Down-regulation of a pectin acetylesterase gene modifies strawberry fruit cell wall pectin stracture and increases fruit firmness

Antisense-mediated down-regulation of several fruit-specific genes has previously demonstrated how the cell wall disassembly in strawberry fruit is mediated by a series of enzymes that act sequentially (Posé et al. 2011). An interesting example, the silencing of the polygalacturonase gene FaPG1, was also related with a significant increase of the post-harvest strawberry fruit firmness (Posé et al. 2013). Our research group has isolated a pectin acetylesterase gene, FaPAE1, which expression is enhanced during strawberry ripening. The main goal of this work was to elucidate the role of the degree of acetylation in cell wall integrity and fruit firmness through the antisense-mediated down-regulation of FaPAE1 in strawberry plants. Several transgenics lines were generated and 5 of them produced fruits 5-15% firmer than controls. Cell wall from ripe fruits was isolated from two independent transgenic lines and a control line, and sequentially extracted with different solvents (PAW, H2O, CDTA, Na2CO3). Modifications in fraction yield, its sugar composition and the degree of acetylation in each fraction were determined. Higher amounts of CDTA and Na2CO3 fractions were obtained in transgenic fruits, suggesting a decreased pectin solubilization as results of FaPAE1 silencing. Accordingly, the degree of acetylation of the Na2CO3-soluble pectins was greater in the transgenic lines than the control, but the opposite result was found in pectins from the CDTA fraction. These results suggest that PAE is preferentially active in pectis that are tightly bound to the cellulose-hemicellulose network and its activity could reduce the complexity of the cell wall structure, allowing that other hydrolytic enzymes could access the pectin chains. Thus, the increased fruit firmness observed in the transgenic FaPAE1 lines could be attributed to the direct effect of the silencing of the PAE enzyme and also to the indirect effect that the increase of the degree of acetylation of pectins has on the activity of other enzymes involved in the cell wall degradation. * Posé et al. (2011). Genes, Genomes and Genomics, 5 (Special Issue 1):40-48 * Posé et al. (2013). Plant Physiology, 150: 1022-1032 We acknowledge support from the Spanish Ministry of Economy and competitivity and Feder EU Funds (grant reference AGL2011-24814), FPI fellowships support for SP (BES-2006-13626) and CP (BES-2009027985), and grant "Ramón y Cajal" support for AJMA (RYC-2011-08839).Universidad de Málaga. Campus de Excelencia Internacional Andalucía Tech

Rhamnogalacturonase lyase gene downregulation in strawberry and its potential on mechanical fruit properties

Strawberry softening is one of the main factors that reduces fruit quality and leads to economically important losses. Textural changes during fruit ripening are mainly due to the dissolution of middle lamellae, a reduction in cell-to-cell adhesion and the weakening of parenchyma cell walls as a result of the action of cell wall modifying enzymes. Functional studies of genes encoding pectinase enzymes (polygalacturonase, pectate lyase and -galactosidase) support a key role of pectin disassembly in strawberry softening. Evidence that RG-I may play an important role in strawberry texture has been obtained from the transient silencing of a RG-lyase gene. Pectins are major components of fruit cell walls and highly dynamic polysaccharides, but due to their heterogeneity the precise relation between the structures and functions is incomplete. In this work, stable transgenic strawberry lines with a rhamnogalacturonate lyase gene (FaRGLyase1) down-regulated have been analyzed. Several transgenic lines showing more than 95% silencing of FaRGLyase1 displayed fruit firmness values higher than control. Cell walls from these lines were extracted and analyzed by ELISA and Epitope Detection Chromatography (EDC). This last technique is based on the detection of specific cell wall oligosaccharide epitopes and provides information on sub-populations of pectins containing homogalacturonan and RG-I domains, but also reveals potential links with other cell wall polysaccharides such as xyloglucan. The results obtained indicate that the silencing of FaRGLyase1 reduces degradation of RG-I backbones, but also homogalacturonan, in cell walls, especially in pectin fractions covalently bound to the cell wall. These changes contribute to the increased firmness of transgenic fruits.This research was supported by FEDER EU Funds and the Ministerio de Economía y Competitividad of Spain (grant reference AGL2014-55784-C2), a Marie Curie IEF within the 7th European Community Framework Programme (reference: PIEF-2013-625270) for SP and a FPI fellowship (BES-2015-073616) to support PR-V. Universidad de Málaga. Campus de Excelencia Internacional Andalucía Tech

Isolation and transfection of strawverry protoplasts for gene editing

Strawberry is the most economically important soft fruit. The improvement of the organoleptic qualities of ripe fruit and the postharvest shelf life are main objectives of strawberry breeding programs. Fruit softening is mainly due to the disassembly of cell walls and the dissolution of middle lamella. In strawberry, functional analyses of genes encoding polygalacturonases (PGs) indicate that these enzymes play a key role in fruit softening, i.e. the antisense downregulation of PG genes FaPG1 or FaPG2 increased fruit firmness and postharvest shelf life (Paniagua et al., 2020). These results suggest that PG encoding genes are excellent targets for gene editing to improve strawberry fruit quality. Transfection of protoplasts with CRISPR/Cas9 ribonucleoprotein complexes is currently being explored in many species to produce DNA-free edited plants. In this research, a protocol for strawberry protoplasts transfection has been optimized with the final goal of producing non-transgenic strawberry plants with the FaPG1 gene edited. Protoplasts were isolated from 9 weeks old in vitro grown plants of Fragaria x ananassa, cv. ‘Chandler’, micropropagated in Murashige and Skoog (MS) medium supplemented with 2 mg/L of BA. Protoplast extraction and purification was performed as described by Barceló et al. (2019). Using this protocol, a yield of 1 x 105 protoplast/g fresh tissue was obtained and nearly 50-70% of them were viable. Protoplasts were transfected with the plasmid pHBT-sGFP(S65T)-NOS using a PEG-mediated transformation system, as reported by Yoo et al. (2007). To improve the efficiency of protoplast transfection, different variables were evaluated: PEG concentration, time of incubation on PEG and DNA concentration. At 48 h after transfection, the highest percentage of protoplasts showing GFP expression, 18%, was obtained with 15 minutes incubation in 20% of PEG and 5 µg of DNA

High-throughput mapping of cell wall glycans to unveil cell wall disassembly, a key process determining strawberry fruit softening

The short shelf life of strawberry fruit is a major limitation that produces important economic losses related to postharvest spoiling. Fruit texture of fleshy fruits is a complex trait but mainly rely on mechanical properties of parenchyma cell walls. Several studies support the relevance of cell wall modifying enzymes on cell wall deconstruction, decreasing cell wall strength and cell to cell adhesion, and ultimately producing the softening of the fruit at macroscopic level. Previous studies on our group showed that transgenic silencing of ripening-specific genes encoding some of these enzymes reduced softening and increased postharvest shelf life in strawberry (Fragaria × ananassa, cv. ‘Chandler’) fruits. In this research, to further investigate the cell wall remodelling process associated to strawberry softening a high-throughput analysis of cell wall composition based on monoclonal antibodies against different polysaccharide epitopes has been performed. To this purpose, cell walls were isolated from non-transgenic fruits at different developmental stages as well as from ripe fruits of selected transgenic lines with genes involved in metabolism of pectins (pectate lyase, polygalacturonase, β-galactosidase, pectin acetil esterase), hemicellulose/cellulose (endo-β-glucanase) or lignin (cinnamyl alcohol dehydrogenase) down-regulated. These transgenic lines showed a large variability in fruit firmness at ripening. Cell walls were fractionated and subjected to a carbohydrate microarray. The results obtained unveiled a common pattern of cell wall composition on those transgenic lines with firmer phenotypes, specially defined by the higher content of pectins on those cell wall fractions more imbricated in the matrix, which can be interpreted as a less degraded cell wall structure.This research was supported by FEDER EU Funds and the Ministerio de Economía y Competitividad of Spain (grant reference AGL2017-86531-C2-1-R). Universidad de Málaga. Campus de Excelencia Internacional Andalucía Tech

A core collection of modified strawberry germplasm as a resource tool for funghi infection and fruit texture studies

Strawberry has been extensively used as a model organism for functional genomics of genes related with fungi infection (Amil-Ruiz et al, 2011) and fruit ripening, specially fruit texture (Posé et al, 2011). These studies implied the genetic transformation and subsequent characterization of a wide range of traits, resulting in a considerable number of lines being created and more or less extensively studied. A preliminary data survey was performed previous publications, laboratory notebooks and project reports. Main categories and the relevant features (like cultivar, transgene sequence, germplasm availability, plant phenotype, experiment results, etc) were identified, establishing the appropriate relationships. The project followed the Chado schema used by the GMOD initiative http://www.gmod.org. The germplasm collection currently hosts two strawberry cultivar (Camarosa and Chandler), nine transgenic lines with resistance genes against fungi infections and over a dozen for fruit texture related genes. Collected information includes in vitro and in planta leaf symptomatology and fungus spore germination, as well as gene expression for each transgene, plant production, fruit color, shape and firmness. Data on cell wall fractionation, pectin and soluble sugars quantification, FT-IR and size exclusion chromatography, AFM pectin structure characterization and Immunohistological analysis. The intrinsic value of these studies makes necessary to preserve both the germplasm and the data generated, and to make it available to the community for further study and reuse. Community driven formats will facilitate the use of the data in new. studies. The present project aims to increase the value of the transgenic strawberry plants in the collection, using standard data formats and open source tools to facilitate access to the research and breeding communities as well as to facilitate the distribution of the germplasm.Universidad de Málaga. Campus de Excelencia Internacional Andalucía Tech. AGL2011-2481

Downregulation of NAC transcription factors modifies cell wall composition and increases strawberry fruit firmness

The strawberry is a soft fruit with a very short post-harvest shelf life. The changes in texture during fruit ripening are mainly due to the dissolution of the middle lamellae, reducing cell-to-cell adhesion, and the weakening of parenchymal cell walls as result of the action of cell wall modifying enzymes. At present, no master regulator of this process has been discovered yet. NAC transcription factors have been involved in numerous physiological processes, including fruit ripening. In strawberry, the NAC family comprises more than 110 genes, and at least 6 of them are expressed during fruit development. In this research, we performed a functional analysis of two ripening-related NAC genes, FaNAC2 and FaNAC3, in Fragaria x ananassa Duch. cv. Chandler. Several RNAi transgenic lines showing low FaNAC2 or FaNAC3 mRNA levels in fruit were obtained through Agrobacterium-mediated transformation. These lines produced fruits significantly firmer than control at the ripe stage, being the increase in firmness higher in FaNAC2 silenced plants. Cell walls were extracted from ripe transgenic fruits and characterized by ELISA and Epitope Detection Chromatography (EDC), using monoclonal antibodies against different polysaccharide epitopes. FaNAC2 transgenic lines showed more extensive changes than FaNAC3; these modifications involved increased amounts of demethylated pectins (LM19) in water and CDTA fractions and an alteration of the lateral branches of RG-I, decreasing the amount of arabinan epitopes and increasing galactan epitopes detected by LM6 and LM5, respectively. The amount of arabinogalactan proteins recognized by the JIM13 antibody was also affected, decreasing in the Na2CO3 fraction and increasing in the 4M KOH and cellulase fraction of the transgenic lines.The results obtained indicate that NAC genes could be involved in the regulation of cell wall disassembly associated to strawberry fruit softening.Universidad de Málaga. Campus de Excelencia Internacional Andalucía Tech

Optimización de la transfección de protoplastos para la edición génica en fresa

Esta investigación ha sido financiada por los fondos FEDER EU, el Ministerio de Economía y Competitividad de España (AGL2017-86531-C2-1-R), y el contrato FPI PRE2018-085509.La fresa es un fruto blando de gran importancia económica, particularmente en Andalucía. La mejora de las cualidades organolépticas del fruto y la disminución del reblandecimiento para alargar la vida postcosecha del fruto, son unos de los principales objetivos de los programas de mejora en este cultivo. El reblandecimiento del fruto es consecuencia del desmantelamiento de la pared celular, la disolución de la lámina media y la pérdida de turgencia. En fresa, el silenciamiento mediante la transformación en antisentido de genes que codifican poligalacturonasas (PG) aumenta la firmeza del fruto y la vida postcosecha (Paniagua et al., 2020). Por tanto, estos genes son excelentes dianas para la edición génica con el fin de mejorar la calidad del fruto de la fresa. La transfección de protoplastos con complejos preensamblados Cas9-sgRNA permite la producción de plantas editadas vía CRISPR/Cas9 libres de ADN foráneo, que podrían ser consideradas como no transgénicas. En esta investigación, se ha optimizado un protocolo para la transfección de protoplastos de fresa, con el objetivo final de producir plantas no transgénicas con el gen de poligalacturonasa FaPG1 mutado. Como fuente de material vegetal se utilizaron hojas de plantas de Fragaria x ananassa, cv. ‘Chandler’, micropropagadas en medio Murashige y Skoog (MS) suplementado con 2 mg/L de BA. Para la extracción de protoplastos se utilizó el protocolo descrito por Barceló et al. (2019). A las 24 h del aislamiento, los protoplastos fueron transfectados con el plásmido pHBT-sGFP(S65T)-NOS que contiene el gen marcador GFP, mediante un tratamiento con polietilenglicol (PEG), como se describe en Yoo et al. (2007). Se evaluaron, entre otras variables, el efecto de la concentración y tiempo de incubación en PEG y la concentración de ADN. Los valores más altos de protoplastos con actividad GFP a las 48 h de la transfección, entre el 15-18%, se obtuvieron tras la incubación en 20% de PEG en presencia de 5 µg de ADN.Universidad de Málaga. Campus de Excelencia Internacional Andalucía Tech

A nanostructural view of the cell wall disassembly process during fruit ripening and postharvest storage by atomic force microscopy

Background: The mechanical properties of parenchyma cell walls and the strength and extension of adhesion areas between adjacent cells, jointly with cell turgor, are main determinants of firmness of fleshy fruits. These traits are modified during ripening leading to fruit softening. Cell wall modifications involve the depolymerisation of matrix glycans and pectins, the solubilisation of pectins and the loss of neutral sugars from pectin side chains. These changes weaken the cell walls and increase cell separation, which in combination with a reduction in cell turgor, bring about textural changes. Atomic force microscopy (AFM) has been used to characterize the nanostructure of cell wall polysaccharides during the ripening and postharvest storage of several fruits. This technique allows the imaging of individual polymers at high magnification with minimal sample preparation. Scope and approach: This paper reviews the main features of the cell wall disassembly process associated to fruit softening from a nanostructural point of view, as has been provided by AFM studies. Key findings and conclusions: AFM studies show that pectin size, ramification and complexity is reduced during fruit ripening and storage, and in most cases these changes correlate with softening. Postharvest treatments that improve fruit quality have been proven to preserve pectin structure, suggesting a clear link between softening and pectin metabolism. Nanostructural characterization of cellulose and hemicellulose during ripening has been poorly explored by AFM and the scarce results available are not conclusive. Globally, AFM could be a powerful tool to gain insights about the bases of textural fruit quality in fresh and stored fruits

Disentangling pectic homogalacturonan and rhamnogalacturonan-I polysaccharides: Evidence for sub-populations in fruit parenchyma systems

The matrix polysaccharides of plant cell walls are diverse and variable sets of polymers influencing cell wall, tissue and organ properties. Focusing on the relatively simple parenchyma tissues of four fruits – tomato, aubergine, strawberry and apple – we have dissected cell wall matrix polysaccharide contents using sequential solubilisation and antibody-based approaches with a focus on pectic homogalacturonan (HG) and rhamnogalacturonan-I (RG-I). Epitope detection in association with anion-exchange chromatography analysis indicates that in all cases solubilized polymers include spectra of HG molecules with unesterified regions that are separable from methylesterified HG domains. In highly soluble fractions, RG-I domains exist in both HG-associated and non-HG-associated forms. Soluble xyloglucan and pectin-associated xyloglucan components were detected in all fruits. Aubergine glycans contain abundant heteroxylan epitopes, some of which are associated with both pectin and xyloglucan. These profiles of polysaccharide heterogeneity provide a basis for future studies of more complex cell and tissue systems