Genetics and Evolution of Abiotic Stress Tolerance in Plants.

Now more than ever, the understanding of the genetics and evolution of the gene mechanisms and the networks of different molecular pathways acting on plant abiotic stress tolerance has an important role in the finding of new solutions and approaches mitigating the effects of global climate changes, thus contributing to a correct equilibrium among human needs, food security and human health and wellbeing [...].

Expression Analysis of the TdDRF1 Gene in Field-Grown Durum Wheat under Full and Reduced Irrigation.

Some of the key genes and regulatory mechanisms controlling drought response in durum wheat have been identified. One of the major challenges for breeders is how to use this knowledge for the achievement of drought stress tolerance. In the present study, we report the expression profiles of the TdDRF1 gene, at consecutive plant growth stages, from different durum wheat genotypes evaluated in two different field environments. The expression of a possible target gene (Wdnh13) of the TdDRF1 gene was also investigated and analogies with the transcript profiles were found. The results of the qRT-PCR highlighted differences in molecular patterns, thus suggesting a genotype dependency of the TdDRF1 gene expression in response to the stress induced. Furthermore, a statistical association between the expression of TdDRF1 transcripts and agronomic traits was also performed and significant differences were found among genotypes, suggesting a relationship. One of the genotypes was found to combine molecular and agronomic characteristics.

Phenotyping of Different Italian Durum Wheat Varieties in Early Growth Stage With the Addition of Pure or Digestate-Activated Biochars.

This study aims to highlight the major effects of biochar incorporation into potting soil substrate on plant growth and performance in early growth stages of five elite Italian varieties of durum wheat (Triticum durum). The biochars used were obtained from two contrasting feedstocks, namely wood chips and wheat straw, by gasification under high temperature conditions, and were applied in a greenhouse experiment either as pure or as nutrient-activated biochar obtained by incubation with digestate. The results of the experiment showed that specific genotypes as well as different treatments with biochar have significant effects on plant response when looking at shoot traits related to growth. The evaluated genotypes could be clustered in two main distinct groups presenting, respectively, significantly increasing (Duilio, Iride, and Saragolla varieties) and decreasing (Marco Aurelio and Grecale varieties) values of projected shoot system area (PSSA), fresh weight (FW), dry weight (DW), and plant water loss by evapotranspiration (ET). All these traits were correlated with Pearson correlation coefficients ranging from 0.74 to 0.98. Concerning the treatment effect, a significant alteration of the mentioned plant traits was observed when applying biochar from wheat straw, characterized by very high electrical conductivity (EC), resulting in a reduction of 34.6% PSSA, 43.2% FW, 66.9% DW, and 36.0% ET, when compared to the control. Interestingly, the application of the same biochar after nutrient spiking with digestate determined about a 15-30% relief from the abovementioned reduction induced by the application of the sole pure wheat straw biochar. Our results reinforce the current basic knowledge available on biological soil amendments as biochar and digestate.

B genome specific polymorphism in the TdDRF1 gene is in relationship with grain yield.

MAIN CONCLUSION: A and B genome copies of DRF1 gene in durum wheat were isolated and sequenced using gene variability. B genome specific polymorphism resulted, in a RIL population, in relationship with grain yield mainly in drought condition. Drought tolerance is one of the main components of yield potential and stability, and its improvement is a major challenge to breeders. Transcription factors are considered among the best candidate genes for developing functional markers, since they are components of the signal transduction pathways that coordinate the expression of several downstream genes. Polymorphisms of the Triticum durum dehydration responsive factor 1 (TdDRF1) gene that belongs to DREB2 transcription factor family were identified and specifically assigned to the A or B genome. A panel of primers was derived to selectively isolate the corresponding gene copies. These molecular information were also used to develop a new molecular marker: an allele-specific PCR assay discriminating two genotypes (Mohawk and Cocorit) was developed and used for screening a durum wheat recombinant inbred line population (RIL-pop) derived from the above genotypes. Phenotypic data from the RIL-pop grown during two seasons, under different environmental conditions, adopting an α-lattice design with two repetitions, were collected, analyzed and correlated with molecular data from the PCR assay. A significant association between a specific polymorphism in the B genome copy of the TdDRF1 gene and the grain yield in drought conditions were observed.

Genomic Characterization of Phenylalanine Ammonia Lyase Gene in Buckwheat.

Phenylalanine Ammonia Lyase (PAL) gene which plays a key role in bio-synthesis of medicinally important compounds, Rutin/quercetin was sequence characterized for its efficient genomics application. These compounds possessing anti-diabetic and anti-cancer properties and are predominantly produced by Fagopyrum spp. In the present study, PAL gene was sequenced from three Fagopyrum spp. (F. tataricum, F. esculentum and F. dibotrys) and showed the presence of three SNPs and four insertion/deletions at intra and inter specific level. Among them, the potential SNP (position 949th bp G>C) with Parsimony Informative Site was selected and successfully utilised to individuate the zygosity/allelic variation of 16 F. tataricum varieties. Insertion mutations were identified in coding region, which resulted the change of a stretch of 39 amino acids on the putative protein. Our Study revealed that autogamous species (F. tataricum) has lower frequency of observed SNPs as compared to allogamous species (F. dibotrys and F. esculentum). The identified SNPs in F. tataricum didn't result to amino acid change, while in other two species it caused both conservative and non-conservative variations. Consistent pattern of SNPs across the species revealed their phylogenetic importance. We found two groups of F. tataricum and one of them was closely related with F. dibotrys. Sequence characterization information of PAL gene reported in present investigation can be utilized in genetic improvement of buckwheat in reference to its medicinal value.

Evaluation of triticale as energy crop in Italy.

The promotion of renewable energy represents a target of the European 2020 strategy for economical growth and sustainable competitiveness. Cereals are considered a promising biomass producing crop in temperate regions of Europe to be used for both fuel alcohol and biogas production. Among cereals, triticale represents a good candidate for this kind of application, showing a number of advantages such as high grain yield even in marginal environments, tolerance to drought, tolerance to more acid soils, lower production costs and lower susceptibility to biotic stresses. The aim of this study was to compare yield and quality of eight triticale lines grown in marginal areas in a two-year experiment. Italian variety, Magistral, and a bread wheat variety (EW9) were selected for comparison. Data from fields, chemical analyses and preliminary results from fermentation are reported.

Variability and expression profile of the DRF1 gene in four cultivars of durum wheat and one triticale under moderate water stress conditions.

The dehydration responsive element binding (DREB) proteins are important transcription factors that contribute to stress endurance in plants triggering the expression of a set of abiotic stress-related genes. A DREB2-related gene, previously referred to as dehydration responsive factor 1 (DRF1) was originally isolated and characterized in durum wheat. The aim of this study was to monitor the expression profiles of three alternatively spliced TdDRF1 transcripts during dehydration experiments and to evaluate the effects of genetic diversity on the molecular response, using experimental conditions reflecting as closely as possible water stress perceived by cereals in open field. To investigate the effect of moderate water stress conditions, time-course dehydration experiments were carried out under controlled conditions in the greenhouse on four durum wheat and one triticale genotypes. Differences were observed in molecular patterns, thus, suggesting a genotype dependency of the DRF1 gene expression in response to the stress induced. The biodiversity of the transcripts of the DRF1 gene was explored in order to assess the level of polymorphism and its possible effects on structure and function of putative proteins. A total of nine haplotypes were identified in the sequences cloned, seven of which encompassing polymorphisms in exon 4, including the region codifying for the DNA binding Apetala2 (AP2) domain. The 3D structural models of the AP2 domain were generated by homology modelling using the variability observed. The polymorphisms analysed did not significantly affect the structural arrangement of the DNA binding domains, thus resulting compatible with the putative functionality.

Dependence of nanoparticle-cell recognition efficiency on the surface orientation of scFv targeting ligands.

The surface activation of multifunctional nanoparticles (MNPs) with peptide ligands directing their targeting to cancer cells is an emerging research area in nanobiotechnology. In this paper, water-soluble MNPs have been synthesized and functionalized with an scFv antibody variant specific toward the HER2 receptor overexpressed in several breast cancer cell lines. The scFv was genetically engineered to introduce a cysteine residue inside the loop sequence bridging the VH and VL lobes of the molecule and a histidine tag at the C-terminus in the VL fragment. The Cys and 6 × His functionalities were exploited as orthogonal reactive groups driving the scFv conjugation to MNPs. In this way, scFv positioning on the MNP surface was forced into two different orientations depending on the molecular binding site used for conjugation. The resulting scFv-functionalized MNP1 and MNP2, respectively, were assessed as to their labeling efficiency and selectivity to HER2-positive MCF7 cells. We demonstrate that, while both MNP1 and MNP2 were selective for HER2, there is a remarkable preference for scFv presentation with VH and VL lobes concurrently available for receptor recognition (MNP1) in terms of cell binding efficiency, suggesting that ligand orientation may strongly affect cell binding from MNPs.

Site-specific conjugation of ScFvs antibodies to nanoparticles by bioorthogonal strain-promoted alkyne-nitrone cycloaddition.

Particularly suitable: An N-terminal serine mutant of anti-HER2 scFv antibody was conjugated to polymer-coated magnetofluorescent nanoparticles by strain-promoted alkyne-nitrone cycloaddition. The resulting nanoparticles (see scheme) proved effective in targeting and labeling HER2-positive breast cancer cells.

Bacterial cytoplasm production of an EGFP-labeled single-chain Fv antibody specific for the HER2 human receptor.

The human epidermal growth factor receptor 2 (HER2) is the main diagnostic marker of breast and ovary cancers. Here, to obtain a rapid and sensitive immunodiagnostic tool a single-chain antibody (scFv800E6) specific for the HER2 was fused to the N-terminus of the enhanced green fluorescent protein (EGFP) by a flexible linker. The soluble production of the novel scFv800E6-EGFP protein in the cytoplasm of Escherichia coli was investigated at different induction temperatures (25, 30 and 37°C); the intrinsic fluorescent properties and the binding activity to HER2 positive tumour cells of the fusion protein were analysed. Western blotting and fluorescence analysis of SDS-PAGE revealed the presence of two scFv800E6-EGFP forms, with different mobility and optical properties, their ratio depending on the induction temperature. The fluorescent form maintained the optical fluorescence properties of EGFP and exhibited a binding activity to the HER2-expressing cells comparable to that of the non-fused scFv800E6. In addition, to provide an insight into the effect of the induction temperature on the molecular structure, the folding of the fusion protein was assessed at atomic level by performing molecular dynamics simulations of the homology-derived model of scFv800E6-EGFP at 300 K and 310 K. The comparison of the data collected at these two temperatures revealed that the higher temperature affects specific structural elements. To improve the production of the soluble and functional scFv800E6-EGFP protein, "in silico" results could be utilised for ad hoc design of the molecular structure.

Multiple presentation of Scfv800E6 on silica nanospheres enhances targeting efficiency toward HER-2 receptor in breast cancer cells.

Spherical silica nanoparticles (SNP) have been synthesized and functionalized with anti-HER-2 scFv800E6 antibody by both localized histidine-tag recognition, leading to an oriented protein ligation, and glutaraldehyde cross-linking, exploiting a statistical reactivity of lysine amine groups in the primary sequence of the molecule. The targeting efficiency of nanocomplexes in comparison with free scFv was evaluated by flow cytometry using a HER-2 antigen-positive MCF-7 breast cancer cell line, exhibiting a 4-fold increase in scFv binding efficacy, close to the affinity of intact anti-HER-2 monoclonal antibody, which suggests the effectiveness of presenting multiple scFv molecules on nanoparticles in improving antigen recognition. Unexpectedly, the conjugation method did not affect the binding efficacy of scFv, suggesting a structural role of lysines in the scFv molecule. Confocal laser scanning microscopy confirmed the binding of nanocomplexes to HER-2 and also provided evidence of their localization at the cell surface.

Highly efficient production of anti-HER2 scFv antibody variant for targeting breast cancer cells.

The human epidermal growth factor receptor 2 (HER2) is a transmembrane tyrosine kinase receptor overexpressed in 30% of human breast cancers. One of the mechanisms by which tumor cell proliferation can be inhibited consists in hampering HER2 dimerization by targeting its extracellular domain with specific antibodies. In recent clinical practice, a valuable alternative to entire IgGs resides in the use of smaller molecules, such as single-chain variable fragments (scFv), developed for selective molecular targeting. In this paper, we report on the production and purification of a soluble anti-HER2 scFv antibody secreted by Pichia pastoris. The gene encoding scFv800E6 with an additional 6× His-tag at the 3'-end was inserted into the expression vector pPICZα and transformed in P. pastoris. The highest expression level was obtained in presence of 0.5% methanol and 0.8% glycerol in the culture medium after 48 h of induction. The use of P. pastoris proved very valuable as an expression system, allowing the isolation of 10 mg/L of highly purified antibody, remarkably higher than previously reported data. The functionality of purified anti-HER2 scFv was assessed by cytofluorimetry and immunofluorescence on HER2-positive MCF7 breast cancer cells, showing good affinity and high selectivity for the target membrane receptor. These findings confirm that P. pastoris is a suitable host for high level expression of antibody fragments and highlight the potential role of scFv800E6 in diagnostic and therapeutic application.

Structure and dynamics of the anti-AMCV scFv(F8): effects of selected mutations on the antigen combining site.

The recombinant antibody fragment scFv(F8), which recognizes the coat protein of the plant virus AMCV, is characterized by peculiar high in vitro stability and functional folding even in reducing environments, making it fit for designing stable antibodies with desired properties. Mutagenesis and functional analysis evidenced two residues, at positions 47 and 58 of the V(H) chain, playing a crucial role in the antigen binding recognition. Here, we used a computational procedure to assess the effects of these mutations on the stability, structure and dynamics of the antigen-binding site. Structural models of the wild type scFv(F8) and of its H47 and H58 mutants were built by homology modelling and assessed by multiple 15.5ns of molecular dynamics simulations. Computational results indicate that the 47H substitution strongly affects the CDR-H(2) conformation, destabilizes the V(H)/V(L) interface and confers high conformational flexibility to the antigen-binding site, leading the mutant to functional loss. The mutation at position H58 strenghtens the binding site, bestowing a high antigen specificity on the mutant. The essential dynamics and the analysis of the protein-solvent interface further corroborate the correspondence between the extent of the structurally-determined flexibility of the binding site with the different functional behaviours proved by the wild-type and its mutants. These results may have useful implications for structure-based design of antibody combining site.

Functional expression of a single-chain antibody to ErbB-2 in plants and cell-free systems.

BACKGROUND: Aberrant signaling by ErbB-2 (HER 2, Neu), a member of the human Epidermal Growth Factor (EGF) receptor family, is associated with an aggressive clinical behaviour of carcinomas, particularly breast tumors. Antibodies targeting the ErbB-2 pathway are a preferred therapeutic option for patients with advanced breast cancer, but a worldwide deficit in the manufacturing capacities of mammalian cell bioreactors is foreseen. METHODS: Herein, we describe a multi-platform approach for the production of recombinant Single chain Fragments of antibody variable regions (ScFvs) to ErbB-2 that involves their functional expression in (a) bacteria, (b) transient as well as stable transgenic tobacco plants, and (c) a newly developed cell-free transcription-translation system. RESULTS: An ScFv (ScFv800E6) was selected by cloning immunoglobulin sequences from murine hybridomas, and was expressed and fully functional in all the expression platforms, thereby representing the first ScFv to ErbB-2 produced in hosts other than bacteria and yeast. ScFv800E6 was optimized with respect to redox synthesis conditions. Different tags were introduced flanking the ScFv800E6 backbone, with and without spacer arms, including a novel Strep II tag that outperforms conventional streptavidin-based detection systems. ScFv800E6 was resistant to standard chemical radiolabeling procedures (i.e. Chloramine T), displayed a binding ability extremely similar to that of the parental monovalent Fab' fragment, as well as a flow cytometry performance and an equilibrium binding affinity (Ka approximately 2 x 10(8) M(-1)) only slightly lower than those of the parental bivalent antibody, suggesting that its binding site is conserved as compared to that of the parental antibody molecule. ScFv800E6 was found to be compatible with routine reagents for immunohistochemical staining. CONCLUSION: ScFv800E6 is a useful reagent for in vitro biochemical and immunodiagnostic applications in oncology, and a candidate for future in vivo studies.

Functional expression of a single-chain antibody specific for the HER2 human oncogene in a bacterial reducing environment.

Recombinant antibody fragments represent useful tools for cancer diagnosis and therapy. Aberrant expression of the HER2 receptor is implicated in metastatic breast and ovary cancers, two malignancies with a high prevalence in young women. In this study, we focussed on a single-chain fragment of variable antibody regions specific for HER2 (scFv800E6) that can be expressed in a functional form in the cytoplasm of Escherichia coli. ScFv800E6 was extracted from bacterial cultures following induction at different temperatures and purified. The yield of both soluble and insoluble forms was measured. We found that scFv800E6 was functional when expressed in the soluble fraction in the bacteria cytosol. In addition, scFv800E6 extracted from inclusion bodies was easily refolded and largely recovered its functionality. Thus, scFv800E6 is intrinsically capable of efficient and functional folding in a reducing environment and represents one of the few described antibody fragments with a framework well adapted for cytoplasmic expression.