EMD-35617
Cryo-EM structure of cyanobacteria phosphoketolase in dodecameric assembly
EMD-35617
Single-particle2.86 Å
Deposition: 11/03/2023Map released: 28/06/2023
Last modified: 15/11/2023
Sample Organism:
Synechococcus,
Synechococcus elongatus (strain ATCC 33912 / PCC 7942 / FACHB-805)
Sample: Cyanobacteria XPK complexed with TPP/Mg2+
Fitted models: 8ioe (Avg. Q-score: 0.486)
Deposition Authors: Chang C-W
,
Tsai M-D
Sample: Cyanobacteria XPK complexed with TPP/Mg2+
Fitted models: 8ioe (Avg. Q-score: 0.486)
Deposition Authors: Chang C-W
,
Tsai M-D
An ATP-sensitive phosphoketolase regulates carbon fixation in cyanobacteria.
Lu KJ ,
Chang CW ,
Wang CH ,
Chen FY ,
Huang IY ,
Huang PH,
Yang CH ,
Wu HY,
Wu WJ ,
Hsu KC ,
Ho MC ,
Tsai MD ,
Liao JC
(2023) Nat Metab , 5 , 1111 - 1126
,
Chang CW ,
Wang CH ,
Chen FY ,
Huang IY ,
Huang PH,
Yang CH ,
Wu HY,
Wu WJ ,
Hsu KC ,
Ho MC ,
Tsai MD ,
Liao JC
(2023) Nat Metab , 5 , 1111 - 1126
Abstract:
Regulation of CO2 fixation in cyanobacteria is important both for the organism and global carbon balance. Here we show that phosphoketolase in Synechococcus elongatus PCC7942 (SeXPK) possesses a distinct ATP-sensing mechanism, where a drop in ATP level allows SeXPK to divert precursors of the RuBisCO substrate away from the Calvin-Benson-Bassham cycle. Deleting the SeXPK gene increased CO2 fixation particularly during light-dark transitions. In high-density cultures, the Δxpk strain showed a 60% increase in carbon fixation and unexpectedly resulted in sucrose secretion without any pathway engineering. Using cryo-EM analysis, we discovered that these functions were enabled by a unique allosteric regulatory site involving two subunits jointly binding two ATP, which constantly suppresses the activity of SeXPK until the ATP level drops. This magnesium-independent ATP allosteric site is present in many species across all three domains of life, where it may also play important regulatory functions.
Regulation of CO2 fixation in cyanobacteria is important both for the organism and global carbon balance. Here we show that phosphoketolase in Synechococcus elongatus PCC7942 (SeXPK) possesses a distinct ATP-sensing mechanism, where a drop in ATP level allows SeXPK to divert precursors of the RuBisCO substrate away from the Calvin-Benson-Bassham cycle. Deleting the SeXPK gene increased CO2 fixation particularly during light-dark transitions. In high-density cultures, the Δxpk strain showed a 60% increase in carbon fixation and unexpectedly resulted in sucrose secretion without any pathway engineering. Using cryo-EM analysis, we discovered that these functions were enabled by a unique allosteric regulatory site involving two subunits jointly binding two ATP, which constantly suppresses the activity of SeXPK until the ATP level drops. This magnesium-independent ATP allosteric site is present in many species across all three domains of life, where it may also play important regulatory functions.