Single-Organelle Quantification Reveals Stoichiometric and Structural Variability of Carboxysomes Dependent on the Environment

Sun, Yaqi; Wollman, Adam J. M.; Huang, Fang; Leake, Mark C.; Liu, Luning

doi:10.1105/tpc.18.00787

Cited by 91 publications

(100 citation statements)

References 99 publications

(167 reference statements)

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“…In quantifications of protein abundance in cyanobacteria, a shortfall of RbcS relative to RbcL has been reported (Long et al, 2007(Long et al, , 2011Sun et al, 2019). This finding suggests that isoforms other than the L 8 S 8 rubisco holoenzyme may be present in vivo, although further substantiating analyses and investigations across multiple species as well as conditions are needed.…”

Section: Discussionmentioning

confidence: 99%

Binding Options for the Small Subunit-Like Domain of Cyanobacteria to Rubisco

2020

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Citation:Rohnke BA, Kerfeld CA and Montgomery BL (2020) Binding Options for the Small Subunit-Like Domain of Cyanobacteria to Rubisco.Two proteins found in cyanobacteria contain a C-terminal domain with homology to the small subunit of rubisco (RbcS). These small subunit-like domains (SSLDs) are important features of CcmM, a protein involved in the biogenesis of carboxysomes found in all β-cyanobacteria, and a rubisco activase homolog [activase-like protein of cyanobacteria (ALC)] found in over a third of sequenced cyanobacterial genomes. Interaction with rubisco is crucial to the function of CcmM and is believed to be important to ALC as well. In both cases, the SSLD aggregates rubisco, and this nucleation event may be important in regulating rubisco assembly and activity. Recently, two independent studies supported the conclusion that the SSLD of CcmM binds equatorially to L 8 S 8 holoenzymes of rubisco rather than by displacing an RbcS, as its structural homology would suggest. We use sequence analysis and homology modeling to examine whether the SSLD from the ALC could bind the large subunit of rubisco either via an equatorial interaction or in an RbcS site, if available. We suggest that the SSLD from the ALC of Fremyella diplosiphon could bind either in a vacant RbcS site or equatorially. Our homology modeling takes into account N-terminal residues not represented in available cryo-electron microscopy structures that potentially contribute to the interface between the large subunit of rubisco (RbcL) and RbcS. Here, we suggest the perspective that binding site variability as a means of regulation is plausible and that the dynamic interaction between the RbcL, RbcS, and SSLDs may be important for carboxysome assembly and function.

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Section: Discussionmentioning

confidence: 99%

Binding Options for the Small Subunit-Like Domain of Cyanobacteria to Rubisco

2020

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“…Therefore, it will be interesting to compare the ATPase activities of the two McdA types, as well as the stimulatory activities of their respective McdB proteins. How Type 1 and Type 2 systems differ mechanistically, and whether these differences correlate to known factors influencing carboxysome positioning such as carboxysome size and quantity (Gonzalez-Esquer et al, 2016; MacCready et al, 2018) , genome copy number and volume (Griese et al, 2011) , redox state of cells (Sun et al, 2016, 2019) , and McdAB stoichiometry (MacCready et al, 2018) , as well as unknown factors including McdB LLPS behavior and/or intracellular salt/pH conditions (see below), is important for understanding the diversity and evolution of the McdAB system among cyanobacteria.…”

Section: Discussionmentioning

confidence: 99%

“…Since O 2 competes with CO 2 as a substrate for ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBisCO), the encapsulation of RuBisCO and carbonic anhydrase within a selectively permeable protein shell (the carboxysome) is necessary for generating the high CO 2 environment needed to drive internal RuBisCO reactions towards the Calvin-Benson-Bassham cycle (CO 2 substrate) and away from the wasteful process of photorespiration (O 2 substrate) (Figure 1AB) (Reviewed in: Kerfeld et al, 2018) . Comprised of thousands of proteins (Sun et al, 2019) , carboxysomes were once thought to be completely paracrystalline (Kaneko et al, 2006) . However, recent reports have challenged this idea by showing that carboxysome formation involves the process of Liquid-Liquid Phase Separation (LLPS) (Wang et al, 2019; Oltrogge et al, 2019) ; a process that describes the ability of proteins to spontaneously demix into dilute and dense phases that resemble liquid droplets (Reviewed in: Alberti et al, 2019) .…”

Section: Introductionmentioning

confidence: 99%

The McdAB Carboxysome Positioning System is Widespread Among β-cyanobacteria

MacCready

Basalla

Vecchiarelli

2019

Preprint

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SummaryCarboxysomes are protein-based organelles that are essential for allowing cyanobacteria to fix CO2. Previously we identified a two-component system, McdAB, responsible for equidistantly positioning carboxysomes in the model cyanobacterium Synechococcus elongatus PCC 7942. McdA, a ParA-type ATPase, non-specifically binds the nucleoid in the presence of ATP. McdB, a novel factor that directly binds carboxysomes, displaces McdA from the nucleoid. Removal of McdA from the nucleoid in the vicinity of carboxysomes by McdB causes a global break in McdA symmetry, and carboxysome motion occurs via a Brownian-ratchet based mechanism towards the highest concentration of McdA. Despite the importance for cyanobacteria to properly position their carboxysomes, whether the McdAB system is widespread among cyanobacteria remains an open question. Here, we used neighborhood analysis to show that the McdAB system is widespread among β-cyanobacteria and often clusters near carboxysome-related components. Moreover, we show that two distinct McdAB systems exist in β-cyanobacteria, with Type 2 systems being the most abundant (>98% of β-cyanobacteria) and Type 1 systems, like that of S. elongatus, possibly being acquired more recently. Surprisingly, our analysis suggests that the McdAB system is completely absent in α-cyanobacteria. Lastly, all McdB proteins we identified share the sequence signatures of a protein capable of undergoing Liquid-Liquid Phase Separation (LLPS). Indeed, we find that S. elongatus McdB undergoes LLPS in vitro, the first example of a ParA-type ATPase partner protein exhibiting this behavior. This is an intriguing finding given the recent demonstration of LLPS activity by β-carboxysome core components. Our results have broader implications for understanding carboxysome biogenesis and positioning across all β-cyanobacteria.In BriefWe found that the McdAB carboxysome positioning system is widespread among β-cyanobacteria, absent in α-cyanobacteria, exists in two distinct forms, and that S. elongatus McdB undergoes liquid-liquid phase separation.

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“…As photobleaching of mGFP proceeded during Slimfield excitation distinct fluorescent foci could be observed of half width at half maximum 250-300 nm, consistent with the diffraction-limited point spread function of our microscope system, which were tracked and characterized in terms of their stoichiometry and apparent microscopic diffusion coefficient. Distinct fluorescent foci that were detected within the microscope's depth of field could be tracked for up to several hundred ms, to a super-resolved lateral precision ~40 nm 35 using a bespoke single particle tracking software written in MATLAB (MATHWORKS) and adapted from similar live cell single-molecule studies 10,[35][36][37] .…”

Section: Single-molecule Slimfield Microscopymentioning

confidence: 99%

Correlating single-molecule characteristics of the yeast aquaglyceroporin Fps1 with environmental perturbations directly in living cells

Shashkova

Andersson

Hohmann

et al. 2020

Preprint

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Membrane proteins play key roles at the interface between the cell and its environment by mediating selective import and export of molecules via plasma membrane channels. Despite a multitude of studies on transmembrane channels, understanding of their dynamics directly within living systems is limited. To address this, we correlated molecular scale information from living cells with real time changes to their microenvironment. We employed super-resolved millisecond fluorescence microscopy with a single-molecule sensitivity, to track labelled molecules of interest in real time. We use as example the aquaglyceroporin Fps1 in the yeast Saccharomyces cerevisiae to dissect and correlate its stoichiometry and molecular turnover kinetics with various extracellular conditions. In this way we shed new light on aspects of architecture and dynamics of glycerolpermeable plasma membrane channels.

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Single-Organelle Quantification Reveals Stoichiometric and Structural Variability of Carboxysomes Dependent on the Environment

Cited by 91 publications

References 99 publications

Binding Options for the Small Subunit-Like Domain of Cyanobacteria to Rubisco

Binding Options for the Small Subunit-Like Domain of Cyanobacteria to Rubisco

The McdAB Carboxysome Positioning System is Widespread Among β-cyanobacteria

Correlating single-molecule characteristics of the yeast aquaglyceroporin Fps1 with environmental perturbations directly in living cells

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