, 2011a) (for gene list see Table S2) Among the up-regulated gen

, 2011a) (for gene list see Table S2). Among the up-regulated genes were FKBPs (FK506-binding proteins), which are immunophillins involved in protein folding, signal transduction and chaperone activity (Aviezer-Hagai et al., 2007). FKBPs interact with HSP90 in A. thaliana (Rotamase

FKBP1, see Table S2) ( Aviezer-Hagai et al., 2007) or protect cells from oxidative stress ( Gallo et al., 2011). Also up-regulated were several components of the 30S and 50S subunits of the chloroplast ribosomes, which are involved in the translation of chloroplast encoded genes ( Nicolaï et al., 2007). However, no up-regulation of chloroplast genes involved in photosynthesis pathways, lipid acid synthesis, or translation/transcription machinery ( Wicke et al., 2011) was detected. In Z. marina, genes related selleck chemicals to cell wall modifications were up-regulated, particularly PD-0332991 nmr pectin esterases and xyloglucan endotransglucosylases, ( Table S2), the latter important for secondary cell wall reinforcement after the completion of cell expansion ( Bourquin et al., 2002). Similar up-regulation of both classes of cell wall-related proteins has been observed in Chinese cabbage in response to mild heat

treatment, leading to increased cell wall thickness and thermotolerance ( Yang et al., 2006). In summary, heat expression responses in Z. marina, besides HSPs, included protectors against oxidative stress and genes that may increase thermotolerance via fortification of secondary cell walls. Expression profiles of N. noltii were more divergent among populations from the northern and southern location compared to Z. marina. While N. noltii from the southern location showed a weak expression response to

the heat treatment, a large change in gene-expression was observed in the northern N. noltii, mainly due to Olopatadine the down-regulation of genes during heat treatment. In contrast to Z. marina, where genes involved in cell wall modification were up-regulated in response to heat, N. noltii showed a down-regulation of various genes involved in cell wall modification and degradation under heat treatment. While this seems contradictory, it might be explained by different optimal temperatures of both species. Z. marina, which typically occurs in colder waters, might require heat “protection” through cell wall fortification ( Yang et al., 2006). In contrast, N. noltii commonly in warmer waters has adjusted to higher temperatures constitutively but experiences negative tradeoffs of this “heat protection” in colder waters, which in turn requires cell wall degradation and modification. Such a hypothesis, however, remains speculative and requires experimental validation. Importantly, up-regulation of HSP genes was detected in neither N. noltii population ( Table S2), although N. noltii (as did Z. marina) showed reduced shoot growth in response to heat.

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