Development of a SCAR Marker Based on SCoT Polymorphisms for Sugarcane Smut Resistance

Sugarcane smut caused by Sporisorium scitanmineumis the most severe sugarcane disease that causes major economic losses in sugarcane production in China, and disease resistance breeding is an important way of preventing and controlling this disease. In this study, BC3F1lines derived from the cross between YC 73-226 and YCE 06-111 were used to generate sugarcane smut-resistant and -susceptible gene pools using bulked segregant analysis (BSA). Eighty-nine random primers of start codon targeted (SCoT) polymorphisms were screened, whereas only primer SCoT44 could stably amplify the specific fragment (HE-Ss44) in the resistant pool. Then, several primer pairs of sequence characterized amplified regions (SCARs) were designed based on the sequence alignment of HE-Ss44 (920 bp), which was recovered after purification, and only one pair of SCAR primers (Ss44-F2/R2, forward: 5'-GGCGGGCACCGTCGAGTCCACAT-3'; reverse: 5'-CCGTCCGTCGG TCTCGTCCTTACG-3') could stably amplify a 400-bp specific band in resistant gene pool and its individuals. A validation test of SCAR marker Ss44-F2/R2 was performed using 34 sugarcane cultivars with known smut resistance, which revealed a selection accuracy of 82.35% between marker detection and known smut resistance. Moreover, Pearson’s correlation analysis also showed that the SCAR marker Ss44-F2/R2 was significantly correlated (r= 0.583, P= 0.0003 < 0.01) with the smut resistance trait in sugarcane. In addition, the nucleotide sequence of HE-Ss44 linked with smut-resistancewas not aligned to the homologous sequence in GenBank (NCBI), and the accession number was MG740763. The SCAR marker Ss44-F2/R2 developed in this study can be used for the rapid detection of smut resistance in sugarcane and may be utilized as reference for the improvement of sugarcane smut resistance based on molecular marker-assisted selection.© 2021 Friends Science Publishers

Genetic Analysis of a Horizontal Resistance Locus BLMR2 in Brassica napus

Leptosphaeria maculans causes blackleg disease in Brassica napus. The blackleg disease is mainly controlled by resistance genes in B. napus. Previous studies have shown that the blackleg resistant BLMR2 locus that conferred horizontal resistance under field conditions, is located on chromosome A10 of B. napus. The purpose of this study is to fine map this locus and hence identify a candidate gene underlying horizontal resistance. The spectrum of resistance to L. maculans isolates of the resistance locus BLMR2 was analyzed using near isogenic lines, resistant, and susceptible cultivars. The results showed that this locus was horizontally resistant to all isolates tested. Sequence characterized amplified regions (SCAR), simple sequence repeats (SSR), and single nucleotide polymorphism (SNP) markers were developed in the chromosome region of BLMR2 and a fine genetic map was constructed. Two molecular markers narrowed BLMR2 in a 53.37 kb region where six genes were annotated. Among the six annotated genes, BnaA10g11280D/BnaA10g11290D encoding a cytochrome P450 protein were predicted as the candidate of BLMR2. Based on the profiling of pathogen induced transcriptome, three expressed genes in the six annotated genes were identified while only cytochrome P450 showed upregulation. The candidate corresponds to the gene involved in the indole glucosinolate biosynthesis pathway and plant basal defense in Arabidopsis thaliana. The molecular markers identified in this study will allow the quick incorporation of the BLMR2 allele in rapeseed cultivars to enhance blackleg resistance.

Evaluation of Recombinase Polymerase Amplification Assay for Detecting Meloidogyne javanica

Meloidogyne javanica is one of the most widespread and economically important nematodes in many countries, including China. In this study, a recombinase polymerase amplification (RPA) assay was evaluated for the detection of M. javanica based on the sequences of a sequence-characterized amplified regions marker gene segment. The RPA assay specifically detected M. javanica from individual juvenile or adult female, M. javanica-induced galls, and nematodes in the soil samples. The detection limit of M. javanica RPA assay was 1 pg of purified genomic DNA, 0.01 adult female, or 0.1 second-stage juvenile, which was 10 times more sensitive than conventional PCR assay. Furthermore, combined with lateral flow dipstick (LFD), a visual detection method of LFD-RPA assay was developed, which is suitable for onsite surveys and routine diagnostics. Results indicate that the RPA assay is rapid, sensitive, and reliable for detection and molecular identification of M. javanica.

SCAR Marker for Identification and Discrimination of Commiphora wightii and C. myrrha

Commercially important Commiphora species are drought-tolerant plants and they are leafless for most of the year. Therefore, it is necessary to develop some molecular marker for the identification. Intended for that, in the present study, species-specific, sequence-characterized amplified regions (SCAR) markers were developed for proficient and precise identification of closely related species Commiphora wightii and C. myrrha, which may ensure the quality, safety, and efficacy of medicines made from these plants through adulterous mixing of these plants. Two species-specific RAPD amplicons were selected, gel-purified, cloned, and sequenced after screening of 20 RAPD primers. The sequence of 979 and 590 nucleotides (Genebank accession numbers K90051 and K90052) was used for development of 4 SCAR markers, namely, Sc1P, Sc1Pm, Sc2P, and Sc2Pm. Out of them, the Sc1Pm was specific for C. wightii, while Sc2P discriminated both the Commiphora species. These markers are first reported and will be useful for rapid identification of closely related Commiphora wightii and C. myrrha species.