Results 221 to 230 of about 97,526 (278)
Case Report: Minigene assays reveal a novel <i>DNAAF6</i> intronic variant as the key etiology for primary ciliary dyskinesia. [PDF]
Front GenetLong Y +11 more
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Insights into the structure and initial host attachment of the flagellotropic bacteriophage 7-7-1. [PDF]
Commun BiolNoteborn WEM +7 more
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Battle beyond membrane: flagella as a conduit for phage DNA entry and a trigger for bacterial defense in Yersinia enterocolitica. [PDF]
Nucleic Acids ResWang Z +7 more
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Role of FlhF and its domains in the assembly of a polar flagellum in <i>P. aeruginosa</i>. [PDF]
J BacteriolRaghav S, Prajapati R, Jain D.
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Proceedings, annual meeting, Electron Microscopy Society of America, 1971
Movement of bacterial cells is accomplished through the action of flagella, organelles consisting of three morphologically distinct portions, a spiral tubular filament [(f)n] which constitutes over 90% of the organelle, an extracellular hook, and a basal structure, which is intimately associated with the cell surface.
R W, Smith, H, Koffler
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Movement of bacterial cells is accomplished through the action of flagella, organelles consisting of three morphologically distinct portions, a spiral tubular filament [(f)n] which constitutes over 90% of the organelle, an extracellular hook, and a basal structure, which is intimately associated with the cell surface.
R W, Smith, H, Koffler
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Annual Review of Microbiology, 1977
Flagella are responsible for bacterial motility and chemotaxis. They are subcellular organdies that originate in the membrane of the cell and extend 15-20 µm from the cell surface. The bacterial flagellar system has been studied from a variety of points of view, including as a model for the regulation of organelle formation and morphogenesis, as a ...
Silverman, Michael, Simon, Melvin I.
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Flagella are responsible for bacterial motility and chemotaxis. They are subcellular organdies that originate in the membrane of the cell and extend 15-20 µm from the cell surface. The bacterial flagellar system has been studied from a variety of points of view, including as a model for the regulation of organelle formation and morphogenesis, as a ...
Silverman, Michael, Simon, Melvin I.
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Bacterial lateral flagella: an inducible flagella system
FEMS Microbiology Letters, 2006Flagella are complex surface organelles that allow bacteria to move towards favourable environments and that contribute to the virulence of pathogenic bacteria through adhesion and biofilm formation on host surfaces. There are a few bacteria that possess functional dual flagella systems, such as Vibrio parahaemolyticus, some mesophilic Aeromonas spp ...
Susana, Merino +2 more
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Current Opinion in Microbiology, 2006
Flagellar gene networks are fascinating, owing to their complexity - they usually coordinate the expression of more than 40 genes - and particular wiring that elicits temporal expression coupled to organelle morphogenesis. Moreover, many of the lessons learned from flagellar regulation are generally applicable to type III secretion systems.
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Flagellar gene networks are fascinating, owing to their complexity - they usually coordinate the expression of more than 40 genes - and particular wiring that elicits temporal expression coupled to organelle morphogenesis. Moreover, many of the lessons learned from flagellar regulation are generally applicable to type III secretion systems.
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The Quarterly Review of Biology, 1980
Most bacterial movement is the result of the action of a subcellular structure, the flagellar organelle. Bacterial flagella propel the cell by rotating, and this rotation is regulated in response to information transmitted by chemoreceptors on the surface of the cell. Rotation is driven by a motor anchored in the cell membrane.
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Most bacterial movement is the result of the action of a subcellular structure, the flagellar organelle. Bacterial flagella propel the cell by rotating, and this rotation is regulated in response to information transmitted by chemoreceptors on the surface of the cell. Rotation is driven by a motor anchored in the cell membrane.
openaire +2 more sources