Saladrigas-García Mireia, Durán Mario, D'Angelo Matilde, Coma Jaume, Pérez José Francisco, Martín-Orúe Susana María
Servicio de Nutrición Y Bienestar Animal. Departamento de Ciencia Animal Y de los Alimentos, Universitat Autònoma de Barcelona, 08193, Bellaterra, Barcelona, Spain.
Grupo Vall Companys, 25191, Lleida, Spain.
Anim Microbiome. 2022 Dec 26;4(1):68. doi: 10.1186/s42523-022-00221-9.
The establishment of the gut microbiota can be influenced by several perinatal factors, including, most importantly, the maternal microbiota. Moreover, early-life environmental variation affects gut microbial colonization and the intestinal health of offspring throughout life. The present study aimed to explore the development of piglet gut microbiota from birth to weaning in the commercial practice and also to assess how different farm environments could condition this process. Although it is possible to find in the literature other studies with similar objectives this work probably represents one of the few studies that make a systematic evaluation of such differential factors under a real scenario. To achieve this objective, we performed two trials. In a first Trial, we selected 2 farms in which we performed an intensive sampling (5 samples /animal) to characterize the gut colonization pattern during the first days of life and to identify the time window with the greatest impact. Both farms differed in their health status and the use of antimicrobials in the piglets. In a second Trial, we selected 4 additional farms with variable rearing conditions and a distinctive use of antimicrobials in the sows with a simplified sampling pattern (2 samples/animal). Faecal samples were obtained with swabs and DNA was extracted by using the PSP® Spin Stool DNA Kit and sequencing of the 16S rRNA gene (V3-V4 region) performed by Illumina MiSeq Platform.
The present study contributes to a better understanding of microbiome development during the transition from birth to weaning in commercial conditions. Alpha diversity was strongly affected by age, with an increased richness of species through time. Beta diversity decreased after weaning, suggesting a convergent evolvement among individuals. We pinpointed the early intestinal colonizers belonging to Bacteroides, Escherichia-Shigella, Clostridium sensu stricto 1, and Fusobacterium genera. During lactation(d7-d21 of life), the higher relative abundances of Bacteroides and Lactobacillus genera were correlated with a milk-oriented microbiome. As the piglets aged and after weaning (d36 of life), increasing abundances of genera such as Prevotella, Butyricimonas, Christensenellaceae R-7 group, Dorea, Phascolarctobacterium, Rikenellaceae RC9 gut group, Subdoligranulum, and Ruminococcaceae UCG-002 were observed. These changes indicate the adaptation of the piglets to a cereal-based diet rich in oligosaccharides and starch. Our results also show that the farm can have a significant impact in such a process, evidencing the influence of different environments and rearing systems on the gut microbiota development of the young piglet. Differences between farms were more noticeable after weaning than during lactation with changes in alpha and beta biodiversity and specific taxa. The analysis of such differences suggests that piglets receiving intramuscular amoxicillin (days 2-5 of life) and being offered an acidifying rehydrating solution (Alpha farm in Trial 1) have a greater alpha diversity and more abundant Lactobacillus population. Moreover, the only farm that did not offer any rehydrating solution (Foxtrot farm in Trial 2) showed a lower alpha diversity (day 2 of life) and increased abundance of Enterobacteriaceae (both at 2 and 21 days). The use of in-feed antibiotics in the sows was also associated with structural changes in the piglets' gut ecosystem although without changes in richness or diversity. Significant shifts could be registered in different microbial groups, particularly lower abundances of Fusobacterium in those piglets from medicated sows.
In conclusion, during the first weeks of life, the pig microbiota showed a relevant succession of microbial groups towards a more homogeneous and stable ecosystem better adapted to the solid dry feed. In this relevant early-age process, the rearing conditions, the farm environment, and particularly the antimicrobial use in piglets and mothers determine changes that could have a relevant impact on gut microbiota maturation. More research is needed to elucidate the relative impact of these farm-induced early life-long changes in the growing pig.
肠道微生物群的建立会受到多种围产期因素的影响,其中最重要的是母体微生物群。此外,生命早期的环境变化会影响肠道微生物的定植以及后代一生的肠道健康。本研究旨在探讨商业养殖中仔猪从出生到断奶期间肠道微生物群的发育情况,并评估不同的农场环境如何影响这一过程。虽然在文献中可以找到其他具有类似目标的研究,但这项工作可能是少数在实际场景下对这些差异因素进行系统评估的研究之一。为实现这一目标,我们进行了两项试验。在第一项试验中,我们选择了2个农场,在其中进行密集采样(每头动物5个样本),以表征生命最初几天的肠道定植模式,并确定影响最大的时间窗口。两个农场在仔猪的健康状况和抗菌药物使用方面存在差异。在第二项试验中,我们选择了另外4个养殖条件不同且母猪抗菌药物使用情况独特的农场,采用简化采样模式(每头动物2个样本)。用拭子获取粪便样本,并使用PSP® Spin Stool DNA试剂盒提取DNA,通过Illumina MiSeq平台对16S rRNA基因(V3 - V4区域)进行测序。
本研究有助于更好地理解商业养殖条件下从出生到断奶期间微生物组的发育情况。α多样性受年龄影响很大,随着时间推移物种丰富度增加。断奶后β多样性降低,表明个体间存在趋同进化。我们确定了属于拟杆菌属、埃希氏菌 - 志贺氏菌属、严格梭菌属1和梭杆菌属的早期肠道定植菌。在哺乳期(生命的第7 - 21天),拟杆菌属和乳杆菌属的相对丰度较高与以奶为导向的微生物组相关。随着仔猪年龄增长和断奶后(生命的第36天),观察到普雷沃氏菌属、丁酸单胞菌属、克里斯滕森菌科R - 7组、多雷亚菌属、考拉杆菌属、瘤胃菌科RC9肠道组、亚多格兰菌属和瘤胃球菌科UCG - 002等菌属的丰度增加。这些变化表明仔猪适应了富含寡糖和淀粉的谷物类日粮。我们的结果还表明,农场在这一过程中可产生重大影响,证明了不同环境和养殖系统对仔猪肠道微生物群发育的影响。断奶后农场间的差异比哺乳期更明显,α和β生物多样性以及特定分类群均有变化。对这些差异的分析表明,在生命的第2 - 5天接受肌肉注射阿莫西林且饮用酸化补液(试验1中的阿尔法农场)的仔猪具有更高的α多样性和更丰富的乳杆菌种群。此外,唯一未提供任何补液的农场(试验2中的狐步农场)在生命第2天显示出较低的α多样性,且肠杆菌科丰度增加(在第2天和第21天均如此)。母猪使用饲料抗生素也与仔猪肠道生态系统的结构变化有关,尽管丰富度或多样性没有变化。不同微生物组中可记录到显著变化,特别是来自用药母猪的仔猪中梭杆菌属丰度较低。
总之,在生命的最初几周,仔猪微生物群显示出微生物群向更均匀、稳定的生态系统的相关演替,该生态系统更适应固体干饲料。在这个重要的早期过程中,养殖条件、农场环境,特别是仔猪和母猪的抗菌药物使用决定了可能对肠道微生物群成熟产生相关影响的变化。需要更多研究来阐明这些农场诱导的仔猪早期终身变化的相对影响。
