Arabidopsis plants possess a family of nine AtAtg8 gene homologues of the yeast autophagy-associated Apg8/Aut7 gene. To gain insight into how these genes function in plants, first, the expression patterns of five AtAtg8 homologues were analysed in young Arabidopsis plants grown under favourable growth conditions or following exposure to prolonged darkness or sugar starvation. Promoters, plus the entire coding regions (exons and introns) of the AtAtg8 genes, were fused to the beta-glucuronidase reporter gene and transformed into Arabidopsis plants. In all plants, grown under favourable growth conditions, beta-glucuronidase staining was much more significant in roots than in shoots. Different genes showed distinct spatial and temporal expression patterns in roots. In some transgenic plants, beta-glucuronidase staining in leaves was induced by prolonged darkness or sugar starvation. Next, Arabidopsis plants were transformed with chimeric gene-encoding Atg8f protein fused to N-terminal green fluorescent protein and C-terminal haemagglutinin epitope tags. Analysis of these plants showed that, under favourable growth conditions, the Atg8f protein is efficiently processed and is localized to autophagosome-resembling structures, both in the cytosol and in the central vacuole, in a similar manner to its processing and localization under starvation stresses. Moreover, treatment with a cocktail of proteasome inhibitors did not prevent the turnover of this protein, implying that its turnover takes place in the vacuoles, as occurs in yeasts. The results suggest that, in plants, the cellular processes involving the Atg8 genes function efficiently in young, non-senescing tissues, both under favourable growth conditions and under starvation stresses.
Eukaryotes contain a ubiquitous family of autophagy-associated Atg8 proteins. In animal cells, these proteins have multiple functions associated with growth, cancer, and degenerative diseases, but their functions in plants are still largely unknown. To search for novel functions of Atg8 in plants, the present report tested the effect of expression of a recombinant AtAtg8 protein, fused at its N-terminus to green fluorescent protein (GFP) and at its C-terminus to the haemagglutinin epitope tag, on the response of Arabidopsis thaliana plants to the hormones cytokinin and auxin as well as to salt and osmotic stresses. Expression of this AtAtg8 fusion protein modulates the effect of cytokinin on root architecture. Moreover, expression of this fusion protein also reduces shoot anthocyanin accumulation in response to cytokinin feeding to the roots, implying the participation of AtAtg8 in cytokinin-regulated root–shoot communication. External application of cytokinin leads to the formation of novel GFP–AtAtg8-containing structures in cells located in the vicinity of the root vascular system, which are clearly distinct in size and dynamic movement from the GFP–AtAtg8-containing autophagosome-resembling structures that were observed in root epidermis cells. Expression of the AtAtg8 fusion construct also renders the plants more sensitive to a mild salt stress and to a lesser extent to a mild osmotic stress. This sensitivity is also associated with various changes in the root architecture, which are morphologically distinct from those observed in response to cytokinin. The results imply multiple functions for AtAtg8 in different root tissues that may also be regulated by different mechanisms.
Euglena complex chloroplasts evolved through secondary endosymbiosis between a phagotrophic trypanosome host and eukaryotic algal endosymbiont. Cytoplasmically synthesized chloroplast proteins are transported in vesicles as integral membrane proteins from the ER to the Golgi apparatus to the Euglena chloroplast. Euglena chloroplast preprotein pre-sequences contain a functional N-terminal ER-targeting signal peptide and a domain having characteristics of a higher plant chloroplast targeting transit peptide, which contains a hydrophobic stop-transfer membrane anchor sequence that anchors the precursor in the vesicle membrane. Pulse-chase subcellular fractionation studies showed that 35S-labeled precursor to the light harvesting chlorophyll a/b binding protein accumulated in the Golgi apparatus of Euglena incubated at 15°C and transport to the chloroplast resumed after transfer to 26°C. Transport of the 35S-labeled precursor to the chlorophyll a/b binding protein from Euglena Golgi membranes to Euglena chloroplasts and import into chloroplasts was reconstituted using Golgi membranes isolated from 15°C cells returned to 26°C. Transport was dependent upon extra- and intrachloroplast ATP and GTP hydrolysis. Golgi to chloroplast transport was not inhibited by N-ethylmaleimide indicating that fusion of Golgi vesicles to the chloroplast envelope does not require N-ethylmaleimide-sensitive factor (NSF). This suggests that N-ethylmaleimide-sensitive factor attachment protein receptors (SNAREs) are not utilized in the targeting fusion reaction. The Euglena precursor to the chloroplast-localized small subunit of ribulose-1,5-bisphosphate carboxylase was not imported into isolated pea chloroplasts. A precursor with the N-terminal signal peptide deleted was imported, indicating that the Euglena pre-sequence has a transit peptide that functions in pea chloroplasts. A precursor to the small subunit of ribulose-1,5-bisphosphate carboxylase with the hydrophobic membrane anchor and the pre-sequence region C-terminal to the hydrophobic membrane anchor deleted was imported localizing the functional transit peptide to the Euglena pre-sequence region between the signal peptidase cleavage site and the hydrophobic membrane anchor. The Euglena precursor to the small subunit of ribulose-1,5-bisphosphate carboxylase and the deletion constructs were not post-translationally imported into isolated Euglena chloroplasts indicating that vesicular transport is the obligate import mechanism. Taken together, these studies suggest that protein import into complex Euglena chloroplasts evolved by developing a novel vesicle fusion targeting system to link the host secretory system to the transit peptide-dependent chloroplast protein import system of the endosymbiont.
The characterisation of transcript levels of chloroplast genes and their changes under different conditions is an initial step towards understanding chloroplast gene expression and the functional integration of the plastid chromosome into the entire integrated compartmentalised genome of the plant cell. Using RNA from cells of 12 different developmental stages and stress treatments, we have studied the transcript patterns of all 96 genes of the circular plastid chromosome of Euglena gracilis, Pringsheim strain Z, by a macroarray-based approach and Northern analysis of selected genes representing approximately half a dozen operons. The unicellular alga possesses complex, triple-envelope chloroplasts that were acquired by secondary endosymbiosis. (1) Transcripts were detected from all genes, although stationary concentrations varied substantially between individual loci. No obvious economy in the expression pattern with respect to transcription units and genes for complex structures was noted. (2) The chromosome appears to be constitutively expressed under all chosen conditions including stresses such as UV light, temperature, antiplastidial agents, herbicide and heavy metal exposure. (3) The euglenoid organelle transcriptome is qualitatively relatively insensitive to the environment, but exhibited marked overall quantitative changes. The more or less global changes demonstrate that primarily RNA turnover, translational, proteolytic and/or metabolic control regulate organelle gene expression in the alga.
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