Browsing by Author "Ashkani, Jahanshah"

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    Expression of recombinant S-locus F-box-S2 protein and computational modeling of protein interaction at the self-incompatibility locus of Rosaceae
    (2012) Ashkani, Jahanshah; Rees, D.J.G.; Ndimba, B.
    Self-incompatibility (SI) is a major mechanism that prevents inbreeding in ow-ering plants, which was identi ed in Rosaceae, Solanaceae and Scrophulariace. In these families, SI is gametophytic and retains inter-speci c genetic variations by out-crossing promotion. Self-incompatibility is genetically controlled by an S- locus where both male (pollen) and female (pistil) S-determinants are encoded. The female determinant (SRNase) has been extensively studied, whereas its male counterpart (SLF/SFB) has only recently been characterized as a pollen-expressed protein, which encodes for an F-box domain. However, the exact mechanism of in- teraction between SLF/SFB and SRNase is still largely unclear in Rosaceae. This study takes a closer look at the mechanism of self-incompatibility to gain a clearer understanding of the ligand-receptor binding mechanism of SI using molecular evolutionary analysis, structure prediction and binding speci city characteriza- tion, the outcome of which, will translate into a guideline for future studies. The major aims of this study were to derive an evolutionary pattern for GSI in Rosaceae subfamilies and to further assess the collaborative non-self recognition in Malus domestica Borkh.. The evolutionary analysis suggests a di erence in the evolution- ary pattern of Prunoideae and Maloideae S-genes, hence proposing a di erence in their GSI systems. Furthermore, sites responsible for this divergence are identi ed as critical amino acids in GSI function. To maintain GSI it is expected that the S-genes must be linked and co-evolve as a genetic unit. The results of this study show that these genes have co-existed, while SRNase have experienced a higher rate of evolution compared to SLF, thus rejecting the co-evolution of these genes in Maloideae. Furthermore, positively selected sites of S-locus pistil and pollen genes were identi ed that are likely to be responsible for speci city determination. Di erent numbers of these sites are found for both S-genes, while SRNase holds a larger number of positively selected sites. Additionally a model of speci city is introduced that supports the collaborative non-self recognition in Malus GSI, while critical sites responsible for such speci city are proposed and mapped to the predicted ancestral tertiary structure of SRNase and SLF/SFB. The identi cation of regions determining pollen pistil speci city as well as proposing a Collaborative Non-self Recognition model for Malus domestica Borkh. provide greater in-sight into how pollen-pistil communication system works in Maloideae (Rosaceae subfamily).
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    Selecting an appropriate method for expressing S locus F-box-S2 recombinant protein
    (Elsevier, 2017) Ashkani, Jahanshah; Rees, Jasper G.
    A single locus (S locus) including at least two linked genes (female and male determinants) genetically controls the gametophytic self-incompatibility (GSI) in apple, which has evolved to avoid self-fertilization. There has been extensive work done on the female determinant of self-incompatibility, which has led to the determination of the tertiary structure of S-RNase. However, the tertiary structure of male determinant (S locus F-box, SLF/SFB) remains unresolved, which could mainly be due to difficulties associated with its expression in the recombinant expression systems. In addressing this, we have evaluated several in vivo (prokaryotic and eukaryotic) and in vitro expression systems for their efficiency in the expression of apple SLF2. The most successful expression of SLF2 (1 mg/ml) was achieved in E. coli using the synthesized gene in a high salt culture and applying heat shock before induction of culture. We therefore present an approach for the efficient expression of S locus F-box recombinant proteins for future functional and structural studies.
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    A simple, high-throughput modeling approach reveals insights into the mechanism of gametophytic self-incompatibility
    (Nature Research, 2016) Ashkani, Jahanshah; Rees, D. J. G.
    Specificity in the GSI response results from the S-haplotype-specific molecular interaction of S-locus F-box (SLF/SFB) and SRNase proteins in the self-incompatibility locus (S-locus). The answer to the question of how these two components of the S-locus (SRNase and SLF/SFB) interact has been gathered from several models. Since there is not enough evidence as to which one is the definitive model, none of them can be ruled out. Despite the identification of interacting protein elements, the mechanism by which SLF/SFB and SRNase interact to differently trigger the self-incompatibility among families and subfamilies remain uncertain. The high-throughput modeling approach demonstrates structural visions into the possible existence of a Collaborative Non-Self Recognition model in apple. These findings postulate several prospects for future investigation providing useful information to guide the implementation of breeding strategies.