TY - JOUR
T1 - Dissociation and re-aggregation of multicell-ensheathed fragments responsible for rapid production of massive clumps of Leptothrix sheaths
AU - Kunoh, Tatsuki
AU - Nagaoka, Noriyuki
AU - McFarlane, Ian R.
AU - Tamura, Katsunori
AU - El-Naggar, Mohamed Y.
AU - Kunoh, Hitoshi
AU - Takada, Jun
N1 - Funding Information:
We thank Keiko Toyoda for technical support and Masumi Furutani (Central Research Laboratory, Okayama University Medical School) for preparation of TEM samples. We also acknowledge Beth E. Hazen for reviewing and editing the manuscript. This study is financially supported by JST-CREST (2012-2016) (Jun Takada). Mohamed Y. El-Naggar acknowledges support from NASA through the NASA Astrobiology Institute under cooperative agreement NNA13AA92A.
Publisher Copyright:
© 2016 by the authors; licensee MDPI, Basel, Switzerland.
PY - 2016/9
Y1 - 2016/9
N2 - Species of the Fe/Mn-oxidizing bacteria Leptothrix produce tremendous amounts of microtubular, Fe/Mn-encrusted sheaths within a few days in outwells of groundwater that can rapidly clog water systems. To understand this mode of rapid sheath production and define the timescales involved, behaviors of sheath-forming Leptothrix sp. strain OUMS1 were examined using time-lapse video at the initial stage of sheath formation. OUMS1 formed clumps of tangled sheaths. Electron microscopy confirmed the presence of a thin layer of bacterial exopolymer fibrils around catenulate cells (corresponding to the immature sheath). In time-lapse videos, numerous sheath filaments that extended from the periphery of sheath clumps repeatedly fragmented at the apex of the same fragment, the fragments then aggregated and again elongated, eventually forming a large sheath clump comprising tangled sheaths within two days. In this study, we found that fast microscopic fragmentation, dissociation, re-aggregation and re-elongation events are the basis of the rapid, massive production of Leptothrix sheaths typically observed at macroscopic scales.
AB - Species of the Fe/Mn-oxidizing bacteria Leptothrix produce tremendous amounts of microtubular, Fe/Mn-encrusted sheaths within a few days in outwells of groundwater that can rapidly clog water systems. To understand this mode of rapid sheath production and define the timescales involved, behaviors of sheath-forming Leptothrix sp. strain OUMS1 were examined using time-lapse video at the initial stage of sheath formation. OUMS1 formed clumps of tangled sheaths. Electron microscopy confirmed the presence of a thin layer of bacterial exopolymer fibrils around catenulate cells (corresponding to the immature sheath). In time-lapse videos, numerous sheath filaments that extended from the periphery of sheath clumps repeatedly fragmented at the apex of the same fragment, the fragments then aggregated and again elongated, eventually forming a large sheath clump comprising tangled sheaths within two days. In this study, we found that fast microscopic fragmentation, dissociation, re-aggregation and re-elongation events are the basis of the rapid, massive production of Leptothrix sheaths typically observed at macroscopic scales.
KW - Bacterial sheath apex
KW - Leptothrix
KW - Massive sheath production
KW - Sheath clump
KW - Sheath fragmentation
KW - Time-lapse microscopy
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U2 - 10.3390/biology5030032
DO - 10.3390/biology5030032
M3 - Article
AN - SCOPUS:84988361297
SN - 2079-7737
VL - 5
JO - Biology
JF - Biology
IS - 3
M1 - 32
ER -