TY - JOUR
T1 - Analysis of gut microbiota–An ever changing landscape
AU - Sadowsky, Michael J.
AU - Staley, Christopher
AU - Heiner, Cheryl
AU - Hall, Richard
AU - Kelly, Colleen R.
AU - Brandt, Lawrence
AU - Khoruts, Alexander
N1 - Publisher Copyright:
© 2017 Taylor & Francis.
PY - 2017/5/4
Y1 - 2017/5/4
N2 - In the last two decades, the field of metagenomics has greatly expanded due to improvement in sequencing technologies allowing for a more comprehensive characterization of microbial communities. The use of these technologies has led to an unprecedented understanding of human, animal, and environmental microbiomes and have shown that the gut microbiota are comparable to an organ that is intrinsically linked with a variety of diseases. Characterization of microbial communities using next-generation sequencing-by-synthesis approaches have revealed important shifts in microbiota associated with debilitating diseases such as Clostridium difficile infection. But due to limitations in sequence read length, primer biases, and the quality of databases, genus- and species-level classification have been difficult. Third-generation technologies, such as Pacific Biosciences' single molecule, real-time (SMRT) approach, allow for unbiased, more specific identification of species that are likely clinically relevant. Comparison of Illumina next-generation characterization and SMRT sequencing of samples from patients treated for C. difficile infection revealed similarities in community composition at the phylum and family levels, but SMRT sequencing further allowed for species-level characterization - permitting a better understanding of the microbial ecology of this disease. Thus, as sequencing technologies continue to advance, new species-level insights can be gained in the study of complex and clinically-relevant microbial communities.
AB - In the last two decades, the field of metagenomics has greatly expanded due to improvement in sequencing technologies allowing for a more comprehensive characterization of microbial communities. The use of these technologies has led to an unprecedented understanding of human, animal, and environmental microbiomes and have shown that the gut microbiota are comparable to an organ that is intrinsically linked with a variety of diseases. Characterization of microbial communities using next-generation sequencing-by-synthesis approaches have revealed important shifts in microbiota associated with debilitating diseases such as Clostridium difficile infection. But due to limitations in sequence read length, primer biases, and the quality of databases, genus- and species-level classification have been difficult. Third-generation technologies, such as Pacific Biosciences' single molecule, real-time (SMRT) approach, allow for unbiased, more specific identification of species that are likely clinically relevant. Comparison of Illumina next-generation characterization and SMRT sequencing of samples from patients treated for C. difficile infection revealed similarities in community composition at the phylum and family levels, but SMRT sequencing further allowed for species-level characterization - permitting a better understanding of the microbial ecology of this disease. Thus, as sequencing technologies continue to advance, new species-level insights can be gained in the study of complex and clinically-relevant microbial communities.
KW - Clostridium difficile
KW - PacBio
KW - SMRT sequencing
KW - fecal microbial transplant
KW - gut microbiota
KW - next-generation sequencing
UR - http://www.scopus.com/inward/record.url?scp=85010657841&partnerID=8YFLogxK
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U2 - 10.1080/19490976.2016.1277313
DO - 10.1080/19490976.2016.1277313
M3 - Article
C2 - 28051919
AN - SCOPUS:85010657841
SN - 1949-0976
VL - 8
SP - 268
EP - 275
JO - Gut microbes
JF - Gut microbes
IS - 3
ER -