A 9 bp cis-element in the promoters of class I small heat shock protein genes on chromosome 3 in rice mediates L-azetidine-2-carboxylic acid and heat shock responses.

In rice, the class I small heat shock protein (sHSP-CI) genes were found to be selectively induced by L-azetidine-2-carboxylic acid (AZC) on chromosome 3 but not chromosome 1. Here it is shown that a novel cis-responsive element contributed to the differential regulation. By serial deletion and computational analysis, a 9 bp putative AZC-responsive element (AZRE), GTCCTGGAC, located between nucleotides -186 and -178 relative to the transcription initiation site of Oshsp17.3 was revealed. Deletion of this putative AZRE from the promoter abolished its ability to be induced by AZC. Moreover, electrophoretic mobility shift assay (EMSA) revealed that the AZRE interacted specifically with nuclear proteins from AZC-treated rice seedlings. Two AZRE-protein complexes were detected by EMSA, one of which could be competed out by a canonical heat shock element (HSE). Deletion of the AZRE also affected the HS response. Furthermore, transient co-expression of the heat shock factor OsHsfA4b with the AZRE in the promoter of Oshsp17.3 was effective. The requirement for the putative AZRE for AZC and HS responses in transgenic Arabidopsis was also shown. Thus, AZRE represents an alternative form of heat HSE, and its interaction with canonical HSEs through heat shock factors may be required to respond to HS and AZC.

Chilling stress suppresses chloroplast development and nuclear gene expression in leaves of mung bean seedlings.

Etiolated leaves of 28 degrees C-dark-grown mung bean (Vigna radiata L. cv. 2937) seedlings fail to turn green after being shifted to a light and cold environment. At the visible phenotypic level, incapability of leaf greening is the only failure event for the de-etiolation of mung bean seedlings at low temperature. Ultrastructural studies revealed that chloroplast development was completely suppressed by chilling treatment. A cDNA library originating from 28 degrees C-light-grown seedling leaves was constructed for screening cold-suppressed (cos) genes. Thirteen full-length cDNA clones were obtained, with 12 clones encoding chloroplast proteins, which, according to their known physiological functions, were important for chloroplast development and photosynthesis. Another cos cDNA encodes CYP90A2, which is a cytochrome P450 protein involved in the biosynthesis of brassinosteroid hormones. All cos genes are light-regulated at normal temperature. The influence of chilling stress on cos expression was examined in 10 degrees C-light- and 10 degrees C-dark-grown etiolated seedlings, and in 10 degrees C-light-grown green plants. The data show that cos expression in these three treatments is severely suppressed. This suppression is controlled at the transcriptional level, as demonstrated by nuclear runoff experiments, and is reversible because cos mRNAs accumulate again after the cold-treated plants have been transferred to 28 degrees C.

Azetidine-induced accumulation of class I small heat shock proteins in the soluble fraction provides thermotolerance in soybean seedlings.

Accumulation of class I small heat shock proteins (sHSPs) is induced by the proline analog, azetidine-2-carboxylic acid (Aze) in soybean seedlings to a level similar to that induced by exposure to 40 degrees C. However, only the treatment with 10 mM Aze for 6 h and subsequently with 10 mM proline for 24 h protected the seedlings from damage during subsequent exposure to 45 degrees C as assessed by 2,3,5-triphenyltetrazolium chloride (TTC) staining. A chaperone activity assay showed that the purified class I sHSPs induced by Aze were functional in vitro and protected proteins from thermal denaturation. Amino acid composition analysis indicated that Aze was not incorporated into de novo synthesized class I sHSPs. Accumulation of class I sHSPs in the soluble post-ribosomal supernatant fraction was found to be important for acquisition of thermotolerance. We suggest that both the accumulation of class I sHSPs and their presence in the soluble fraction are important for establishment of thermotolerance.

Characterization of the genomic structures and selective expression profiles of nine class I small heat shock protein genes clustered on two chromosomes in rice (Oryza sativa L.).

The cytosolic class I small heat shock proteins (sHSP-CI) represent the most abundant sHSP in plants. Here, we report the characterization and the expression profile of nine members of the sHSP-CI gene family in rice (Oryza sativa Tainung No.67), of which Oshsp16.9A, Oshsp16.9B, Oshsp16.9C, Oshsp16.9D and Oshsp17.9B are clustered on chromosome 1, and Oshsp17.3, Oshsp17.7, Oshsp17.9A and Oshsp18.0 are clustered on chromosome 3. Oshsp17.3 and Oshsp18.0 are linked by a 356-bp putative bi-directional promoter. Individual gene products were identified from the protein subunits of a heat shock complex (HSC) and from in vitro transcription/ translation products by two-dimensional gel electrophoreses (2-DE). All sHSP-CI genes except Oshsp17.9B were induced strongly after a 2-h heat shock treatment. The genes on chromosome 3 were induced rapidly at 32 and 41 degrees C, whereas those on chromosome 1 were induced slowly by similar conditions. Seven of these genes, except Oshsp16.9D and Oshsp17.9B, were induced by arsenite (As), but only genes on chromosome 3 were strongly induced by azetidine-2-carboxylic acid (Aze, a proline analog) and cadmium (Cd). A similar expression profile of all sHSP-CI genes at a lower level was evoked by ethanol, H2O2 and CuCl2 treatments. Transient expression assays of the promoter activity by linking to GUS reporter gene also supported the in vivo selective expression of the sHSP-CI genes by Aze treatment indicating the differential induction of rice sHSP-CI genes is most likely regulated at the transcriptional level. Only Oshsp16.9A abundantly accumulated in mature dry seed also suggested additionally prominent roles played by this HSP in development.

Functional regions of rice heat shock protein, Oshsp16.9, required for conferring thermotolerance in Escherichia coli.

Rice (Oryza sativa) class I low-molecular mass (LMM) heat shock protein (HSP), Oshsp16.9, has been shown to be able to confer thermotolerance in Escherichia coli. To define the regions for this intriguing property, deletion mutants of this hsp have been constructed and overexpressed in E. coli XL1-blue cells after isopropyl beta-D-thioglactopyranoside induction. The deletion of amino acid residues 30 through 36 (PATSDND) in the N-terminal domain or 73 through 78 (EEGNVL) in the consensus II domain of Oshsp16.9 led to the loss of chaperone activities and also rendered the E. coli incapable of surviving at 47.5 degrees C. To further investigate the function of these two domains, we determined the light scattering changes of Oshsp16.9 mutant proteins at 320 nm under heat treatment either by themselves or in the presence of a thermosensitive enzyme, citrate synthase. It was observed that regions of amino acid residues 30 through 36 and 73 through 78 were responsible for stability of Oshsp16.9 and its interactions with other unfolded protein substrates, such as citrate synthase. Studies of two-point mutants of Oshsp16.9, GST-N74E73K and GST-N74E74K, indicate that amino acid residues 73 and 74 are an important part of the substrate-binding site of Oshsp16.9. Non-denaturing gel analysis of purified Oshsp16.9 revealed that oligomerization of Oshsp16.9 was necessary but not sufficient for its chaperone activity.