Abstract
Carboxysomes are an essential part of the cyanobacterial CO2-concentrating mechanism, consisting of a protein shell and an interior of Rubisco. The beta-carboxysome shell protein CcmM forms two peptides via a proposed internal ribosomal entry site (IRES) within the ccmM transcript in Synechococcus PCC7942. The abundant short form (35 kD, M35) consists of Rubisco small subunit-like repeats and binds Rubisco. The lower abundance long form (58 kD, M58) also contains a gamma-carbonic anhydrase-like domain, which binds the carboxysomal carbonic anhydrase, CcaA. We examined whether these CcmM forms arise via an IRES or by other means. Mutations of a putative internal start codon (GTG) and Shine-Dalgarno sequence within ccmM, along with a gene coding for M35 alone, were examined in the high-CO2-requiring (HCR) carboxysomeless mutant, DeltaccmM. Expression of wild-type ccmM in DeltaccmM restored the wild-type phenotype, while mutation of putative start and Shine-Dalgarno sequences led to as much as 20-fold reduction in M35 content with no recovery from HCR phenotype. These cells also contained small electron-dense structures. Cells producing little or no M58, but sufficient M35, were found to contain large electron-dense structures, no CcaA, and had a HCR phenotype. Large subcellular aggregates can therefore form in the absence of M58, suggesting a role for M35 in internal carboxysome Rubisco packing. The results confirm that M35 is independently translated via an IRES within ccmM. Importantly, the data reveal that functional carboxysomes require both M35 and M58 in sufficient quantities and with a minimum stoichiometry of close to 1:1.
Highlights
Carboxysomes are an essential part of the cyanobacterial CO2-concentrating mechanism, consisting of a protein shell and an interior of Rubisco
Mutations of a putative internal ribosomal entry site (IRES) and start codon within the Synechococcus PCC7942 ccmM gene have enabled us to determine a translational origin for the carboxysomal protein M35
Our data reveal a significant reduction in M35 production in the DccmM + gtc mutant, indicating this protein arises via a mechanism other than M58 proteolysis
Summary
Carboxysomes are an essential part of the cyanobacterial CO2-concentrating mechanism, consisting of a protein shell and an interior of Rubisco. Expression of wild-type ccmM in DccmM restored the wild-type phenotype, while mutation of putative start and ShineDalgarno sequences led to as much as 20-fold reduction in M35 content with no recovery from HCR phenotype Our work focuses on b-carboxysomes, which are present in cyanobacteria from both freshwater and marine habitats (Badger et al, 2006) This group of carboxysomes is characterized by their ccm-type shell proteins, the complement of which is currently the subject of a number of characterization studies; present indications are that b-carboxysomes could be composed of as little as six shell proteins (CcmKLMNO and CcaA) and the two Rubisco proteins (RbcLS; Kerfeld et al, 2005; Price et al, 2008; Yeates et al, 2008; Tanaka et al, 2009; Cannon et al, 2010). There is consistent evidence that CcmM exists as at least two forms in a number of b-cyanobacteria; our studies show that in Synechococcus PCC7942 these are a fulllength 58 kD form (M58) and a shorter 35 kD form (M35) that contains three SSU-like repeats (Price et al, 1998; Long et al, 2005)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
