation of the gut immune system and the establishment of a homeostatic gut environment. Improving our understanding of gut immune maturation in food-producing animals is crucial for both human and animal health.IMPORTANCEIn commercial farms, newly hatched chicks may lack host-specific microbiota that help mature their gut immune system for lifelong health benefits. Here, introducing an avian segmented filamentous bacteria (SFB) to commercially sourced chickens orally at hatch accelerated SFB colonization of the ileum. Remarkably, SFB from layers were able to colonize broilers and enhance gut immune maturation, and this immunomodulation impacted the ability to increase intestinal and extraintestinal resistance to bacteria relevant to poultry and human health. With the antibiotic restrictions in animal production, strategies that will help mitigate infections are urgently needed. In summary, we developed a live prophylactic for newly hatched chicks to improve animal health and food safety. Due to the host specificity of SFB, our data highlight the importance of investigating the molecular mechanism of SFB interaction in their own host.
在商业家禽养殖场,雏鸡在远离其亲代的地方孵化,从亲代那里获得关键的宿主特异性微生物群,如参与早期肠道成熟的分段丝状菌(SFB)。本研究旨在探讨向刚孵化的肉鸡提供鸡 SFB 是否会增加其肠道成熟度,并提高其对与肉鸡和人类健康相关的细菌的抵抗力。本研究使用磷酸盐缓冲盐水(CON)或层源 SFB(D-SFB)对 1 日龄 Ross308 肉鸡进行口服处理。在第 5、10、17 和 24 天收集粪便,以检测和计数 SFB 和。在第 8、15、22 和 29 天,处死鸟类,收集肠道样本,通过定量 PCR(qPCR)和显微镜检测和计数 SFB,并通过逆转录 qPCR 检测与肠道免疫功能相关的基因表达。本研究表明,尽管宿主特异性,层 SFB 可以定植其遗传上不同的相对肉鸡。SFB 处理使回肠 SFB 定植提前一周,并覆盖回肠的近端、中部和远端。SFB 在早期生命中对回肠的定植高度激活了肠道屏障蛋白和细胞因子的基因表达,例如 IL-10 和 IFNγ,但不是 IL-17。SFB 处理降低了肠道中 的水平,并提供了对肠道和肠道外病原体的更好抗性。总的来说,早期 SFB 定植对肠道免疫系统的成熟和肠道内稳态环境的建立至关重要。提高我们对生产性动物肠道免疫成熟的理解对人类和动物健康都至关重要。
在商业农场中,刚孵化的雏鸡可能缺乏有助于其肠道免疫系统成熟以获得终身健康益处的宿主特异性微生物群。在这里,在孵化时通过口服向商业来源的鸡引入禽类分段丝状菌(SFB)可加速 SFB 在回肠中的定植。值得注意的是,来自层的 SFB 能够定植肉鸡并增强肠道免疫成熟,这种免疫调节影响了增加与家禽和人类健康相关的细菌的肠道和肠道外抵抗力的能力。随着动物生产中抗生素限制的增加,迫切需要寻找有助于减轻感染的策略。综上所述,我们开发了一种用于刚孵化雏鸡的活体预防性制剂,以改善动物健康和食品安全。由于 SFB 的宿主特异性,我们的数据强调了研究 SFB 在其自身宿主中的相互作用的分子机制的重要性。
