Your search keyword '"Karina B. Ruiz"' showing total 24 results

1. Pulsed LED Light: Exploring the Balance between Energy Use and Nutraceutical Properties in Indoor-Grown Lettuce

Author

Laura Carotti, Giulia Potente, Giuseppina Pennisi, Karina B. Ruiz, Stefania Biondi, Andrea Crepaldi, Francesco Orsini, Giorgio Gianquinto, and Fabiana Antognoni

Subjects

lettuce (Lactuca sativa), indoor farming, hydroponics, phenolic compounds, antioxidant capacity, LED lighting, Agriculture

Abstract

In indoor vertical farms, energy consumption represents a bottleneck for both a system’s affordability and environmental footprint. Although switching frequency (sf) represents a crucial factor in determining the efficacy of light emitting diodes (LED) lighting systems in converting electricity into light, the impact of sf is still underexplored. The aim of this work was to investigate the effect of LEDs sf on the productive and qualitative responses of lettuce (Lactuca sativa L.), also considering the resource use efficiency. Plants were grown for 14 days under red and blue LEDs (215 μmol m−2 s−1 and 16/8 h light/dark, with a red:blue ratio of 3) characterized by two different sf for the blue diode, namely high sf (850 kHz) and low sf (293 kHz). A fluorescent light (same light intensity and photoperiod) was included. LED sf did not alter plant morphological parameters, including fresh or dry biomass, leaf number, leaf area, or water use efficiency. A low sf increased the energy use efficiency (EUE) by 40% as compared to high sf. The latter enhanced the leaf antioxidant capacity, as a consequence of increased concentrations of caftaric and chicoric acids, isoquercetin, and luteolin, consistent with the upregulation of a few genes related to the biosynthetic pathway of phenolic compounds (4C3H and DFR). The study highlights that different sf may significantly affect the EUE as well as crop nutritional properties.

Published

2021

2. The Importance of Non-Diffusional Factors in Determining Photosynthesis of Two Contrasting Quinoa Ecotypes (Chenopodium quinoa Willd.) Subjected to Salinity Conditions

Author

José Delatorre-Herrera, Karina B. Ruiz, and Manuel Pinto

Subjects

Na+, K+, CO2 assimilation, stomatal restrictions, non-diffusional, diffusional, RubisCO activity, Botany, QK1-989

Abstract

The broad distribution of quinoa in saline and non-saline environments is reflected in variations in the photosynthesis-associated mechanisms of different ecotypes. The aim of this study was to characterize the photosynthetic response to high salinity (0.4 M NaCl) of two contrasting Chilean genotypes, Amarilla (salt-tolerant, salares ecotype) and Hueque (salt-sensitive, coastal ecotype). Our results show that saline stress induced a significant decrease in the K+/Na+ ratio in roots and an increase in glycine betaine in leaves, particularly in the sensitive genotype (Hueque). Measurement of the photosynthesis-related parameters showed that maximum CO2 assimilation (Amax) in control plants was comparable between genotypes (ca. 9–10 μmol CO2 m−2 s−1). However, salt treatment produced different responses, with Amax values decreasing by 65.1% in the sensitive ecotype and 37.7% in the tolerant one. Although both genotypes maintained mesophyll conductance when stomatal restrictions were removed, the biochemical components of Amarilla were impaired to a lesser extent under salt stress conditions: for example, the maximum rate of ribulose-1,5-bisphosphate carboxylase/oxygenase (RubisCO; Vcmax) was not as affected in Amarilla, revealing that this enzyme has a higher affinity for its substrate in this genotype and, thus, a better carboxylation efficiency. The present results show that the higher salinity tolerance of Amarilla was also due to its ability to control non-diffusional components, indicating its superior photosynthetic capacity compared to Hueque, particularly under salt stress conditions.

Published

2021

3. Free and Conjugated Phenolic Profiles and Antioxidant Activity in Quinoa Seeds and Their Relationship with Genotype and Environment

Author

Fabiana Antognoni, Giulia Potente, Stefania Biondi, Roberto Mandrioli, Lorenzo Marincich, and Karina B. Ruiz

Subjects

antioxidant activity, Chenopodium quinoa, conjugated phenolics, flavonoids, phenolic acids, nutraceutical properties, Botany, QK1-989

Abstract

The nutraceutical interest in quinoa (Chenopodium quinoa Willd.) seeds is associated with the presence of macronutrients, micronutrients, minerals, vitamins, and polyphenols. In particular, polyphenols contribute to the health-promoting effects of this food crop, and their levels are influenced by environmental conditions. Production of quinoa is recently being explored in temperate climate areas, including Italy. The aim of this research was to assess the profile of bioactive compounds in seeds of two quinoa varieties, Regalona-Baer and Titicaca, grown in northern Italy, compared to that of seeds of those varieties grown in Chile and Denmark, respectively. High-performance liquid chromatography-diode array detector (HPLC-DAD) analysis of phenolic acid and flavonoid profiles, both in their free and soluble conjugated forms, showed that the main differences between Regalona grown in Chile and Italy were for the free vanillic acid and daidzein contents, while the two Titicaca samples mainly differed in quercetin derivative levels. The total phenolic index was comparable in Titicaca and Regalona, and only a slight decrease in this parameter was found in seeds of the two varieties grown in Italy. The in vitro antioxidant activity of seed extracts, evaluated by means of three different assays, indicated that it correlated with flavonol (quercetin derivative) levels. In conclusion, the results indicate that, although environmental conditions alter the polyphenolic profile and biological activities, it is possible to grow good-quality quinoa in northern Italy.

Published

2021

4. New insight into quinoa seed quality under salinity: changes in proteomic and amino acid profiles, phenolic content, and antioxidant activity of protein extracts

Author

Iris eAloisi, Luigi eParrotta, Karina B. RUIZ, Claudia eLandi, Luca eBini, Giampiero eCai, Stefania eBiondi, and Stefano eDel Duca

Subjects

Amino Acids, Chenopodium quinoa, Polyphenols, salt stress, antioxidant activity, seed storage proteins., Plant culture, SB1-1110

Abstract

Quinoa (Chenopodium quinoa Willd) is an ancient Andean seed-producing crop well known for its exceptional nutritional properties and resistance to adverse environmental conditions, such as salinity and drought. Storage proteins, amino acid composition, and bioactive compounds play a crucial role in determining the nutritional value of quinoa seeds. Seeds harvested from three Chilean landraces of quinoa, one belonging to the salares ecotype (R49) and two to the coastal-lowlands ecotype, VI-1 and Villarrica (VR), exposed to two levels of salinity (100 and 300 mM NaCl) were used to conduct a sequential extraction of storage proteins in order to obtain fractions enriched in albumins/globulins, 11S globulin and in prolamin-like proteins. The composition of the resulting protein fractions was analyzed by one- and two-dimensional polyacrylamide gel electrophoresis. Results confirmed a high polymorphism in seed storage proteins; the two most representative genotype-specific bands of the albumin/globulin fraction were the 30- and 32-kDa bands, while the 11S globulin showed genotype-specific polymorphism for the 40- and 42-kDa bands. Spot analysis by mass spectrometry followed by in silico analyses were conducted to identify the proteins whose expression changed most significantly in response to salinity in VR. Proteins belonging to several functional categories (i.e., stress protein, metabolism, and storage) were affected by salinity. Other nutritional and functional properties, namely amino acid profiles, total polyphenol (TPC) and flavonoid (TFC) contents, and antioxidant activity (AA) of protein extracts were also analyzed. With the exception of Ala and Met in R49, all amino acids derived from protein hydrolysis were diminished in seeds from salt-treated plants, especially in landrace VI-1. By contrast, several free amino acids were unchanged or increased by salinity in R49 as compared with VR and VI-1, suggesting a greater tolerance in the salares landrace. VR had the highest TPC and AA under non-saline conditions. Salinity increased TPC in all three landraces, with the strongest increase occurring in R49, and enhanced radical scavenging capacity in R49 and VR. Overall, results show that salinity deeply altered the seed proteome and amino acid profiles and, in general, increased the concentration of bioactive molecules and AA of protein extracts in a genotype-dependent

Published

2016

5. Genotype and Environment as Key Factors Controlling Seed Quality in Latin-American Crops

Author

Luisa Bascuñán-Godoy, María Reguera, Ángel Mujica, Néstor Fernández del Saz, Carolina Sanhueza, Catalina Castro, José Ortiz, Gabriel Barros, José Delatorre-Herrera, Karina B. Ruiz, Teodoro Coba de la Peña, Enrique Ostria, Enrique Martínez, and Susana Fischer

Published

2023

6. The polyamine 'multiverse' and stress mitigation in crops: A case study with seed priming in quinoa

Author

Stefania Biondi, Fabiana Antognoni, Lorenzo Marincich, Mariacaterina Lianza, Ricardo Tejos, Karina B. Ruiz, Biondi S., Antognoni F., Marincich L., Lianza M., Tejos R., and Ruiz K.B.

Subjects

Horticulture, Gene expression, quinoa, salt stress, seed priming, spermidine, spermine

Abstract

The importance of polyamines (PAs) in plant growth and development was recognised several decades ago and, since then, their role in cell proliferation, embryogenesis, organogenesis, flowering, fruit development and ripening, etc. has been investigated to a great extent. In more recent years, most of the attention on PAs has been focussed on their functions in biotic and, especially, abiotic stress responses. Exogenous application, transgenic plants over- or under-expressing PA biosynthetic genes, and mutants have been used to unveil their essential contribution to plant tolerance to salinity, drought, chilling, and heavy metal stresses, among others. In parallel, knowledge on their mechanisms of action has increased greatly and it is today evident that PA functions depend upon their ability to (a) bind electrostatically or covalently to numerous compounds thereby modulating membrane, cell wall, nucleic acid, and protein structure and functions, (b) produce hydrogen peroxide via their catabolic pathways, (c) interact with the biosynthetic and signaling pathways of practically all known phyto hormones, and (d) interact with nitric oxide. In this review, a state-of-the-art overview of PA functions in plants and their possible applications in mitigating stress in crop plants is provided. The potential of seed priming with PAs as an economically and environmentally valid approach for enhancing plant tolerance to adverse environmental conditions is discussed and some results from our study on quinoa and salt stress are presented.

Published

2022

7. The Importance of Non-Diffusional Factors in Determining Photosynthesis of Two Contrasting Quinoa Ecotypes (Chenopodium quinoa Willd.) Subjected to Salinity Conditions

Author

Manuel Pinto, José Delatorre-Herrera, and Karina B. Ruiz

Subjects

0106 biological sciences, 0301 basic medicine, RubisCO activity, Plant Science, non-diffusional, Photosynthesis, 01 natural sciences, Chenopodium quinoa, Article, Na+, K+, CO2 assimilation, 03 medical and health sciences, chemistry.chemical_compound, Betaine, Ecology, Evolution, Behavior and Systematics, diffusional, Ecology, biology, Ecotype, AMAX, RuBisCO, Botany, stomatal restrictions, Photosynthetic capacity, Salinity, Horticulture, 030104 developmental biology, chemistry, QK1-989, biology.protein, 010606 plant biology & botany

Abstract

The broad distribution of quinoa in saline and non-saline environments is reflected in variations in the photosynthesis-associated mechanisms of different ecotypes. The aim of this study was to characterize the photosynthetic response to high salinity (0.4 M NaCl) of two contrasting Chilean genotypes, Amarilla (salt-tolerant, salares ecotype) and Hueque (salt-sensitive, coastal ecotype). Our results show that saline stress induced a significant decrease in the K+/Na+ ratio in roots and an increase in glycine betaine in leaves, particularly in the sensitive genotype (Hueque). Measurement of the photosynthesis-related parameters showed that maximum CO2 assimilation (Amax) in control plants was comparable between genotypes (ca. 9–10 μmol CO2 m−2 s−1). However, salt treatment produced different responses, with Amax values decreasing by 65.1% in the sensitive ecotype and 37.7% in the tolerant one. Although both genotypes maintained mesophyll conductance when stomatal restrictions were removed, the biochemical components of Amarilla were impaired to a lesser extent under salt stress conditions: for example, the maximum rate of ribulose-1,5-bisphosphate carboxylase/oxygenase (RubisCO, Vcmax) was not as affected in Amarilla, revealing that this enzyme has a higher affinity for its substrate in this genotype and, thus, a better carboxylation efficiency. The present results show that the higher salinity tolerance of Amarilla was also due to its ability to control non-diffusional components, indicating its superior photosynthetic capacity compared to Hueque, particularly under salt stress conditions.

Published

2021

8. Pulsed led light: Exploring the balance between energy use and nutraceutical properties in indoor-grown lettuce

Author

Fabiana Antognoni, Francesco Orsini, Giuseppina Pennisi, Giorgio Gianquinto, Giulia Potente, Karina B. Ruiz, Laura Carotti, Andrea Crepaldi, Stefania Biondi, Carotti L., Potente G., Pennisi G., Ruiz K.B., Biondi S., Crepaldi A., Orsini F., Gianquinto G., and Antognoni F.

Subjects

0106 biological sciences, Antioxidative enzyme, Phenolic compound, Biomass, Lactuca, LED lighting, phenolic compounds, antioxidative enzymes, Lettuce (Lactuca sativa), 01 natural sciences, 7. Clean energy, law.invention, 03 medical and health sciences, Pulsed light, law, Indoor farming, Food science, Water-use efficiency, lettuce (Lactuca sativa), 030304 developmental biology, photoperiodism, 0303 health sciences, Hydroponic, biology, Chemistry, Agriculture, hydroponics, 15. Life on land, biology.organism_classification, Hydroponics, Antioxidant capacity, LED lamp, Light intensity, flavonoids, Flavonoid, Gene expression, Agronomy and Crop Science, 010606 plant biology & botany, Light-emitting diode

Abstract

In indoor vertical farms, energy consumption represents a bottleneck for both a system’s affordability and environmental footprint. Although switching frequency (sf) represents a crucial factor in determining the efficacy of light emitting diodes (LED) lighting systems in converting electricity into light, the impact of sf is still underexplored. The aim of this work was to investigate the effect of LEDs sf on the productive and qualitative responses of lettuce (Lactuca sativa L.), also considering the resource use efficiency. Plants were grown for 14 days under red and blue LEDs (215 μmol m−2 s−1 and 16/8 h light/dark, with a red:blue ratio of 3) characterized by two different sf for the blue diode, namely high sf (850 kHz) and low sf (293 kHz). A fluorescent light (same light intensity and photoperiod) was included. LED sf did not alter plant morphological parameters, including fresh or dry biomass, leaf number, leaf area, or water use efficiency. A low sf increased the energy use efficiency (EUE) by 40% as compared to high sf. The latter enhanced the leaf antioxidant capacity, as a consequence of increased concentrations of caftaric and chicoric acids, isoquercetin, and luteolin, consistent with the upregulation of a few genes related to the biosynthetic pathway of phenolic compounds (4C3H and DFR). The study highlights that different sf may significantly affect the EUE as well as crop nutritional properties.

Published

2021

9. Quinoa seed coats as an expanding and sustainable source of bioactive compounds: An investigation of genotypic diversity in saponin profiles

Author

Sven-Erik Jacobsen, Bekzod Khakimov, Karina B. Ruiz, Stefania Biondi, Søren Bak, Søren B. Engelsen, Ruiz, Karina B., Khakimov, Bekzod, Engelsen, Søren B., Bak, Sã¸ren, Biondi, Stefania, and Jacobsen, Sven-Erik

Subjects

Seed coat, 0106 biological sciences, Triterpenoid, Saponin, Biology, 01 natural sciences, Chenopodium quinoa, chemistry.chemical_compound, Nutraceutical, Quinoa waste-product, Sugar, Oleanolic acid, chemistry.chemical_classification, business.industry, 010401 analytical chemistry, 0104 chemical sciences, Biotechnology, Hederagenin, Biopesticide, Aglycone, chemistry, business, Agronomy and Crop Science, 010606 plant biology & botany

Abstract

Saponins (SAPs) are a diverse family of plant secondary metabolites and due to their biological activities, SAPs can be utilised as biopesticides and as therapeutic compounds. Given their widespread industrial use, a search for alternative sources of SAPs is a priority. Quinoa ( Chenopodium quinoa Willd) is a valuable food source that is gaining importance worldwide for its nutritional and nutraceutical properties. SAPs from quinoa seed coats could represent a new sustainable source to obtain these compounds in high quantities due to the increasing production and worldwide expansion of the crop. This research aims to characterise saponins of seed coat waste products from six different quinoa varieties for their potential use as a saponin source. Gas chromatography (GC)- and Liquid chromatography (LC)- with mass spectrometry (MS) were applied for qualitative and relative quantitative analysis of saponins. GC–MS led to the identification of three main aglycones, oleanolic acid (Ole), hederagenin (Hed), and a phytolaccagenic acid (Phy), while LC–MS enabled characterization of 24 SAPs with varying sugar moieties. Hed was the most abundant aglycone, followed by Phy and Oledepending on the genotype. Saponin distribution and relative abundances are discussed in the light of genotype provenance and agronomic features. Improved knowledge on the phytochemicals present in quinoa varieties might help in finding valuable and sustainable uses for quinoa SAPs in agroindustry as biopesticides as well as in the production of food and pharmaceuticals.

Published

2017

10. Comparing salt-induced responses at the transcript level in a salares and coastal-lowlands landrace of quinoa (Chenopodium quinoa Willd)

Author

Karina B. Ruiz, Francesca Rapparini, Herman Silva, Stefania Biondi, Patrizia Torrigiani, G. Bertazza, Ruiz, Karina B., Rapparini, Francesca, Bertazza, Gianpaolo, Silva, Herman, Torrigiani, Patrizia, and Biondi, Stefania

Subjects

0106 biological sciences, 0301 basic medicine, Polyamine, Halophyte, Plant Science, Biology, 01 natural sciences, Chenopodium quinoa, Abscisic acid, 03 medical and health sciences, chemistry.chemical_compound, Salt stre, Botany, Ecology, Evolution, Behavior and Systematics, Ecotype, biology.organism_classification, Ecology, Evolution, Behavior and Systematic, Salinity, 030104 developmental biology, Ion homeostasis, chemistry, Seedling, Quinoa, Shoot, Gene expression, Ion transporter, Agronomy and Crop Science, 010606 plant biology & botany

Abstract

To further our understanding of the mechanisms governing salt stress responses and adaptation in halophytes, we explored morphological, metabolic, and gene expression responses to high salinity in quinoa (Chenopodium quinoa Willd). The main objective of this study was to analyze selected responsive genes in a time-course experiment to test for expression kinetics and to compare short-term salt-induced effects at the transcript level between two Chilean landraces belonging to different ecotypes. Quinoa genotypes exhibit a large variability in their responses to salinity, but it is not clear whether this is strictly related to the ecotype to which they belong. We tested this hypothesis by comparing the expression levels of genes involved in growth, ion homeostasis, abscisic acid (ABA) biosynthesis, perception, and conjugate cleavage, polyamine (PA) biosynthesis and oxidation, and proline biosynthesis as well as genes encoding ABA-dependent and −independent transcription factors. Landraces R49 (salares ecotype) and Villarrica (VR, coastal-lowlands ecotype) were analyzed from 0.5 to 120Âh after transfer to saline (300ÂmM NaCl) or non-saline (control) medium. All the genes, except CqSOS1 and CqNHX, were investigated here for the first time in quinoa under salt stress. Transcript levels were determined by quantitative Reverse Transcription-Polymerase Chain Reaction (qRT-PCR) analysis. Germination, seedling growth, ABA, and PA contents were evaluated in parallel. Even though on saline medium germination was inhibited in VR but not in R49, seedling growth reduction at 120Âh was not substantially different in the two landraces. The ABA biosynthetic enzyme NCED was the most strongly salt-induced gene; ABA content was similarly enhanced (shoots) or unaffected (roots) in both R49 and VR. NaCl treatment also altered transcript levels of some PA metabolic enzymes and the PA profile leading to an enhanced ratio between the higher PAs and putrescine. All other genes also exhibited similar expression profiles in response to salinity in the two landraces especially in roots, while in shoots some differences were observed. Our results provide new information indicating that crucial salt adaptation strategies at the molecular level and in terms of ABA and PA contents are shared by the coastal-lowlands and salares landraces; however, the timing of the onset of transcriptional changes (e.g., NCED, ABF3, and RD22) may reflect genotype-dependent constitutive and/or inducible adaptive strategies.

Published

2017

11. The combined effect of Cr(III) and NaCl determines changes in metal uptake, nutrient content, and gene expression in quinoa (Chenopodium quinoa Willd.)

Author

Karina B. Ruiz, Stefania Biondi, Angela Cicatelli, Stefano Castiglione, Francesco Guarino, Guarino F., Ruiz K.B., Castiglione S., Cicatelli A., and Biondi S.

Subjects

Chromium, Salinity, Soil salinity, Proline, Osmotic shock, Iron, Health, Toxicology and Mutagenesis, Halophyte, 0211 other engineering and technologies, Gene Expression, Tocopherols, chemistry.chemical_element, 02 engineering and technology, Sodium Chloride, 010501 environmental sciences, Plant Roots, 01 natural sciences, Chenopodium quinoa, Stress, Physiological, Soil Pollutants, 0105 earth and related environmental sciences, Ions, Stress-responsive genes, 021110 strategic, defence & security studies, Chemistry, Phosphorus, Sodium, Public Health, Environmental and Occupational Health, Biological Transport, Salt-Tolerant Plants, General Medicine, Pollution, Phytoremediation, Plant Leaves, Horticulture, Biodegradation, Environmental, Lead, Quinoa, Phytochelatin, Sulfur

Abstract

Many areas of the world are affected simultaneously by salinity and heavy metal pollution. Halophytes are considered as useful candidates in remediation of such soils due to their ability to withstand both osmotic stress and ion toxicity deriving from high salt concentrations. Quinoa (Chenopodium quinoa Willd) is a halophyte with a high resistance to abiotic stresses (drought, salinity, frost), but its capacity to cope with heavy metals has not yet been fully investigated. In this pot experiment, we investigated phytoextraction capacity, effects on nutrient levels (P and Fe), and changes in gene expression in response to application of Cr(III) in quinoa plants grown on saline or non-saline soil. Plants were exposed for three weeks to 500 mg kg−1 soil of Cr(NO3)3·9H2O either in the presence or absence of 150 mM NaCl. Results show that plants were able tolerate this soil concentration of Cr(III); the metal was mainly accumulated in roots where it reached the highest concentration (ca. 2.6 mg g−1 DW) in the presence of NaCl. On saline soil, foliar Na concentration was significantly reduced by Cr(III). Phosphorus translocation to leaves was reduced in the presence of Cr(III), while Fe accumulation was enhanced by treatment with NaCl alone. A real-time RT-qPCR analysis was conducted on genes encoding for sulfate, iron, and phosphate transporters, a phytochelatin, a metallothionein, glutathione synthetase, a dehydrin, Hsp70, and enzymes responsible for the biosynthesis of proline (P5CS), glycine betaine (BADH), tocopherols (TAT), and phenolic compounds (PAL). Cr(III), and especially Cr(III)+NaCl, affected transcript levels of most of the investigated genes, indicating that tolerance to Cr is associated with changes in phosphorus and sulfur allocation, and activation of stress-protective molecules. Moderately saline conditions, in most cases, enhanced this response, suggesting that the halophytism of quinoa could contribute to prime the plants to respond to chromium stress.

Published

2020

12. New Insight into Quinoa Seed Quality under Salinity: Changes in Proteomic and Amino Acid Profiles, Phenolic Content, and Antioxidant Activity of Protein Extracts

Author

Giampiero Cai, Claudia Landi, Stefania Biondi, Luca Bini, Iris Aloisi, Karina B. Ruiz, Stefano Del Duca, Luigi Parrotta, Aloisi, Iri, Parrotta, Luigi, Ruiz, KARINA BEATRIZ, Landi, Claudia, Bini, Luca, Cai, Giampiero, Biondi, Stefania, and DEL DUCA, Stefano

Subjects

Polyphenol, 0106 biological sciences, 0301 basic medicine, Hydrolyzed protein, Seed storage protein, Globulin, seed storage proteins, Plant Science, lcsh:Plant culture, Biology, 01 natural sciences, Chenopodium quinoa, 03 medical and health sciences, Antioxidant activity, Salt stre, Storage protein, lcsh:SB1-1110, Amino Acids, polyphenols, Original Research, salt stress, chemistry.chemical_classification, Albumin, Polyphenols, Salt stress, Seed storage proteins, Amino acid, Salinity, 030104 developmental biology, chemistry, Biochemistry, biology.protein, 010606 plant biology & botany

Abstract

Quinoa (Chenopodium quinoa Willd) is an ancient Andean seed-producing crop well known for its exceptional nutritional properties and resistance to adverse environmental conditions, such as salinity and drought. Seed storage proteins, amino acid composition, and bioactive compounds play a crucial role in determining the nutritional value of quinoa. Seeds harvested from three Chilean landraces of quinoa, one belonging to the salares ecotype (R49) and two to the coastal-lowlands ecotype, VI-1 and Villarrica (VR), exposed to two levels of salinity (100 and 300 mM NaCl) were used to conduct a sequential extraction of storage proteins in order to obtain fractions enriched in albumins/globulins, 11S globulin and in prolamin-like proteins. The composition of the resulting protein fractions was analyzed by one- and two-dimensional polyacrylamide gel electrophoresis. Results confirmed a high polymorphism in seed storage proteins; the two most representative genotype-specific bands of the albumin/globulin fraction were the 30- and 32-kDa bands, while the 11S globulin showed genotype-specific polymorphism for the 40- and 42-kDa bands. Spot analysis by mass spectrometry followed by in silico analyses were conducted to identify the proteins whose expression changed most significantly in response to salinity in VR. Proteins belonging to several functional categories (i.e., stress protein, metabolism, and storage) were affected by salinity. Other nutritional and functional properties, namely amino acid profiles, total polyphenol (TPC) and flavonoid (TFC) contents, and antioxidant activity (AA) of protein extracts were also analyzed. With the exception of Ala and Met in R49, all amino acids derived from protein hydrolysis were diminished in seeds from salt-treated plants, especially in landrace VI-1. By contrast, several free amino acids were unchanged or increased by salinity in R49 as compared with VR and VI-1, suggesting a greater tolerance in the salares landrace. VR had the highest TPC and AA under non-saline conditions. Salinity increased TPC in all three landraces, with the strongest increase occurring in R49, and enhanced radical scavenging capacity in R49 and VR. Overall, results show that salinity deeply altered the seed proteome and amino acid profiles and, in general, increased the concentration of bioactive molecules and AA of protein extracts in a genotype-dependent manner.

Published

2016

13. Oxidative stress and antioxidant responses to increasing concentrations of trivalent chromium in the Andean crop species Chenopodium quinoa Willd

Author

Anahi Bucchini, Marta Iacobucci, Valeria Scoccianti, Karina B. Ruiz, Stefania Biondi, Scoccianti, Valeria, Bucchini, Anahi E., Iacobucci, Marta, Ruiz, Karina B., Biondi, Stefania, DIPARTIMENTO DI SCIENZE BIOLOGICHE, GEOLOGICHE E AMBIENTALI, Facolta' di SCIENZE MATEMATICHE FISICHE e NATURALI, and AREA MIN. 05 - Scienze biologiche

Subjects

0106 biological sciences, Chromium, Polyamine, Antioxidant, DPPH, Chenopodium quinoa, Oxidative stress, Polyamines, Tocopherols, Tyrosine aminotransferase, Health, Toxicology and Mutagenesis, Public Health, Environmental and Occupational Health, Pollution, medicine.medical_treatment, 010501 environmental sciences, medicine.disease_cause, 01 natural sciences, Plant Roots, Antioxidants, chemistry.chemical_compound, Food science, Photosynthesis, Hydrogen peroxide, Tocopherol, Plant Stems, Chemistry, food and beverages, General Medicine, Health, Seeds, Public Health, Oxidation-Reduction, Chenopodium quinoa, Chromium, Oxidative stress, Polyamines, Tocopherols, Tyrosine aminotransferase, Proline, Botany, medicine, Toxicology and Mutagenesis, 0105 earth and related environmental sciences, Tyrosine Transaminase, Flavonoids, Dose-Response Relationship, Drug, Abiotic stress, Environmental and Occupational Health, Polyphenols, Hydrogen Peroxide, Health, Toxicology and Mutagenesi, Plant Leaves, Oxidative Stress, Oxidative stre, Lipid Peroxidation, 010606 plant biology & botany

Abstract

none 5 no This research was supported by funds from the University of Bologna (RFO2014) to S.B.and from the University of Urbino (RFO 2014) to V.S.. Quinoa (Chenopodium quinoa Willd), an ancient Andean seed crop, exhibits exceptional nutritional properties and resistance to abiotic stress. The species' tolerance to heavy metals has, however, not yet been investigated nor its ability to take up and translocate chromium (Cr). This study aimed to investigate the metabolic adjustments occurring upon exposure of quinoa to several concentrations (0.01–5mM) of CrCl3. Young hydroponically grown plants were used to evaluate Cr uptake, growth, oxidative stress, and other biochemical parameters three and/or seven days after treatment. Leaves accumulated the lowest amounts of Cr, while roots and stems accumulated the most at low and at high metal concentrations, respectively. Fresh weight and photosynthetic pigments were reduced only by the higher Cr(III) doses. Substantially increased lipid peroxidation, hydrogen peroxide, and proline levels were observed only with 5mM Cr(III). Except for a significant decrease at day 7 with 5mM Cr(III), total polyphenols and flavonoids maintained control levels in Cr(III)-treated plants, whereas antioxidant activity increased in a dose-dependent manner. Maximum polyamine accumulation was observed in 1mM CrCl3-treated plants. Even though α- and γ-tocopherols also showed enhanced levels only with the 1mM concentration, tyrosine aminotransferase (TAT, EC 2.6.1.5) activity increased under Cr(III) treatment in a dose- and time-dependent manner. Taken together, results suggest that polyamines, tocopherols, and TAT activity could contribute to tolerance to 1mM Cr(III), but not to the highest concentration that, instead, generated oxidative stress. open Scoccianti, Valeria; Bucchini, Anahi E.; Iacobucci, Marta; Ruiz, Karina B.; Biondi, Stefania Scoccianti, Valeria; Bucchini, Anahi E.; Iacobucci, Marta; Ruiz, Karina B.; Biondi, Stefania

Published

2016

14. Differential expression of allene oxide synthase (AOS), and jasmonate relationship with ethylene biosynthesis in seed and mesocarp of developing peach fruit

Author

Guglielmo Costa, Satoru Kondo, Karina B. Ruiz, Vanina Ziosi, Patrizia Torrigiani, Fabio Fregola, P. Torrigiani, F. Fregola, V. Ziosi, K.B. Ruiz, S. Kondo, and G. Costa

Subjects

EMBRYO DEVELOPMENT, METHYL JASMONATE, Ethylene, Methyl jasmonate, Jasmonic acid, food and beverages, Ripening, Embryo, ETHYLENE BIOSYNTHESIS, Horticulture, Biology, chemistry.chemical_compound, Prunus, chemistry, Biosynthesis, PAECH FRUIT, Botany, AOS, Jasmonate, Agronomy and Crop Science, Food Science

Abstract

To better understand the physiological role of jasmonates (JAs) during fruit development and ripening, and relationships with ethylene, the time course of transcript accumulation of the key enzyme in JA biosynthesis, allene oxide synthase (AOS), was analyzed during S1–S4 fruit developmental stages, until ripening, in the mesocarp and seed of peach ( Prunus persica var. laevis Gray), cv. ‘Stark Red Gold’. In the mesocarp, transcript amounts of PpAOS1 were the highest in S1–S2, then decreased to almost undetectable levels at the transition S3/S4, to rise slightly at harvest. In parallel, JA concentration was measured in the mesocarp during development; maximum jasmonic acid accumulation was observed in S1, the lowest levels in S2 and S3 and a new rise in S4. In the seed, an AOS1 transcript was detected whose accumulation differed in the embryo as compared to cotyledons during seed growth. The reciprocal JA/ethylene relationships were investigated in fruit at different physiological stages by exogenously supplying methyl jasmonate (MJ). The effects of treatments with 0.88 mM MJ on transcript levels of PpAOS1 and ethylene biosynthetic genes PpACS1 , PpACO1 and PpACO2 were evaluated in the mesocarp and seed of detached nectarines at an early (S1) and late (S4) developmental stage. Results show that JA biosynthesis appears to be developmentally regulated in seed and mesocarp of nectarine fruit and that the response to MJ depends upon the fruit physiological stage.

Published

2012

15. Salares versus coastal ecotypes of quinoa: Salinity responses in Chilean landraces from contrasting habitats

Author

Iris Aloisi, Karina B. Ruiz, Valentina Canelo, Herman Silva, Stefano Del Duca, Patrizia Torrigiani, Stefania Biondi, Ruiz, KARINA BEATRIZ, Aloisi, Iri, DEL DUCA, Stefano, Canelo, Valentina, Torrigiani, Patrizia, Silva, Herman, and Biondi, Stefania

Subjects

Polyphenol, 0106 biological sciences, 0301 basic medicine, Salinity, Physiology, Growth, Plant Science, Sodium Chloride, 01 natural sciences, Chenopodium quinoa, Plant Roots, 03 medical and health sciences, chemistry.chemical_compound, Genetic, Gene Expression Regulation, Plant, Genetics, Extreme environment, Adaptation, Chile, Ecosystem, Plant Proteins, Ecotype, biology, food and beverages, Plant physiology, biology.organism_classification, Plant Leaves, 030104 developmental biology, chemistry, Agronomy, Seed quality/protein, Seedling, Germination, Chlorophyll, 010606 plant biology & botany

Abstract

Quinoa (Chenopodium quinoa Willd.) is a highly salt-tolerant species subdivided into five ecotypes and exhibiting broad intra-specific differences in tolerance levels. In a greenhouse study, Chilean landraces belonging either to the salares (R49) or coastal lowlands (VI-1, Villarrica) ecotype with contrasting agro-ecological origins were investigated for their responses to high salinity. The effects of two levels of salinity, 100 (T1) and 300 (T2) mM NaCl, on plant growth and on some physiological parameters were measured. Leaf and root Na(+) accumulation differed among landraces. T2 reduced growth and seed yield in all landraces with maximum inhibition relative to controls in R49. Salinity negatively affected chlorophyll and total polyphenol content (TPC) in VI-1 and Villarrica but not R49. Germination on saline or control media of seeds harvested from plants treated or not with NaCl was sometimes different; the best performing landrace was R49 insofar as 45-65% of seeds germinated on 500 mM NaCl-containing medium. In all landraces, average seedling root length declined strongly with increasing NaCl concentration, but roots of R49 were significantly longer than those of VI-1 and Villarrica up to 300 mM NaCl. Salt caused increases in seed TPC relative to controls, but radical scavenging capacity was higher only in seeds from T2 plants of R49. Total SDS-extractable seed proteins were resolved into distinct bands (10-70 kDa) with some evident differences between landraces. Salt-induced changes in protein patterns were landrace-specific. The responses to salinity of the salares landrace are discussed in relation to its better adaptation to an extreme environment.

Published

2015

16. Corrigendum to 'Comparing salt-induced responses at the transcript level in a salares and coastal-lowlands landrace of quinoa (Chenopodium quinoa Willd)' [Environ. Exp. Bot. 139 (2017) 127–142]

Author

G. Bertazza, Herman Silva, Karina B. Ruiz, Stefania Biondi, Patrizia Torrigiani, and Francesca Rapparini

Subjects

Botany, Plant Science, Transcript level, Biology, Agronomy and Crop Science, Chenopodium quinoa, Ecology, Evolution, Behavior and Systematics

Published

2017

17. Quinoa biodiversity and sustainability for food security under climate change. A review

Author

Rómulo Oses, Fabiana Antognoni, Marco A. Molina-Montenegro, Ian S. Acuña-Rodríguez, Didier Bazile, Milton Pinto, Enrique A. Martinez-Mosqueira, Karina B. Ruiz, Stefania Biondi, Alipio Canahua-Murillo, Andrés Zurita-Silva, Amadou Coulibaly, Sven-Erik Jacobsen, RUIZ K. B., BIONDI S., OSES R., ACUÑA-RODRÍGUEZ I. S., ANTOGNONI F., MARTINEZ-MOSQUEIRA E.A., COULIBALY A., CANAHUA-MURILLO A., PINTO M., ZURITA-SILVA A., BAZILE D., JACOBSEN S.-E., and MOLINA-MONTENEGRO M.A.

Subjects

[SDV.SA]Life Sciences [q-bio]/Agricultural sciences, PLANT ABIOTIC STRESS, QUINOA, Biodiversity, Stress tolerance, Ecosystem services, F30 - Génétique et amélioration des plantes, E14 - Économie et politique du développement, F01 - Culture des plantes, Tolérance au sel, Chenopodium quinoa, 2. Zero hunger, [SDV.EE]Life Sciences [q-bio]/Ecology, environment, education.field_of_study, Food security, Ecology, Agroforestry, FOOD SECURITY, food and beverages, Geography, sécurité alimentaire, Sustainability, Agroécosystème, Diversification, Environmental Engineering, P40 - Météorologie et climatologie, F60 - Physiologie et biochimie végétale, Population, Petite exploitation agricole, Variation génétique, education, Agroecology, Changement climatique, business.industry, E80 - Économie familiale et artisanale, 15. Life on land, Valeur nutritive, Agrobiodiversity, Résistance à la sécheresse, 13. Climate action, Agriculture, Développement durable, Agricultural biodiversity, business, Agronomy and Crop Science, Andean farmers, Food quality

Abstract

International audience; Climate change is rapidly degrading the conditions of crop production. For instance, increasing salinization and aridity is forecasted to increase in most parts of the world. As a consequence, new stress-tolerant species and genotypes must be identified and used for future agriculture. Stress-tolerant species exist but are actually underutilized and neglected. Many stress-tolerant species are indeed traditional crops that are only cultivated by farmers at a local scale. Those species have a high biodiversity value. Besides, the human population will probably reach nine billion within coming decades. To keep pace with population growth, food production must increase dramatically despite the limited availability of cultivable land and water. Here, we review the benefits of quinoa, Chenopodium quinoa Willd., a seed crop that has endured the harsh bioclimatic conditions of the Andes since ancient times. Although the crop is still mainly produced in Bolivia and Peru, agronomic trials and cultivation are spreading to many other countries. Quinoa maintains productivity on rather poor soils and under conditions of water shortage and high salinity. Moreover, quinoa seeds are an exceptionally nutritious food source, owing to their high protein content with all essential amino acids, lack of gluten, and high content of several minerals, e.g., Ca, Mg, Fe, and health-promoting compounds such as flavonoids. Quinoa has a vast genetic diversity resulting from its fragmented and localized production over the centuries in the Andean region, from Ecuador to southern Chile, and from sea level to the altiplano. Quinoa can be adapted to diverse agroecological conditions worldwide. Year 2013 has therefore been declared the International Year of Quinoa by the United Nations Food and Agriculture Organization. Here, we review the main characteristics of quinoa, its origin and genetic diversity, its exceptional tolerance to drought and salinity, its nutritional properties, the reasons why this crop can offer several ecosystem services, and the role of Andean farmers in preserving its agrobiodiversity. Finally, we propose a schematic model integrating the fundamental factors that should determine the future utilization of quinoa, in terms of food security, biodiversity conservation, and cultural identity.

Published

2014

18. PpeTAC1 promotes the horizontal growth of branches in peach trees and is a member of a functionally conserved gene family found in diverse plants species

Author

Ann M. Callahan, Courtney A. Hollender, Chris Dardick, Karina B. Ruiz, Ralph Scorza, Renate Horn, Michael Whitaker, Tetyana Zhebentyayeva, and Albert G. Abbott

Subjects

Candidate gene, Hypothetical protein, Mutant, Molecular Sequence Data, Arabidopsis, Plant Science, Flowers, Trees, Evolution, Molecular, Gene Expression Regulation, Plant, Botany, Genetics, Gene family, Gene, Phylogeny, Plant Proteins, Oryza sativa, biology, Base Sequence, food and beverages, Chromosome Mapping, Oryza, Cell Biology, Sequence Analysis, DNA, biology.organism_classification, Plants, Genetically Modified, Phenotype, Evolutionary biology, Organ Specificity, Multigene Family, Mutation, Prunus, Polar auxin transport, Carrier Proteins, Genome, Plant, Plant Shoots

Abstract

†SUMMARY Trees are capable of tremendous architectural plasticity, allowing them to maximize their light exposure under highly competitive environments. One key component of tree architecture is the branch angle, yet little is known about the molecular basis for the spatial patterning of branches in trees. Here, we report the identification of a candidate gene for the br mutation in Prunus persica (peach) associated with vertically oriented growth of branches, referred to as ‘pillar’ or ‘broomy’. Ppa010082, annotated as hypothetical protein in the peach genome sequence, was identified as a candidate gene for br using a next generation sequence-based mapping approach. Sequence similarity searches identified rice TAC1 (tiller angle control 1) as a putative ortholog, and we thus named it PpeTAC1. In monocots, TAC1 is known to lead to less compact growth by increasing the tiller angle. In Arabidopsis, an attac1 mutant showed more vertical branch growth angles, suggesting that the gene functions universally to promote the horizontal growth of branches. TAC1 genes belong to a gene family (here named IGT for a shared conserved motif) found in all plant genomes, consisting of two clades: one containing TAC1-like genes; the other containing LAZY1, which contains an EAR motif, and promotes vertical shoot growth in Oryza sativa (rice) and Arabidopsis through influencing polar auxin transport. The data suggest that IGT genes are ancient, and play conserved roles in determining shoot growth angles in plants. Understanding how IGT genes modulate branch angles will provide insights into how different architectural growth habits evolved in terrestrial plants.

Published

2013

19. Early Methyl Jasmonate Application to Peach Delays Fruit/Seed Development by Altering the Expression of Multiple Hormone-Related Genes

Author

Livio Trainotti, Guglielmo Costa, Claudio Bonghi, Vanina Ziosi, Patrizia Torrigiani, Karina B. Ruiz, Karina Beatriz Ruiz, Livio Trainotti, Claudio Bonghi, Vanina Ziosi, Guglielmo Costa, and Patrizia Torrigiani

Subjects

Prunus persica, Ethylene, Methyl jasmonate, Seed, Fruit development, Plant physiology, food and beverages, Ripening, Plant Science, Quantitative RT-PCR, Biology, chemistry.chemical_compound, Prunus, chemistry, Downregulation and upregulation, Botany, Gene expression, Agronomy and Crop Science, Gene

Abstract

Jasmonates (JAs) play a role in the responses to environmental stress and during growth processes, including fruit/seed development. To better understand the molecular basis of the developmental control exerted by JAs in fruit and seed, methyl jasmonate (MJ, 0.80 mM) was applied to peach fruit (Prunus persica var. laevis Gray) at an early (S1) developmental stage and under field conditions. Mesocarp and seed were sampled at time intervals until ripening; at harvest, MJ-treated fruit were less ripe than controls as assessed by a nondestructive device called a DA-meter. Real-time reverse-transcription polymerase chain reaction analyses revealed that JA-related gene expression (AOS1 and JAZs) was affected early (24 h) after treatment, whereas peaks in transcript accumulation of mesocarp (CYCD3, RD22, SP, Aux/IAA) and seed (PRP, SSADH, PRU, LEA) developmental marker genes were shifted in accord with a developmental slowing down. At ripening (S4), in the mesocarp the upregulation of the ethylene biosynthetic genes ACO1 and ACS1 and of the softening-related genes PG and EXP2 was dramatically counteracted by MJ. Ethylene signaling (ETR1, ETR2) was also affected. Because JAs cross-talk with other hormones, the transcript amounts of major hormone-related genes such as GH3, IAA-AH, NCED, and GA2ox were evaluated and showed changes that further support the hypothesis of delay of the developmental program.

Published

2013

20. ABA may promote or delay peach fruit ripening through modulation of ripening- and hormone-related gene expression depending on the developmental stage

Author

Guglielmo Costa, Alvaro Soto, Daniela Ravaglia, Patrizia Torrigiani, Karina B. Ruiz, A. Soto, K.B. Ruiz, D. Ravaglia, G. Costa, and P. Torrigiani

Subjects

Ethylene, Physiology, Gene Expression, Plant Science, AUXIN, Biology, Genes, Plant, Real-Time Polymerase Chain Reaction, ABSCISIC ACID, FRUIT RIPENING, chemistry.chemical_compound, Prunus, Plant Growth Regulators, Auxin, Cell Wall, Gene Expression Regulation, Plant, Gene expression, Genetics, Abscisic acid, Gene, PEACH, chemistry.chemical_classification, Regulation of gene expression, Indoleacetic Acids, food and beverages, Ripening, Ethylenes, ETHYLENE, Cell biology, chemistry, Biochemistry, Fruit, Signal Transduction

Abstract

Peach (Prunus persica laevis L. Batsch) was chosen as a model to further clarify the physiological role of ABA during fruit ripening. To this aim, branches bearing one fruit at mid-S3, S3/S4 and S4 stages of fruit development and characterized by a different ripening index (IAD), as revealed by a non-destructive device called a DA-meter, were treated with ABA (0.02 mM) for 1 and 5 days. Exogenously applied ABA interfered with the progression of ripening leading to less ripe or riper fruit depending on the physiological stage. To better understand the molecular basis of ABA interference with ripening, the time-course changes in the expression of ethylene-, cell wall-, and auxin-related genes as well as other genes (NCED, PIP, LOX, AOS and SOT) was evaluated in the fruit mesocarp. Real-time PCR analyses revealed that in mid-S3 fruit transcript levels of ethylene biosynthesis and signaling (ACS1, ACO1, ETR2, ERF2), cell wall softening-related (PG, PMEI, EXP1, EXP2) and auxin biosynthesis, conjugation, transport and perception (TRPB, IGPS, Aux/IAA, GH3, PIN1 and TIR1) genes were substantially down-regulated on day 5 indicating a ripening delay. On the contrary, in more advanced stages (S3/S4 and S4) the same genes were early (day 1) up-regulated suggesting an acceleration of ripening. Transcript profiling of other ripening-related genes revealed changes that were in accord with a ripening delay (mid-S3) or acceleration (S3/S4 and S4). Thus, in peach fruit, ABA appears to modulate ripening through interference not only with ethylene and cell wall but also with auxin-related genes.

Published

2013

21. Ethylene and auxin biosynthesis and signaling are impaired by methyl jasmonate leading to a transient slowing down of ripening in peach fruit

Author

Guglielmo Costa, Alvaro Soto, Karina B. Ruiz, Patrizia Torrigiani, Vanina Ziosi, A. Soto, K.B. Ruiz, V. Ziosi, G. Costa, and P. Torrigiani

Subjects

METHYL JASMONATE, Ethylene, Time Factors, Physiology, PRUNUS PERSICA, Down-Regulation, AUXIN, Plant Science, Cyclopentanes, Biology, Acetates, Real-Time Polymerase Chain Reaction, FRUIT RIPENING, chemistry.chemical_compound, Auxin, Cell Wall, Gene Expression Regulation, Plant, Oxylipins, RNA, Messenger, Gene, Transcription factor, Plant Proteins, chemistry.chemical_classification, Regulation of gene expression, Methyl jasmonate, Indoleacetic Acids, Gene Expression Profiling, food and beverages, Ripening, Ethylenes, ETHYLENE, Up-Regulation, Gene expression profiling, Biochemistry, chemistry, RNA, Plant, Seedlings, Fruit, Prunus, Agronomy and Crop Science, Signal Transduction

Abstract

Peach (Prunus persica) was chosen as a model to further clarify the physiological role of jasmonates (JAs) during fruit ripening. To this aim, the effect of methyl jasmonate (MJ, 0.88 mM), applied at a late stage (S3) of fruit development under field conditions (in planta), on the time-course of fruit ripening over a 14-day period was evaluated. As revealed by a non-destructive device called a DA-meter, exogenously applied MJ impaired the progression of ripening leading to less ripe fruit at harvest. To better understand the molecular basis of MJ interference with ripening, the time-course changes in the expression of ethylene-, cell wall-, and auxin-related genes as well as other genes (LOX, AOS and bZIP) was evaluated in the fruit mesocarp. Real-time PCR analyses revealed that transcript levels of ethylene-related genes were strongly affected. In a first phase (days 2 and/or 7) of the MJ response, mRNAs of the ethylene biosynthetic genes ACO1, ACS1 and the receptor gene ETR2 were strongly but transiently down-regulated, and then returned to or above control levels in a second phase (days 11 and/or 14). Auxin biosynthetic, conjugating, transport and perception gene transcripts were also affected. While biosynthetic genes (TRPB and IGPS) were up-regulated, auxin-conjugating (GH3), perception (TIR1) and transport (PIN1) genes were transiently but strongly down-regulated in a first phase, but returned to control levels subsequently. Transcript levels of two JA-related genes (LOX, AOS) and a developmentally regulated transcription factor (bZIP) were also affected, suggesting a shift ahead of the ripening process. Thus, in peach fruit, the transient slowing down of ripening by exogenous MJ was associated with an interference not only with ethylene but also with auxin-related genes.

Published

2012

22. Spermidine application to young developing peach fruits leads to a slowing down of ripening by impairing ripening-related ethylene and auxin metabolism and signaling

Author

Guglielmo Costa, Livio Trainotti, Alice Tadiello, Karina B. Ruiz, Daniela Bressanin, Claudio Bonghi, Patrizia Torrigiani, Vanina Ziosi, P. Torrigiani, D. Bressanin, K. Ruiz Carrasco, A. Tadiello, L. Trainotti, C. Bonghi, V. Ziosi, and G. Costa

Subjects

PEACH RIPENING, GENE EXPRESSION, Ethylene, Physiology, fruit ripening, Plant Science, AUXIN, Biology, Genes, Plant, chemistry.chemical_compound, Prunus, Downregulation and upregulation, Plant Growth Regulators, Auxin, Gene Expression Regulation, Plant, Gene expression, spermidine, Genetics, ethylene, chemistry.chemical_classification, Regulation of gene expression, Indoleacetic Acids, food and beverages, Ripening, Cell Biology, General Medicine, Ethylenes, Spermidine, Horticulture, chemistry, Biochemistry, Fruit, Signal Transduction

Abstract

Peach (Prunus persica var. laevis Gray) was chosen to unravel the molecular basis underlying the ability of spermidine (Sd) to influence fruit development and ripening. Field applications of 1 mM Sd on peach fruit at an early developmental stage, 41 days after full bloom (dAFB), i.e. at late stage S1, led to a slowing down of fruit ripening. At commercial harvest (125 dAFB, S4II) Sd-treated fruits showed a reduced ethylene production and flesh softening. The endogenous concentration of free and insoluble conjugated polyamines (PAs) increased (0.3-2.6-fold) 1 day after treatment (short-term response) butsoon it declined to control levels; starting from S3/S4, when soluble conjugated forms increased (up to five-fold relative to controls at ripening), PA levels became more abundant in treated fruits, (long-term response). Real-time reverse transcription-polymerase chain reaction analyses revealed that peaks in transcript levels of fruit developmental marker genes were shifted ahead in accord with a developmental slowing down. At ripening (S4I-S4II) the upregulation of the ethylene biosynthetic genes ACO1 and ACS1 was dramatically counteracted by Sd and this led to a strong downregulation of genes responsible for fruit softening, such as PG and PMEI. Auxin-related gene expression was also altered both in the short term (TRPB) and in the long term (GH3, TIR1 and PIN1), indicating that auxin plays different roles during development and ripening processes. Messenger RNA amounts of other hormone-related ripening-regulated genes, such as NCED and GA2-OX, were strongly downregulated at maturity. Results suggest that Sd interferes with fruit development/ripening by interacting with multiple hormonal pathways.

Published

2012

23. Beyond the ionic and osmotic response to salinity in Chenopodium quinoa: functional elements of successful halophytism

Author

Orsini, Francesco, primary, Accorsi, Mattia, additional, Gianquinto, Giorgio, additional, Dinelli, Giovanni, additional, Antognoni, Fabiana, additional, Carrasco, Karina B. Ruiz, additional, Martinez, Enrique A., additional, Alnayef, Mohammad, additional, Marotti, Ilaria, additional, Bosi, Sara, additional, and Biondi, Stefania, additional

Published

2011

24. Early jasmonate application interferes with peach fruit development and ripening as revealed by several differentially expressed seed and mesocarp genes

Author

Guglielmo Costa, Daniela Bressanin, Claudio Bonghi, Vanina Ziosi, Alice Tadiello, Livio Trainotti, Karina B. Ruiz, and Patrizia Torrigiani

Subjects

Methyl jasmonate, Ethylene, biology, Aminocyclopropanecarboxylate oxidase, Jasmonic acid, Ripening, Horticulture, chemistry.chemical_compound, chemistry, Biochemistry, Gene expression, Botany, biology.protein, Jasmonate, 1-aminocyclopropane-1-carboxylate synthase