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    Allelic diversity of a panel of Aegilops mutica Boiss (Amblyopyrym muticum (Boiss.) Eig) from Turkey
    (Cambridge Univ Press, 2022) Alsaleh, Ahmad; Cakir, Esra; Bektas, Harun; Ozkan, Hakan
    The members of the Aegilops genus serve as a vast pool of allele discovery for wheat improvement in abiotic and biotic stress responses. Aegilops mutica Boiss (Amblyopyrym muticum (Boiss) Eig) is an unexplored candidate with significant potential. Even though it has been used in cytogenetics applications within the last century, natural population diversity and allele discovery have been neglected. As an endemic species for Anatolia and the lower Caucasian region, it has an unexplored population structure. Here, seventy-five genotypes from five different newly collected populations from central Anatolia were evaluated with 29 polymorphic SSR loci. Significant diversity within (83%) and between (17%) the populations was obtained. Three of the populations were clearly separated, while two had some level of the mixture. Relatively easy cross-species hybridization and introgressions make Ae. mutica a good candidate for novel allele discovery and pre-breeding. Here, for the first time, representative natural populations of Ae. mutica were compared and population structures were revealed with SSR markers which may clear the misty vision that geneticists might have regarding Ae. mutica. This could be exploited in genetic resource conservation and breeding programs and maybe a point for further studies.
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    Genome-wide association analysis of coleoptile length and interaction with plant height in durum wheat
    (Wiley, 2024) Sesiz, Ugur; Alsaleh, Ahmad; Bektas, Harun; Topu, Mustafa; Ozkan, Hakan
    Genotypes with longer coleoptiles can be sown in deep soil layers to reach the underground moisture needed for germination in dry areas. Developing new varieties with longer coleoptiles and shorter plant heights would be novel for wheat breeding and production. In this study, coleoptile lengths of a panel of durum wheat (Triticum turgidum ssp. durum) genotypes were determined, and 14,255 DArTseq (SNP and Silico-DArT) markers were used to identify coleoptile length-associated markers by genome-wide association study (GWAS). A wide genetic variation was accounted for both coleoptile length and plant height. The genetic relationships between coleoptile length and plant height were evaluated using plant height values from five different environments. Two environmentally stable MTAs were identified, one for coleoptile length (QCol.su.4BS) and one for plant height (QPh.su.4BS). These MTAs were located on the short arm of chromosome 4B, with LOD scores up to 12.00 and 17.00, respectively. A relatively high LD (r2 = 0.71) was accounted for between QCol.su.4BS and QPh.su.4BS. The LD block intervals of the MTAs overlapped with some genes with roles in plant growth and development. The functions of plausible candidate genes tell us that QCol.su.4BS may be controlling coleoptile length, whereas QPh.su.4BS may be regulating plant height. The combination of the two loci would be desirable. In conclusion, this study sheds light on the genetic control of coleoptile length and its relationship with plant height in durum wheat. Cultivars with longer coleoptiles perform better at emergence and seedling establishment.A diverse durum wheat panel was studied using GWAS analysis to evaluate coleoptile length and plant height.Two significant and stable genomic regions were identified for coleoptile length and plant height.These regions might enhance coleoptile length while reducing plant height.
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    Next-Generation-Sequencing-Based Simple Sequence Repeat (SSR) Marker Development and Linkage Mapping in Lentil (Lens culinaris L.)
    (Mdpi, 2023) Topu, Mustafa; Sesiz, Ugur; Bektas, Harun; Toklu, Faruk; Ozkan, Hakan
    Simple Summary Although lentil is not as popular as other legumes, it is a climate-resilient legume crop because of its high protein content, nitrogen fixation, and abiotic stress tolerance ability. Even though it can be grown on almost every continent and is distributed globally, the use of existing genetic diversity in marker-assisted selection is still limited. In this study, novel SSR markers needed in lentil were identified using a next-generation sequencing approach. In this study, we created a ready-to-use SSR library for genetic diversity studies and breeding and evaluated the effectiveness of the obtained SSR markers in a recombinant inbred line (RIL) population. Simple sequence repeats (SSRs) are highly versatile markers in genetic diversity analysis and plant breeding, making them widely applicable. They hold potential in lentil (Lens culinaris) breeding for genetic diversity analysis, marker-assisted selection (MAS), and linkage mapping. However, the availability and diversity of SSR markers in lentil is limited. We used next-generation sequencing (NGS) technology to develop SSR markers in lentil. NGS allowed us to identify regions of the lentil genome that contained SSRs. Illumina Hiseq-2000 sequencing of the lentil genotype Karacadag resulted in 1,727,734 sequence reads comprising more than 48,390 Mb, and contigs were mined for SSRs, resulting in the identification of a total of 8697 SSR motifs. Among these, dinucleotide repeats were the most abundant (53.38%), followed by trinucleotides (30.38%), hexanucleotides (6.96%), tetranucleotides (6.59%), and pentanucleotides (3.19%). The most frequent repeat in dinucleotides was the TC (21.80%), followed by the GA (17.60%). A total of 2000 primer pairs were designed from these motifs, and 458 SSR markers were validated following their amplified PCR products. A linkage map was constructed using these new SSRs with high linkage disequilibrium (209) and previously known SSRs (11). The highest number of SSR markers (43) was obtained in LG2, while the lowest number of SSR markers (19) was obtained in LG7. The longest linkage group (LG) was LG2 (86.84 cM), whereas the shortest linkage group was LG7 (53.46 cM). The average length between markers ranged from 1.86 cM in LG1 to 2.81 cM in LG7, and the map density was 2.16 cM. The developed SSRs and created linkage map may provide useful information and offer a new library for genetic diversity analyses, linkage mapping studies, and lentil breeding programs.
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    Turkish durum wheat conserved ex-situ and in situ unveils a new hotspot of unexplored genetic diversity
    (Wiley, 2022) Alsaleh, Ahmad; Bektas, Harun; Baloch, Faheem Shehzad; Nadeem, Muhammad Azhar; Ozkan, Hakan
    Durum wheat (Triticum turgidum L.) is the 10(th) most cultivated crop and is a vital food source for human consumption. Genetic diversity in durum wheat is still an unexplored subject, and gene banks are filled with accessions waiting to be screened. Here, four different groups of durum wheat, Turkish and foreign cultivars, and in situ and ex situ landraces were evaluated for population structure and genetic diversity. A collection of 129 durum wheat accessions were genotyped, with a total of 6,357 markers (SilicoDArT, SNP [single-nucleotide polymorphism], and simple sequence repeats [SSRs]). The highest mean allele number per marker (1.562) was obtained with SNP markers in ex situ landraces; the lowest mean allele number per marker (0.788) was obtained with SSR markers in the foreign cultivars. The minimum percentage of polymorphic loci was 38.70% observed with SSR markers in foreign cultivars; the maximum was 76.20% in SilicoDArT markers in ex situ landraces. According to Neighbor-Joining analyses, the studied collection was divided into groups of cultivars and landraces, with some level of admixtures. Structure and principal coordinate analysis obtained distinct clusters for ex situ landraces and foreign cultivars, supported by Neighbor-Joining analysis. A significant level of intergroup and intragroup variation was observed, and Turkish ex situ landraces were found as the most diverse and distinct group in the collection. Turkish landraces may be a promising source of novel allelic diversity that can be used in durum wheat breeding worldwide.