Database of articles cited by EMDB/PDB/SASBDB data

Keywords
Structure methods	All X-ray diffraction NMR electron microscopy small angle scattering neutron diffraction fiber diffraction powder diffraction infrared spectroscopy EPR fluorescence transfer theoretical model Hybrid
Author
Journal
IF	>30 >20 >10 >5 all

Title	Morphological Plasticity in a Sulfur-Oxidizing Marine Bacterium from the SUP05 Clade Enhances Dark Carbon Fixation.
Journal, issue, pages	mBio, Vol. 10, Issue 3, Year 2019
Publish date	May 7, 2019
Authors	Vega Shah / Xiaowei Zhao / Rachel A Lundeen / Anitra E Ingalls / Daniela Nicastro / Robert M Morris /
PubMed Abstract	Sulfur-oxidizing bacteria from the SUP05 clade are abundant in anoxic and oxygenated marine waters that appear to lack reduced sources of sulfur for cell growth. This raises questions about how these ...Sulfur-oxidizing bacteria from the SUP05 clade are abundant in anoxic and oxygenated marine waters that appear to lack reduced sources of sulfur for cell growth. This raises questions about how these chemosynthetic bacteria survive across oxygen and sulfur gradients and how their mode of survival impacts the environment. Here, we use growth experiments, proteomics, and cryo-electron tomography to show that a SUP05 isolate, " Thioglobus autotrophicus," is amorphous in shape and several times larger and stores considerably more intracellular sulfur when it respires oxygen. We also show that these cells can use diverse sources of reduced organic and inorganic sulfur at submicromolar concentrations. Enhanced cell size, carbon content, and metabolic activity of the aerobic phenotype are likely facilitated by a stabilizing surface-layer (S-layer) and an uncharacterized form of FtsZ-less cell division that supports morphological plasticity. The additional sulfur storage provides an energy source that allows cells to continue metabolic activity when exogenous sulfur sources are not available. This metabolic flexibility leads to the production of more organic carbon in the ocean than is estimated based solely on their anaerobic phenotype. Identifying shifts in microbial metabolism across redox gradients will improve efforts to model marine oxygen minimum zone (OMZ) ecosystems. Here, we show that aerobic morphology and metabolism increase cell size, sulfur storage capacity, and carbon fixation rates in " Thioglobus autotrophicus," a chemosynthetic bacterium from the SUP05 clade that crosses oxic-anoxic boundaries.
External links	mBio / PubMed:31064824 / PubMed Central
Methods	EM (tomography) / EM (subtomogram averaging)
Resolution	35.0 Å
Structure data	EMDB-0507: cryo-electron tomography of marine bacteria T. autotrophicus, EF1 strain, cultured under anaerobic, repleted with sulfur source. Method: EM (tomography) EMDB-0508: Cryo-electron tomography of marine bacteria T. autotrophicus EF1 strain, which is cultured under anaerobic, depleted sulfur source conditions Method: EM (tomography) EMDB-0509: Cryo-electron tomography of marine bacterium T. autotrophicus EF1 strain, cultured under aerobic, depleted sulfur source condition Method: EM (tomography) EMDB-0511: Cryo-electron tomography of marine bacterium T. autotrophicus, EF1 strain, cultured under aerobic condition, repleted with sulfur source. Method: EM (tomography) EMDB-0512: Cryo-electron tomography of marine bacterium T. autotrophicus EF1 strain reveals an S_layer pattern on outer membrane. Method: EM (tomography) EMDB-0513: Subtomogram average of S_layer structure on the outer membrane surface of Thioglobus autotrophicus EF1 cell Method: EM (subtomogram averaging) / Resolution: 35.0 Å
Source	Candidatus Thioglobus (bacteria) Thioglobus (bacteria) Candidatus Thioglobus autotrophicus (bacteria)