Dual N- and C-terminal processing of citrus chlorophyllase precursor within the plastid membranes leads to the mature enzyme.

Chl, the central player in harvesting light energy for photosynthesis, is enzymatically degraded during natural turnover, leaf senescence, fruit ripening or following biotic/abiotic stress induction. The photodynamic properties of Chl and its metabolites call for tight regulation of the catabolic pathway enzymes to avoid accumulation of intermediate breakdown products. Chlorophyllase, the Chl dephytilation enzyme, was previously demonstrated to be an initiator of Chl breakdown when transcriptionally induced to be expressed during ethylene-induced citrus fruit color break or when heterologously expressed in different plant systems. Citrus chlorophyllase was previously shown to be translated as a precursor protein, which is subsequently post-translationally processed to a mature form. We demonstrate that maturation of citrus chlorophyllase involves dual N- and C-terminal processing which appear to be rate-limiting post-translational events when chlorophyllase expression levels are high. The chlorophyllase precursor and intermediate forms were shown to be of transient nature, while the mature form accumulates over time, suggesting that processing may be involved in post-translational regulation of enzyme in vivo function. This notion is further supported by the finding that neither N- nor C-terminal processed domains are essential for chloroplast targeting of the enzyme, and that both processing events occur within the chloroplast membranes. Studies on the processing of chlorophyllase versions truncated at the N- or C-termini or mutated to abolish C-terminal processing suggest that each of the processing events is independent. Dual N- and C-terminal processing, not involving an organellar targeting signal, has rarely been documented in plants and is unique for a plastid protein.

Sumoylation of Arabidopsis heat shock factor A2 (HsfA2) modifies its activity during acquired thermotholerance.

Post-translational modification of target proteins by the small ubiquitin-like modifier protein (SUMO) regulate many cellular processes. In this work we show SUMOylation of the heat shock transcription factor, AtHsfA2, in connection with the plant's response to heat stress and acquired thermotolerance. Using the Yeast two hybrid and the bimolecular fluorescence complementation system, we have found that AtSUMO1 physically interacts with AtHsfA2. Further investigation allowed us to determine that Lys 315 of AtHsfA2 is the main SUMOylation site. Overexpression of AtSUMO1 led to a decrease in AtHsfA2 transcriptional activation of heat shock promoters. We have examined the effect of AtSUMO1 on AtHsfA2 during heat shock treatments. The phenotype of seedlings overexpressing AtSUMO1 resembled the phenotype of AtHsfA2 knock out seedlings, which were more sensitive than wild type seedlings to repeated heat treatment. Furthermore, AtSUMO1 overexpressing seedlings exhibited lower expression levels of small heat shock proteins as compared with wild type seedlings after heat treatment. Based on our findings, we suggest that AtSUMO1 is involved in the regulation of AtHsfA2 in acquired thermotolerance.

Involvement of Arabidopsis ROF2 (FKBP65) in thermotolerance.

The ROF2 (FKBP65) is a heat stress protein which belongs to the FK506 Binding Protein (FKBP) family. It is homologous to ROF1 (FKBP62) which was recently shown to be involved in long term acquired thermotolerance by its interaction with HSP90.1 and modulation of the heat shock transcription factor HsfA2. In this study, we have demonstrated that ROF2 participates in long term acquired thermolerance, its mode of action being different from ROF1. In the absence of ROF2, the small heat shock proteins were highly expressed and the plants were resistant to heat stress, opposite to the effect observed in the absence of ROF1. It was further demonstrated that ROF2 transcription is modulated by HsfA2 which is also essential for keeping high levels of ROF2 during recovery from heat stress. ROF2 localization to the nucleus was observed several hours after heat stress exposure and its translocation to the nucleus was independent from the presence of HSP90.1 or HsfA2. ROF2 has been shown to interact with ROF1, to form heterodimers and it is suggested that via this interaction it can join the complex ROF1-HSP90.1- HsfA2. Transient expression of ROF2 together with ROF1 repressed transcription of small HSPs. A model describing the mode of action of ROF2 as a heat stress modulator which functions in negative feedback regulation of HsfA2 is proposed.