Abstract
Phormidium lacuna is a naturally competent, filamentous cyanobacterium that belongs to the order Oscillatoriales. The filaments are motile on agar and other surfaces and display rapid lateral movements in liquid culture. Furthermore, they exhibit a photophobotactic response, a phototactic response towards light that is projected vertically onto the area covered by the culture. However, the molecular mechanisms underlying these phenomena are unclear. We performed the first molecular studies on the motility of an Oscillatoriales member. We generated mutants in which a kanamycin resistance cassette (KanR) was integrated in the phytochrome gene cphA and in various genes of the type IV pilin apparatus. pilM, pilN, pilQ and pilT mutants were defective in gliding motility, lateral movements and photophobotaxis, indicating that type IV pili are involved in all three kinds of motility. pilB mutants were only partially blocked in terms of their responses. pilB is the proposed ATPase for expelling of the filament in type IV pili. The genome reveals proteins sharing weak pilB homology in the ATPase region, these might explain the incomplete phenotype. The cphA mutant revealed a significantly reduced photophobotactic response towards red light. Therefore, our results imply that CphA acts as one of several photophobotaxis photoreceptors or that it could modulate the photophobotaxis response.
Highlights
Around 3.0 billion years ago, cyanobacteria evolved the ability to perform oxygenic photosynthesis [1]
Type IV pili are involved in gliding motility of many bacteria including single celled cyanobacteria and members of the Nostocales
To see how type IV pili are involved in a member of Oscillatoriales, we aimed at disrupting genes of PilA1, PilB, PilD, PilM, PilN, PilQ and PilT in the genome of Phormidium lacuna
Summary
Around 3.0 billion years ago, cyanobacteria evolved the ability to perform oxygenic photosynthesis [1]. This invention caused a rise in atmospheric oxygen that changed the diversity and complexity of species on earth dramatically. The plastids of all eukaryotic photosynthetic organisms are descendants of a cyanobacterial endosymbiont [2, 3]. Four kinds of cellular organizations are recognized in cyanobacteria, namely single celled species, linear filaments, linear filaments with heterocysts and branched filaments. Single celled and filamentous cyanobacteria can move across surfaces using a gliding mechanism [4–.
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