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ABSTRACT: The biogenesis of Symbiodinium symbiosome in the host cells of the sea anemone, Aiptasia pulchella, involves retention of ApRab5 on and exclusion of ApRab11 from the organelle. One predicted consequence of this differential Rab association is the constant membrane fusion of symbiosomes with endocytic vesicles in the absence of parallel membrane retrieval and the subsequent formation of spacious symbiosomes, which nevertheless, contradicts the common perception. To solve this discrepancy, we determined whether membrane fusion occurs between symbiosomes and endocytic vesicles, and whether ApRab11-independent recycling is involved in symbiosome biogenesis. By using the biotin-avidin detection system, we found evidence for symbiosome-endocytic vesicle fusion. Cloning and characterization of ApRab4, an A. pulchella homolog of Rab4, showed that ApRab4 is associated with both the early endocytic and the perinuclear recycling compartments, and its normal function is required for the organization of the recycling compartments. Immunostaining localized ApRab4 to the symbiosome membrane, partially overlapping with ApRab5-decorated microdomains. Significantly, a treatment that impaired Symbiodinium photosynthesis also abolished symbiosome association of ApRab4. Furthermore, ApRab4 was quickly recruited to newly formed phagosomes, but prolonged association only occurred in those harboring live zooxanthelllae. We propose that ApRab4 retention on the symbiosome is an essential part of the mechanism for the biogenesis of Symbiodinium symbiosome.
Marine Biotechnology 06/2009; 11(6):771-85. · 3.43 Impact Factor
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ABSTRACT: Symbiosome biogenesis and function are central to the endosymbiotic interaction between symbiotic dinoflagellates and their host cnidarians. To understand these important organelles, we have been conducting studies to identify and characterize symbiosome-associated proteins of the Rab family, key regulatory components of vesicular trafficking and membrane fusion in eukaryotic cells. Our prior studies have implicated three endocytic Rab proteins in the regulation of symbiosome biogenesis. Here, we show that ApRab3 is a new member of the Rab3 subfamily, associating with symbiosomes and accumulating on the maturing phagosomes in the A. pulchella digestive cells. ApRab3 is 78% identical to human Rab3C, and contains all Rab 3-specific signature motifs. EGFP-ApRab3-labeled vesicular structures tended to either align along the cell peripheral, or aggregate at one side of the nucleus. ApRab3 specifically co-distributed with the TGN marker, WGA, but not other organelle-specific markers tested. Immunofluorescence staining with a specific peptide antibody showed similar results. Significantly, an expression of a constitutively active mutant caused the enlargement and random dispersion of EGFP-ApRab3-decorated compartments in PC12 cells. Together, these data suggest that ApRab3 is a new member of the Rab3 subfamily, participating in the biosynthetic trafficking pathway, and symbiosome biogenesis involves an interaction with ApRab3-positive vesicles.
Comparative biochemistry and physiology. Part B, Biochemistry & molecular biology 01/2009; 152(3):249-59. · 1.61 Impact Factor
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ABSTRACT: Endosymbiotic association of the Symbiodinium dinoflagellates (zooxanthellae) with their cnidarian host cells involves an alteration in the development of the alga-enclosing phagosomes. To uncover its molecular basis, we previously investigated and established that the intracellular persistence of the zooxanthella-containing phagosomes involves specific alga-mediated interference with the expression of ApRab5 and ApRab7, two key endocytic regulatory Rab proteins, which results in the selective retention of the former on and exclusion of the later from the organelles. Here we examined the role of ApRab11, a cnidarian homologue of the key endocytic recycling regulator, Rab11, in the Aiptasia-Symbiodinium endosymbiosis. ApRab11 protein shared 88% overall sequence identity with human Rab11A and contained all Rab-specific signature motifs. Co-localization and mutagenesis studies showed that EGFP-tagged ApRab11 was predominantly associated with recycling endosomes and functioned in the recycling of internalized transferrin. In phagocytosis of latex beads, ApRab11 was quickly recruited to and later gradually removed from the developing phagosomes. Significantly, although ApRab11 immunoreactivity was rapidly detected on the phagosomes containing either newly internalized, heat-killed zooxanthellae, or resident zooxanthellae briefly treated with the photosynthesis inhibitor DCMU, it was rarely observed in the majority of phagosomes containing either newly internalized live, or healthy resident, zooxanthellae. It was concluded that through active exclusion of ApRab11 from the phagosomes in which they reside, zooxanthellae interfere with the normal recycling process required for efficient phagosome maturation, and thereby, secure their intracellular persistence, and consequently their endosymbiotic relationship with their cnidarian hosts.
Biochemical and Biophysical Research Communications 01/2006; 338(3):1607-16. · 2.48 Impact Factor
