Richard Nyamota, Earl A Middlebrook, Hussein M Abkallo, James Akoko, Francis Gakuya, Lillian Wambua, Bernard Ronoh, Isaac Lekolool, Athman Mwatondo, Mathew Muturi, Bernard Bett, Jeanne M Fair, Andrew W Bartlow
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This study investigated the blood microbiome of clinically healthy wild buffaloes in Kenya to determine its applicability in agnostic testing for bacteria in apparently healthy wild animals.</p><p><strong>Methods: </strong>Whole blood and serum samples were collected from 46 wild African buffalos from Meru National Park (30), Buffalo Springs (6) and Shaba (10) National Reserves in upper eastern Kenya. Total deoxyribonucleic acid (DNA) was extracted from these samples and subjected to amplicon-based sequencing targeting the 16 S rRNA gene. The bacteria operational taxonomic units (OTU) were identified to species levels by mapping the generated V12 and V45 regions of 16 S rRNA gene to the SILVA database. These OTU tables were used to infer the microbial abundance in each sample type and at the individual animal level. The sequences for the corresponding OTUs were also used to generate phylogenetic trees and thus infer evolution for the OTUs of interest.</p><p><strong>Results: </strong>Here, we demonstrate that buffaloes harbor many bacteria in their blood. We also report a diversity of 16 S rRNA gene sequences for Anaplasma and Mycoplasma from individual animals. By sequencing both whole blood and serum in triplicate for each animal, we provide evidence of the differences in detecting bacteria in both sample types.</p><p><strong>Conclusions: </strong>Diverse bacteria, including some potential pathogens, can be found in the blood of clinically healthy wild African buffalo. Agnostic surveillance for such pathogens can be achieved through blood microbiome sequencing. 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引用次数: 0
摘要
背景:非洲水牛(Syncerus caffer)是非洲许多人畜共患病和寄生虫感染的重要宿主。其中包括一系列病毒和致病细菌,如蜱传立克次体。尽管考虑到哺乳动物的血液是无菌环境,但血液微生物组测序可能成为不可知论生物监测的关键。本研究调查了肯尼亚临床健康野生水牛的血液微生物组,以确定其是否适用于对表面健康的野生动物进行不可知细菌检测:方法:从肯尼亚上东部梅鲁国家公园(30 头)、水牛泉国家保护区(6 头)和沙巴国家保护区(10 头)的 46 头非洲野生水牛身上采集了全血和血清样本。从这些样本中提取了总脱氧核糖核酸(DNA),并以 16 S rRNA 基因为目标进行了基于扩增子的测序。通过将生成的 16 S rRNA 基因的 V12 和 V45 区域映射到 SILVA 数据库,确定了细菌的操作分类单元(OTU)到物种水平。这些 OTU 表用于推断每种样本类型和动物个体中微生物的丰度。相应 OTU 的序列也用于生成系统发生树,从而推断相关 OTU 的进化情况:结果:我们在此证明,水牛的血液中含有多种细菌。结果:我们在这里证明了水牛的血液中存在许多细菌。我们还报告了来自个体动物的阿纳普拉斯ma 和支原体的 16 S rRNA 基因序列的多样性。通过对每只动物的全血和血清进行一式三份的测序,我们提供了在两种样本类型中检测细菌差异的证据:结论:在临床健康的非洲野生水牛血液中可发现多种细菌,包括一些潜在的病原体。通过血液微生物组测序可以对这些病原体进行不可知的监测。不过,对野生动物血液微生物组问题的考虑将影响到使用全血还是血清进行测序的选择。
The Bacterial and pathogenic landscape of African buffalo (Syncerus caffer) whole blood and serum from Kenya.
Background: African buffalo (Syncerus caffer) is a significant reservoir host for many zoonotic and parasitic infections in Africa. These include a range of viruses and pathogenic bacteria, such as tick-borne rickettsial organisms. Despite the considerations of mammalian blood as a sterile environment, blood microbiome sequencing could become crucial for agnostic biosurveillance. This study investigated the blood microbiome of clinically healthy wild buffaloes in Kenya to determine its applicability in agnostic testing for bacteria in apparently healthy wild animals.
Methods: Whole blood and serum samples were collected from 46 wild African buffalos from Meru National Park (30), Buffalo Springs (6) and Shaba (10) National Reserves in upper eastern Kenya. Total deoxyribonucleic acid (DNA) was extracted from these samples and subjected to amplicon-based sequencing targeting the 16 S rRNA gene. The bacteria operational taxonomic units (OTU) were identified to species levels by mapping the generated V12 and V45 regions of 16 S rRNA gene to the SILVA database. These OTU tables were used to infer the microbial abundance in each sample type and at the individual animal level. The sequences for the corresponding OTUs were also used to generate phylogenetic trees and thus infer evolution for the OTUs of interest.
Results: Here, we demonstrate that buffaloes harbor many bacteria in their blood. We also report a diversity of 16 S rRNA gene sequences for Anaplasma and Mycoplasma from individual animals. By sequencing both whole blood and serum in triplicate for each animal, we provide evidence of the differences in detecting bacteria in both sample types.
Conclusions: Diverse bacteria, including some potential pathogens, can be found in the blood of clinically healthy wild African buffalo. Agnostic surveillance for such pathogens can be achieved through blood microbiome sequencing. However, considerations for the question being asked for the blood microbiome in wildlife will impact the choice for using whole blood or serum for sequencing.
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