Abstract
The use of gnotobiotics has gained large interest in recent years due to technological advances that have revealed the importance of host-associated microbiomes for host physiology and health. One of the oldest and most important gnotobiotics mouse model, the Altered Schaedler Flora (ASF) has been used for several decades. ASF comprises eight different bacterial species, which have been characterized to different extent, but only few are available through public strain collections. Here, the isolation of a close relative to one of the less studied ASF strains, Clostridium sp. ASF 502, is reported. Isolate TLL-A1, which shares 99.6% 16S rRNA gene sequence identity with Clostridium sp. ASF 502, was obtained from feces of C57BL/6J mice where is was detectable at a relative abundance of less than one percent. D-arabinose was used as sole carbon source in the anaerobic cultivation medium. Growth experiments with TLL-A1 on different carbon sources and analysis of its ~6.5 gigabase genome indicate that TLL-A1 harbors a large gene repertoire to utilize different carbohydrates for growth. Comparative genome analyses of TLL-A1 and Clostridium sp. ASF 502 reveal differences in genome content between the two strains, in particular with regards to carbohydrate activating enzymes. Based on physiology and genomic analysis it is proposed to name TLL-A1 to gen. nov. sp. nov Schaedlerella arabinophila TLL-A1 (DSMZ 106076T; KCTC 15657T). The closely related Clostridium sp. ASF 502 is proposed to be renamed to Schaedlerella arabinophila to reflect its taxonomic standing and to keep ‘ASF 502’ as strain designation.
Importance The Altered Schaedler Flora (ASF) remains an important tool to mechanistically investigate host-microbe interactions in the mammalian alimentary tract. Extensively characterizing the eight different bacterial strains, which are constituting ASF, has the potential to further increase the definition of this widely used model microbial community and to enhance our understanding of how individual microorganism interact with a host and/or how they may affect its physiology. However, some of the ASF strains have unfortunately been lost or are not easily accessible to the scientific community. The isolation and characterization of the here described species, proposed to be named Schaedlerella arabinophila, which is closely related to Clostridium species ASF502, may therefore be an important corner stone in further improving the value of studies using ASF or other defined synthetic microbial communities that require usage of autochthonous microorganisms in gnotobiotic mice.