Biased inheritance of the protein PatN frees vegetative cells to initiate patterned heterocyst differentiation

Abstract: Heterocysts, cells specialized for nitrogen fixation in certain filamentous cyanobacteria, appear singly in a nonrandom spacing pattern along the chain of vegetative cells. A two-stage, biased initiation and competitive resolution model has been proposed to explain the establishment of this spacing pattern. There is substantial evidence that competitive resolution of a subset of cells initiating differentiation occurs by interactions between a selfenhancing activator protein, HetR, and a diffusible pentapeptid… Show more

“…However, can any cell in a filament differentiate into a heterocyst? In PNAS, Risser et al (5) present evidence consistent with the idea that, at a given time, only some cells in the filament have the capability to differentiate.…”

“…In the patN mutant, vegetative cell intervals between heterocysts are shorter than in the wild type, but the distribution of heterocysts in the filaments is still nonrandom. Thus, the PatS-and HetNdependent lateral inhibition seems to operate in the patN mutant, and inhibition of differentiation by PatS has indeed been corroborated (5). Analyzing the fluorescence from a PatN-GFP fusion protein, Risser et al observe the protein in the periphery of the cell, consistent with a cytoplasmic membrane location, but with an uneven distribution between cells.…”

“…By performing genetic analysis, Risser et al (5) A two-stage model of heterocyst differentiation involving biased initiation followed by competitive resolution has been previously proposed (3). Whereas experimental support for competitive resolution of cells simultaneously starting differentiation was available (10-13), Risser et al (5) now identify a factor putatively influencing biased initiation of heterocyst differentiation. Genes encoding homologues to PatN are present in all heterocystforming cyanobacteria for which the complete genomic sequence is available, indicating that PatN may generally participate in heterocyst differentiation.…”

“…Mutants of this gene form heterocysts preferentially at the filaments termini (16), and PatA is postulated to counteract the negative effects of PatSand HetN-related regulators on heterocyst differentiation (2,4). By performing genetic analysis, Risser et al (5) A two-stage model of heterocyst differentiation involving biased initiation followed by competitive resolution has been previously proposed (3). Whereas experimental support for competitive resolution of cells simultaneously starting differentiation was available (10-13), Risser et al (5) now identify a factor putatively influencing biased initiation of heterocyst differentiation.…”

“…Second, how does PatN impede cell differentiation? First, analyzing a transcriptional fusion of the gfp gene to the patN gene promoter, Risser et al (5) show that the expression of patN takes place in all cells of the filament when they grow in the presence of ammonium, as well as after nitrogen deprivation. This implies that the uneven distribution of PatN in the filaments results from posttranslational regulation rather than from differential gene expression.…”

Restricted cellular differentiation in cyanobacterial filaments

“…However, can any cell in a filament differentiate into a heterocyst? In PNAS, Risser et al (5) present evidence consistent with the idea that, at a given time, only some cells in the filament have the capability to differentiate.…”

“…In the patN mutant, vegetative cell intervals between heterocysts are shorter than in the wild type, but the distribution of heterocysts in the filaments is still nonrandom. Thus, the PatS-and HetNdependent lateral inhibition seems to operate in the patN mutant, and inhibition of differentiation by PatS has indeed been corroborated (5). Analyzing the fluorescence from a PatN-GFP fusion protein, Risser et al observe the protein in the periphery of the cell, consistent with a cytoplasmic membrane location, but with an uneven distribution between cells.…”

“…By performing genetic analysis, Risser et al (5) A two-stage model of heterocyst differentiation involving biased initiation followed by competitive resolution has been previously proposed (3). Whereas experimental support for competitive resolution of cells simultaneously starting differentiation was available (10-13), Risser et al (5) now identify a factor putatively influencing biased initiation of heterocyst differentiation. Genes encoding homologues to PatN are present in all heterocystforming cyanobacteria for which the complete genomic sequence is available, indicating that PatN may generally participate in heterocyst differentiation.…”

“…Mutants of this gene form heterocysts preferentially at the filaments termini (16), and PatA is postulated to counteract the negative effects of PatSand HetN-related regulators on heterocyst differentiation (2,4). By performing genetic analysis, Risser et al (5) A two-stage model of heterocyst differentiation involving biased initiation followed by competitive resolution has been previously proposed (3). Whereas experimental support for competitive resolution of cells simultaneously starting differentiation was available (10-13), Risser et al (5) now identify a factor putatively influencing biased initiation of heterocyst differentiation.…”

“…Second, how does PatN impede cell differentiation? First, analyzing a transcriptional fusion of the gfp gene to the patN gene promoter, Risser et al (5) show that the expression of patN takes place in all cells of the filament when they grow in the presence of ammonium, as well as after nitrogen deprivation. This implies that the uneven distribution of PatN in the filaments results from posttranslational regulation rather than from differential gene expression.…”

Restricted cellular differentiation in cyanobacterial filaments

Processing of PatS, a morphogen precursor, in cell extracts of Anabaena sp. PCC 7120

Increased heterocyst frequency by patN disruption in Anabaena leads to enhanced photobiological hydrogen production at high light intensity and high cell density