BackgroundSugar beet is a highly salt-tolerant crop. However, its ability to withstand high salinity is reduced compared to sea beet, a wild ancestor of all beet crops. The aim of this study was to investigate transcriptional patterns associated with physiological, cytological and biochemical mechanisms involved in salt response in these closely related subspecies. Salt acclimation strategies were assessed in plants subjected to either gradually increasing salt levels (salt-stress) or in excised leaves, exposed instantly to salinity (salt-shock).ResultThe majority of DEGs was down-regulated under stress, which may lead to certain aspects of metabolism being reduced in this treatment, as exemplified by lowered transpiration and photosynthesis. This effect was more pronounced in sugar beet. Additionally, sugar beet, but not sea beet, growth was restricted. Silencing of genes encoding numerous transcription factors and signaling proteins was observed, concomitantly with the up-regulation of lipid transfer protein-encoding genes and those coding for NRTs. Bark storage protein genes were up-regulated in sugar beet to the level observed in unstressed sea beet. Osmotic adjustment, manifested by increased water and proline content, occurred in salt-shocked leaves of both genotypes, due to the concerted activation of genes encoding aquaporins, ion channels and osmoprotectants synthesizing enzymes. bHLH137 was the only TF-encoding gene induced by salt in a dose-dependent manner irrespective of the mode of salt treatment. Moreover, the incidence of bHLH-binding motives in promoter regions of salinity-regulated genes was significantly greater than in non-regulated ones.ConclusionsMaintaining homeostasis under salt stress requires deeper transcriptomic changes in the sugar beet than in the sea beet. In both genotypes salt shock elicits greater transcriptomic changes than stress and it results in greater number of up-regulated genes compared to the latter. NRTs and bark storage protein may play a yet undefined role in salt stress-acclimation in beet. bHLH is a putative regulator of salt response in beet leaves and a promising candidate for further studies.Electronic supplementary materialThe online version of this article (10.1186/s12870-019-1661-x) contains supplementary material, which is available to authorized users.
Arabidopsis plants responding to phosphorus (P) deficiency increase lateral root formation and reduce primary root elongation. In addition the number and length of root hairs increases in response to P deficiency. Here we studied the patterns of radical oxygen species (ROS) in the roots of Arabidopsis seedlings cultured on media supplemented with high or low P concentration. We found that P availability affected ROS distribution in the apical part of roots. If plants were grown on high P medium, ROS were located in the root elongation zone and quiescent centre. At low P ROS were absent in the elongation zone, however, their synthesis was detected in the primary root meristem. The proximal part of roots was characterized by ROS production in the lateral root primordia and in elongation zones of young lateral roots irrespective of P concentration in the medium. On the other hand, plants grown at high or low P differed in the pattern of ROS distribution in older lateral roots. At high P, the elongation zone was the primary site of ROS production. At low P, ROS were not detected in the elongation zone. However, they were present in the proximal part of the lateral root meristem. These results suggest that P deficiency affects ROS distribution in distal parts of Arabidopsis roots. Under P-sufficiency ROS maximum was observed in the elongation zone, under low P, ROS were not synthesized in this segment of the root, however, they were detected in the apical root meristem.Keywords Hydrogen peroxide Á Lateral roots Á Phosphate availability Á Superoxide Á Root growth Á Root system architecture Abbreviations DCF 2 0 ,7 0 -Dichlorofluorescein DCFH 2 0 ,7 0 -Dichlorodihydrofluorescein NBT Nitroblue tetrazolium QC Quiescent centre ROS Radical oxygen species
The aim of this study was to test the effect of auxin treatment on selected parameters of the redox metabolism in roots. We found that auxin application results in a reduction in the H 2 O 2 level in roots. The hormone stimulated CuZn-superoxide dismutase, but simultaneously increased the activities of catalase, cell wall bound ferulic acid peroxidase, and soluble peroxidase izoenzymes. The analysis of the expression of genes coding for the cytosolic izoform of CuZn-superoxide dismutase, catalase, and cell wall associated peroxidase (TPX 1) involved in cell wall stiffening and lignification revealed the stimulatory effect of exogenous auxin on the expression of the aforementioned genes. The enzyme activity and gene expression in the roots of control and auxin-treated plants were studied in daily intervals, during a 3-day-long growth cycle. The stimulatory effect of auxin on the enzymatic activity was transient with the highest stimulation observed on the second day of treatment. On the third day, the activities of the enzymes decreased. The maximal enzyme activities were preceded by a rise in gene expression. The increase in the level of CuZn-superoxide dismutase and catalase transcripts were detected after 1 day of auxin treatment. Then the expression of the aforementioned genes decreased. The period of auxin-dependent stimulation of the TPX 1 gene expression encompassed the first and the second day of treatment. Auxin stimulated CuZnsuperoxide dismutase and catalase activities only in the distal zone of the root while peroxidase activity was increased by auxin in the distal as well as in the proximal parts of the organ.
Plant peroxidases have strong potential utility for decontamination of phenol-polluted wastewater. However, large-scale use of these enzymes for phenol depollution requires a source of cheap, abundant, and easily accessible peroxidase-containing material. In this study, we show that potato pulp, a waste product of the starch industry, contains large amounts of active peroxidases. We demonstrate that potato pulp may serve as a tool for peroxidase-based remediation of phenol pollution. The phenol removal efficiency of potato pulp was over 95 % for optimized phenol concentrations. The potato pulp enzymes maintained their activity at pH 4 to 8 and were stable over a wide temperature range. Phenol solutions treated with potato pulp showed a significant reduction in toxicity compared with untreated phenol solutions. Finally we determined that this method may be employed to remove phenol from industrial effluent with over 90 % removal efficiency under optimal conditions.
To study the relationship between glutathione and rooting, tomato seedling cuttings, grown on basal-or on auxin-supplemented media, were treated with the reduced (GSH) or oxidized (GSSG) form of this antioxidant. In turn, the consequences of the depletion of GSH pool on rooting were tested using L-buthionine sulfoximine (BSO), a specific inhibitor of GSH biosynthesis. Effects of the aforementioned treatments on rooting response were assessed. GSH treatment promoted root formation on cuttings grown on both basal-and auxin-supplemented media. Whereas GSSG did not affect the number of roots formed by cuttings grown on basal medium, it strongly enhanced the rooting stimulatory effect of auxin treatment. GSH depletion resulting from BSO application did not change the number of roots formed. All the tested compounds, namely GSH, GSSG, BSO and auxin, had a strong inhibitory effect on the elongation of regenerated roots. Supplementing the rooting medium with glutathione efficiently increased the GSH level in the rooting zones, while addition of BSO led to a strong decrease in endogenous GSH level. Neither of the treatments affected the level of GSSG. Exogenous auxin affect neither GSH nor GSSG levels in rooting zones; however, in the regenerated roots, GSH level was significantly higher when the organs were formed on auxin-supplemented medium. Patterns of GSH distribution in the roots regenerated on basal-and auxin-enriched media were studied using the GSH-specific dye monochlorobimane and confocal laser scanning microscopy. GSH was found in the root apical meristem and in the elongation zone. Auxin did not change the GSH distribution; however, the number of fluorescent cells was higher when roots were regenerated on auxin-supplemented medium.
BvpAPX is a full-length cDNA-encoding peroxisomal ascorbate peroxidase isolated from leaves of salt-stressed beet (Beta vulgaris) plants. A high level of identity has been reported between the deduced amino acid sequence of BvpAPX and other known ascorbate peroxidases. The genomic sequence of BvpAPX revealed a gene composed of 5 exons and 4 introns. Several sequence motifs revealed in the 5’UTR region of the gene confer to BvpAPX a putative responsiveness to various abiotic stresses. We determined the effect of salt stress on BvpAPX expression in leaves of the cultivated beet varieties, Huzar and Janosik, and their wild salt-tolerant relative B. vulgaris ssp. maritima. Plants were subjected to salt stress during a 32-day culture period (long-term salt treatment). An alternative salinization protocol consisted of an 18-h incubation of detached beet leaves in media supplemented with toxic salt concentrations (short-term salt treatment). RT-Q-PCR analysis revealed that BvpAPX expression markedly increased in leaves of plants subjected to conditions of long-term treatment with salinity, whereas BvpAPX transcript levels remained unaffected in detached leaves during short-term salt treatment. In addition, several leaf redox system parameters, such as ascorbate peroxidase activity or ascorbic acid, hydrogen peroxide, and lipid hydroperoxide concentration, were determined in the leaves of beet plants subjected to salt stress conditions.Electronic supplementary materialThe online version of this article (doi:10.1007/s11105-013-0636-6) contains supplementary material, which is available to authorized users.
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