Der1-mediated Preprotein Import into the Periplastid Compartment of Chromalveolates?

Diatoms are microalgae that possess so-called "complex plastids," which evolved by secondary endosymbiosis and are surrounded by four membranes. Thus, in contrast to primary plastids, which are surrounded by only two membranes, nucleus-encoded proteins of complex plastids face additional barriers, i.e., during evolution, mechanisms had to evolve to transport preproteins across all four membranes. This study reveals that there exist glycoproteins not only in primary but also in complex plastids, making transport issues even more complicated, as most translocation machineries are not believed to be able to transport bulky proteins. We show that plastidal reporter proteins with artificial N-glycosylation sites are indeed glycosylated during transport into the complex plastid of the diatom Phaeodactylum tricornutum. Additionally, we identified five endogenous glycoproteins, which are transported into different compartments of the complex plastid. These proteins get N-glycosylated during transport across the outermost plastid membrane and thereafter are transported across the second, third, and fourth plastid membranes in the case of stromal proteins. The results of this study provide insights into the evolutionary pressure on translocation mechanisms and pose unique questions on the operating mode of well-known transport machineries like the translocons of the outer/inner chloroplast membranes (Toc/Tic).

Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

See 1 more Smart Citation

Evidence for glycoprotein transport into complex plastids

Peschke¹,

Moog

Klingl

et al. 2013

“…This functional compatibility is also supported by 2 previous findings. The existence of an ER-associated degradation (ERAD)-like system for transporting preproteins across the second-from-theoutside of the 4 plastid-surrounding membranes in cryptophytes, heterokonts, and apicomplexans (39); and the capability of cryptophyte plastid-targeting peptide to deliver GFP into the plastids of the heterokont Phaeodactylum tricornutum (17). It appears that photosynthetic chromalveolates with secondary plastids use, at least in part, the protein-targeting signals for plastids of the red algal endosymbiont, which eventually became their own plastids.…”

Section: Functional Compatibility Of Bipartite Plastid-targeting Peptidementioning

confidence: 99%

Protein targeting into secondary plastids of chlorarachniophytes

Hirakawa

Nagamune²,

Ishida³

2009

Most plastid proteins are encoded by the nuclear genome, and consequently, need to be transported into plastids across multiple envelope membranes. In diverse organisms possessing secondary plastids, nuclear-encoded plastid precursor proteins (preproteins) commonly have an N-terminal extension that consists of an endoplasmic reticulum (ER)-targeting signal peptide and a transit peptide-like sequence (TPL). This bipartite targeting peptide is believed to be necessary for targeting the preproteins into the secondary plastids. Here, we newly demonstrate the function of the bipartite targeting peptides of an algal group, chlorarachniophytes, and characterize the functional domains of the TPL in the precursor of a plastid protein, ATP synthase delta subunit (AtpD), using a GFP as a reporter molecule. We show that the C-terminal portion of the TPL is important for targeting the AtpD preprotein from the ER into the chlorarachniophyte plastids, and several positively charged amino acids in the TPL are also necessary for transporting the preprotein across the 2 innermost plastid membranes. Compared with other groups with secondary plastids, the TPL functional domains of the chlorarachniophytes are unique, which might be caused by independent acquisition of their plastids.ATP synthase delta subunit ͉ secondary endosymbiosis ͉ transit peptides ͉ bipartite targeting peptide ͉ periplastidal compartment

“…What about the remaining membrane? Maier and colleagues have shown that translocation across the second outermost membrane (originally the plasma membrane of the algal endosymbiont) in red-type four-membrane plastids is mediated by a multiprotein complex dubbed SELMA [symbiont-specific endoplasmic reticulum (ER)-associated degradation-like machinery (68)(69)(70)(71)]. The evolution of SELMA appears to represent a singularity, an intricate complex cobbled together from a dozen or more proteins at least some of which originally functioned as part of the ER-associated degradation machinery in the red algal endosymbiont.…”

Section: Evolving a Complex Algamentioning

confidence: 99%

Genomic perspectives on the birth and spread of plastids

Archibald

2015

130

113

The endosymbiotic origin of plastids from cyanobacteria was a landmark event in the history of eukaryotic life. Subsequent to the evolution of primary plastids, photosynthesis spread from red and green algae to unrelated eukaryotes by secondary and tertiary endosymbiosis. Although the movement of cyanobacterial genes from endosymbiont to host is well studied, less is known about the migration of eukaryotic genes from one nucleus to the other in the context of serial endosymbiosis. Here I explore the magnitude and potential impact of nucleus-to-nucleus endosymbiotic gene transfer in the evolution of complex algae, and the extent to which such transfers compromise our ability to infer the deep structure of the eukaryotic tree of life. In addition to endosymbiotic gene transfer, horizontal gene transfer events occurring before, during, and after endosymbioses further confound our efforts to reconstruct the ancient mergers that forged multiple lines of photosynthetic microbial eukaryotes.