Explore the vast range of titles available.

ERF proteins (ethylene-responsive factors), which belong to the AP2/ERF superfamily, play essential roles in plant development, growth, and response to abiotic and biotic constraints. In a previous study, we cloned a cDNA encoding the StERF94 factor from potato plants and the phylogenetic analyses showed that it belongs to group IX of the ERF family. Genes of this group are known to be involved in plant response to biotic stress. The StERF94 cDNA was overexpressed in transgenic potato plants and the resulting transgenic plants showed a high tolerance to salinity. In this study, we investigated the response of StERF94 transgenic plants to biotic stress by evaluating their resistance to Fusarium solani infection. A significant enhanced resistance to the fungus was noticed in the transgenic plants which displayed limited malondialdehyde and H2O2 production and increasing antioxidant enzyme activities. Our findings also revealed that overexpression of StERF94 in potato enhanced expression of relevant defense genes like those encoding PR proteins (pathogenesis related) which led to a protection against disease propagation and reduction of fungus development in plant tissues.

Potato plants are often exposed to biotic and abiotic stresses that negatively impact their growth, development, and yield. Plants respond to different stresses by inducing large numbers of stress-responsive genes, which can be either functional or regulatory genes. Among regulatory genes, Dehydration Responsive Element Binding (DREB) genes are considered as one of the main groups of transcriptional regulators. The overexpression of these factors in several transgenic plants leads to enhancement of abiotic stress tolerance. However, a number of reports showed that the overexpression of DREB factors under control of constitutive promoter, affects their morphology and production. Therefore, it becomes interesting to evaluate the effect of the overexpression of this StDREB1 transcription factor on plant growth, morphology, yield and tuber composition under both greenhouse and field culture conditions. To our knowledge, there is no available data on the effect of DREBA-4 overexpression on potato plants morphology and yield. Indeed, most studies focused on DREB genes from A-1 and A-2 groups for other plant species. Our results showed that StDREB1, a A-4 group of DREB gene from potato (Solanum tuberosum L.), overexpressing plants did not show any growth retardation. On the contrary, they seem to be more vigorous, and produced higher tuber weight in greenhouse and field culture than the wild type (WT) plants. Moreover, the overexpression of StDREB1 transcription factor seemed to have an effect on tuber quality in terms of dry matter, starch contents and reducing sugars in comparison to the WT tubers. These data suggest that the StDREB1 gene from A-4 group of DREB subfamily can be a good candidate in potato breeding for stress tolerance.

The purpose of this study was to characterize the peels of a CN1 somatic hybrid obtained from two dihaploid potato lines (Cardinal H14 and Nicola H1) in terms of the health‐promoting phenolic compounds (phenolic acids and anthocyanins). The CN1 hybrid is defined by a pink tuber skin color making it different from the light‐yellow‐skinned “Spunta,” which is the most commonly grown potato cultivar in Tunisia. Oven‐dried peel samples derived from CN1 hybrid and cv. Spunta were ground, and phenolic compounds were extracted with water or methanol for quantification. Lyophilized peels were used for the phenolic acid and anthocyanin analyses. Higher total quantities of phenolic compounds were recovered in methanol extracts compared with water extracts. A slightly higher concentration of phenolic acids (100 mg/100 g DW) was obtained in the lyophilized peels extract of CN1 hybrid than in the cv. Spunta corresponding sample (83 mg/100 g DW). The profiles of the chlorogenic acid isomers were almost identical in both of CN1 hybrid and cv. Spunta. Caffeic acid (CA) and three caffeoylquinic acids (CQAs): 3‐CQA, 4‐CQA, and 5‐CQA, were identified from both genotypes, 5‐CQA being the dominant form in both potatoes. Since the CN1 hybrid has a pink skin color, its anthocyanin profile was also determined. The anthocyanin quantity in the CN1 peels was 5.07 mg/100 g DW, involving six different anthocyanins that were identified within the extract, namely, Pelargonidin‐3‐rutinoside‐5‐glucoside, peonidin‐3‐rutinoside‐5‐glucoside, coumaroyl ester of pelargonidin‐3‐rutinoside‐5‐glucoside, coumaroyl ester of peonidin‐3‐rutinoside‐5‐glucoside, feruloyl ester of pelargonidin‐3‐rutinoside‐5‐glucoside, and feruloyl ester of peonidin‐3‐rutinoside‐5‐glucoside. These results suggest that the peel waste of CN1 somatic hybrid can be considered as a promising source of high‐value compounds for food industry. The peel waste of the cultivated CN1 somatic hybrid can be considered as a promising source of high‐value compounds for food industry.

Despite their economic importance worldwide, potato plants are sensitive to various abiotic constraints, such as drought and high temperatures, which cause significant losses in yields and tuber quality. Moreover, because of the climate change phenomenon, plants are frequently subjected to combined stresses, mainly high temperatures and drought. In this context, breeding for tolerant varieties should consider not only plant response to drought or high temperature but also to combined stresses. In the current study, we studied transgenic potato plants overexpressing an ethylene response transcription factor (TF; StERF94) involved in abiotic stress response signaling pathways. Our previous results showed that these transgenic plants display tolerance to salt stress more than wildtype (WT). In this work, we aimed to investigate the effects of drought, heat, and combined stresses on transgenic potato plants overexpressing StERF94 TF under in vitro culture conditions. The obtained results revealed that StERF94 overexpression improved the tolerance of the transgenic plants to drought, heat, and combined stresses through better control of the leaf water and chlorophyll contents, activation of antioxidant enzymes, and an accumulation of proline, especially in the leaves. Indeed, the expression level of antioxidant enzyme-encoding genes (CuZnSOD, FeSOD, CAT1, and CAT2) was significantly induced by the different stress conditions in the transgenic potato plants compared with the WT plants. This study further confirms that StERF94 TF may be implicated in regulating the expression of target genes encoding antioxidant enzymes.

Salinity is one of the most important constraints threatening the cultivation of potato plants (Solanum tuberosum L.). It affects plant growth and leads to significant yield loss. Consequently, it is important to improve the tolerance of potato plants to salinity. In this context, we investigated the involvement of a potato ethylene responsive factor (StERF94) in plant response to salinity, since our previous genome-wide analysis showed that it may be related to biotic and abiotic stress response. ERF proteins belong to a large family of transcription factors that participate in plant response to abiotic stresses. We have previously identified the StERF94 gene which shows increased expression in potato plants submitted to salt treatment. In this study, transgenic potato plants overexpressing StERF94 were produced and submitted to salt treatment (100 mM NaCl) in vitro and under greenhouse culture conditions. StERF94 transgenic lines showed lower decrease of stem elongation under salt treatment in comparison to non-transgenic wild-type plants. Moreover, these plants showed a low level of H2O2 and Malondialdehyde content, and an increase in catalase and GPX (Gluthation peroxidase) activities compared to non-transgenic plants. In a second step, enhanced expression of some target genes for example CuZn-SOD, DHN25 (Dehydrin) and ERD (Early Responsive to Dehydration) was noted in the StERF94 transgenic plants, submitted to salt treatment. The StERF94 factor was also involved in the activation of osmoprotectant synthesis. Taken together, all these data suggest that overexpression of the StERF94 transcription factor increases the tolerance of potato plants to salinity by improving plant growth, osmoprotectant synthesis and antioxidant activityleading to low oxidative stress damage.

The ERF transcription factors belong to the AP2/ERF superfamily, one of the largest transcription factor families in plants. They play important roles in plant development processes, as well as in the response to biotic, abiotic, and hormone signaling. In the present study, 155 putative ERF transcription factor genes were identified from the potato ( Solanum tuberosum ) genome database, and compared with those from Arabidopsis thaliana . The StERF proteins are divided into ten phylogenetic groups. Expression analyses of five StERFs were carried out by semi-quantitative RT-PCR and compared with published RNA-seq data. These latter analyses were used to distinguish tissue-specific, biotic, and abiotic stress genes as well as hormone-responsive StERF genes. The results are of interest to better understand the role of the AP2/ERF genes in response to diverse types of stress in potatoes. A comprehensive analysis of the physiological functions and biological roles of the ERF family genes in S. tuberosum is required to understand crop stress tolerance mechanisms.

Cadmium (Cd) is a toxic heavy metal naturally present in soils. It causes environmental pollution because of the increase of mining and industrial activities in the twentieth century. Although plants do not require Cd, they can accumulate high levels of this metal. The response of plants to Cd pollution involves several signaling pathways involving stress responsive transcription factors. Among these transcription factors, it has been reported that DREB (drought-responsive element binding) factors are involved in plant response to abiotic constraints. In this context, in previous studies, we isolated and characterized two DREB genes from potato that were designated StDREB1 and StDREB2. Their overexpression in transgenic potato lines led to enhanced drought and salt stress tolerance in comparison to untransformed plants. These DREB transcription factors play crucial regulatory roles in different stress responsive pathways in potato. The goal of this report is to study the response of these transgenic potato plants overexpressing StDREB1 and StDREB2 to Cd stress. Therefore, transgenic plants and control plants were cultivated in vitro in MS (Murashige and Skoog) medium supplemented with 50–150 µM CdCl2. After 7 and 14 days of treatment, plant tissues were used to evaluate a number of physiological parameters. Transgenic plants submitted to Cd stress, showed lower decrease in growth, chlorpophyll and carotenoid content than wild-type (WT) plants. Similarly, almost no loss of water content was measured in BF3, SP1 and SPM lines. All transgenic plants exhibited lower H2O2 content and higher antioxidant enzyme expression than WT. A higher proline content was also measured in these plants after Cd treatment in comparison to WT. All these data suggest that overexpression of the StDREB genes improves tolerance of potato plants to Cd by improving plant growth, proline and antioxidant production leading to low oxidative stress damage.

Vanadium has been shown to catalyze the generation of reactive oxygen species. Since free radical production and lipid peroxidation are potentially important mediators in testicular physiology and pathophysiology, the present study was conducted to elucidate vanadium-induced oxidative damage in rat testis and the ameliorative role of Salvia officinalis essential oil (SEO) against the adverse effects of this heavy metal. Adult male Wistar rats were treated daily during 10 days either with ammonium metavanadate (5 mg/kg bw, intraperitoneally), SEO (15 mg/kg bw, orally) or their combination. A group of rats receiving daily a saline solution served as a negative control. Vanadium treatment induced a significant decrease in body and reproductive organ weights, serum testosterone level and sperm number and motility. An increase in lipid peroxidation and protein oxidation as well as a marked inhibition in the activities of antioxidant enzymes in the testes and seminal vesicles indicated the occurrence of oxidative stress after vanadium toxicity. Histopathological changes in testis and seminal vesicles were also observed following vanadium administration. However, co-administration of SEO to vanadium-treated rats resulted in an appreciable improvement of these parameters, emphasizing the therapeutic effects of SEO. It can be suggested that SEO mitigates vanadium-induced reproductive damage due to its antioxidant capacity. Thus, we can hypothesize that SEO supplementation could protect against vanadium poisoning.

It has been established that drought-responsiveelement binding (DREB) proteins correspond to transcriptionfactors which play important regulatory roles in plant response to abiotic and biotic stresses. In this study, a novel cDNA encoding DREB transcription factor, designatedStDREB1, was isolated from potato (Solanum tuberosum L.). This protein was classified in the A-4 group of DREB subfamily based on multiple sequence alignments and phylogenetic characterization. Semi-quantitativeRT-PCR showed that StDREB1 is expressed in leaves,stems, and roots under stress conditions and it is greatlyinduced by NaCl, drought, low temperature, and abscisicacid (ABA) treatments. Overexpression of StDREB1 cDNAin transgenic potato plants exhibited an improved salt anddrought stress tolerance in comparison to the non-transformed controls. The enhanced stress tolerance may beassociated with the increase in P5CS-RNA expression (d1-pyrroline-5-carboxylate synthetase) and the subsequentaccumulation of proline osmoprotectant in addition to abetter control of water loss. Overexpression of StDREB1also activated stress-responsive genes, such as thoseencoding calcium-dependent protein kinases (CDPKs), intransgenic potatoes under standard and high salt conditions.These data suggest that the StDREB1 transcription factor isinvolved in the regulation of salt stress tolerance in potato by the activation of different downstream gene expression.

Dehydrins (DHNs) correspond to late embryogenesis abundant proteins (LEA) of group 2, they are known as glycin rich proteins. Despite their expression during the late seed maturation stages, they are also involved in plant response to a number of abiotic stresses such as drought, salinity and cold. In the present study, we identified five full-length cDNAs encoding dehydrins (designated StDHN2a, StDHN1, TAS14, StDHN25 and StLEA27) isolated from potato. These dehydrins were composed of serine amino acids called S domain and lysine-rich segment corresponding to a K domain. Three DHNs (StDHN1, TAS14 and StLEA27) contained Y segments. In silico analysis showed that these StDHN sequences share high homology with other Solanum dehydrin proteins species. The analysis of gene expression using quantitative RT-PCR showed that they were upregulated by dehydration and salinity. Moreover, the search for putative regulatory element in the promoter sequence of dehydrin genes was investigated.