The cyanelles of glaucocystophytes are probably the most primitive of known extant plastids and the closest to cyanobacteria. Their kidney shape and FtsZ arc during the early stage of division define cyanelle division. In order to deepen and expand earlier results (Planta 227:177-187, 2007), cells of Cyanophora paradoxa were fixed with two different chemical and two different freeze-fixation methods. In addition, cyanelles from C. paradoxa were isolated to observe the surface structure of dividing cyanelles using field emission scanning electron microscopy (FE-SEM). A shallow furrow started on one side of the division plane. The furrow subsequently extended, covering the entire division circle, and then invaginated deeply, becoming clearly visible. The typical FtsZ arc was 2.3-3.4 microm long. This length matches that of the cleavage furrow observed using FE-SEM. The cyanelle cleavage furrows are from one-fourth to one-half of the circumference of the division plane. The shallow furrow that appears on the cyanelle outer surface effectively changes the division plane. Using freeze-fixation methods, the electron-dense stroma and peptidoglycan could be distinguished. In addition, an electron-dense belt structure (the cyanelle ring) was observed inside the leading edge at the cyanelle division plane. The FtsZ arc is located at the division plane ahead of the cyanelle ring. Immunogold-TEM localization shows that FtsZ is located interiorly of the cyanelle ring. The lack of an outer PD ring, together with the arch-shaped furrow, suggests that the mechanical force of the initial (arch shaped) septum furrow constriction comes from inside the cyanelle.
Non-flagellated vegetative green algae of the Trebouxiophyceae propagate mainly by autosporulation. In this manner, the mother cell wall is shed following division of the protoplast in each round of cell division. Binary fission type Nannochloris and budding type Marvania are also included in the Trebouxiophyceae. Phylogenetic trees based on the actin sequences of Trebouxiophyceae members revealed that the binary fission type Nannochloris bacillaris and the budding type Marvania geminata are closely related in a distal monophyletic group. Our results suggest that autosporulation is the ancestral mode of cell division in Trebouxiophyceae. To elucidate how non-autosporulative mechanisms such as binary fission and budding evolved, we focused on the cleavage of the mother cell wall. Cell wall development was analyzed using a cell wall-specific fluorescent dye, Fluostain I. Exfoliation of the mother cell wall was not observed in either N. bacillaris or M. geminata. We then compared the two algae by transmission electron microscopy with rapid freeze fixation and freeze substitution; in both algae, the mother cell wall was cleaved at the site of cell division, but remained adhered to the daughter cell wall. In N. bacillaris, the cleaved mother cell wall gradually degenerated and was not observed in the next cell cycle. In contrast, M. geminata daughter cells entered the growth phase of the next cell cycle bearing the mother and grandmother cell walls, causing the uncovered portion of the plane of division to bulge outward. Such a delay in the degeneration and shedding of the mother cell wall probably led to the development of binary fission and budding.
Cyanelles of the biflagellate protist Cyanophora paradoxa have retained the peptidoglycan layer, which is critical for division, as indicated by the inhibitory effects of beta-lactam antibiotics. An FtsZ ring is formed at the division site during cyanelle division. We used immunofluorescence microscopy to observe the process of FtsZ ring formation, which is expected to lead cyanelle division, and demonstrated that an FtsZ arc and a split FtsZ ring emerge during the early and late stages of cyanelle division, respectively. We used an anti-FtsZ antibody to observe cyanelle FtsZ rings. We observed bright, ring-shaped fluorescence of FtsZ in cyanelles. Cyanelles were kidney-shaped shortly after division. Fluorescence indicated that FtsZ did not surround the division plane at an early stage of division, but rather formed an FtsZ arc localized at the constriction site. The constriction spread around the cyanelle, which gradually became dumbbell shaped. After the envelope's invagination, the ring split parallel to the cyanelle division plane without disappearing. Treatment of C. paradoxa cells with ampicillin, a beta-lactam antibiotic, resulted in spherical cyanelles with an FtsZ arc or ring on the division plane. Transmission electron microscopy of the ampicillin-treated cyanelle envelope membrane revealed that the surface was not smooth. Thus, the inhibition of peptidoglycan synthesis by ampicillin causes the inhibition of septum formation and a marked delay in constriction development. The formation of the FtsZ arc and FtsZ ring is the earliest sign of cyanelle division, followed by constriction and septum formation.
Plastids of glaucocystophytes are termed cyanelles and retain primitive features, such as a peptidoglycan wall. We isolated a full-length prokaryotic plastid division gene, FtsZ, from the glaucocystophyte alga Cyanophora paradoxa Korshikov (CpFtsZ-cy). CpftsZ-cy has a chloroplast-targeting signal at the N-teminus. Immunofluorescence microscopy showed that CpFtsZ-cy forms a ring-like structure at the division plane of cyanelles.
Summary Haptophytes are abundant phytoplankton that possess 4 membrane-bound chloroplasts. These chloroplasts originated from a red alga that was taken up by a eukaryotic host cell. No previous work has reported on the protein targeting of haptophytes, except for computational analyses. We isolated the two genes encoding chloroplast proteins AtpC1 and FtsZ from Pavlova pinguis and analyzed their molecular structure. These proteins had a bipartite sequence at the Nterminus, which consisted of an endoplasmic reticulum (ER) signal sequence followed by a chloroplast transit peptide. To demonstrate the functionality of the ER signal sequences and the chloroplast targeting sequences in vivo, we fused the predicted ER signal sequence, chloroplast transit peptide, and bipartite sequence of AtpC1 and FtsZ individually to the N-terminus of green fluorescent protein (sGFP). This was then introduced into cultured tobacco cells. Microscopic observation revealed that the predicted ER signal sequences of AtpC1 and FtsZ had the ability to localize to the ER, and the following amino acids worked as a chloroplast transit peptide in the tobacco cells. We concluded that the AtpC1 and FtsZ of P. pinguis have a bipartite sequence at the N-terminus and a molecular structure in common with other independently established secondarily endosymbiotic algae.
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