Diversity of Late Blight Resistance Genes in the VIR Potato Collection.

Late blight (LB) caused by the oomycete Phytophthora infestans (Mont.) de Bary is the greatest threat to potato production worldwide. Current potato breeding for LB resistance heavily depends on the introduction of new genes for resistance to P. infestans (Rpi genes). Such genes have been discovered in highly diverse wild, primitive, and cultivated species of tuber-bearing potatoes (Solanum L. section Petota Dumort.) and introgressed into the elite potato cultivars by hybridization and transgenic complementation. Unfortunately, even the most resistant potato varieties have been overcome by LB due to the arrival of new pathogen strains and their rapid evolution. Therefore, novel sources for germplasm enhancement comprising the broad-spectrum Rpi genes are in high demand with breeders who aim to provide durable LB resistance. The Genbank of the N.I. Vavilov Institute of Plant Genetic Resources (VIR) in St. Petersburg harbors one of the world's largest collections of potato and potato relatives. In this study, LB resistance was evaluated in a core selection representing 20 species of seven Petota series according to the Hawkes (1990) classification: Bulbocastana (Rydb.) Hawkes, Demissa Buk., Longipedicellata Buk., Maglia Bitt., Pinnatisecta (Rydb.) Hawkes, Tuberosa (Rydb.) Hawkes (wild and cultivated species), and Yungasensa Corr. LB resistance was assessed in 96 accessions representing 18 species in the laboratory test with detached leaves using a highly virulent and aggressive isolate of P. infestans. The Petota species notably differed in their LB resistance: S. bulbocastanum Dun., S. demissum Lindl., S. cardiophyllum Lindl., and S. berthaultii Hawkes stood out at a high frequency of resistant accessions (7-9 points on a 9-point scale). Well-established specific SCAR markers of ten Rpi genes-Rpi-R1, Rpi-R2/Rpi-blb3, Rpi-R3a, Rpi-R3b, Rpi-R8, Rpi-blb1/Rpi-sto1, Rpi-blb2, and Rpi-vnt1-were used to mine 117 accessions representing 20 species from seven Petota series. In particular, our evidence confirmed the diverse Rpi gene location in two American continents. The structural homologs of the Rpi-R2, Rpi-R3a, Rpi-R3b, and Rpi-R8 genes were found in the North American species other than S. demissum, the species that was the original source of these genes for early potato breeding, and in some cases, in the South American Tuberosa species. The Rpi-blb1/Rpi-sto1 orthologs from S. bulbocastanum and S. stoloniferum Schlechtd et Bché were restricted to genome B in the Mesoamerican series Bulbocastana, Pinnatisecta, and Longipedicellata. The structural homologs of the Rpi-vnt1 gene that were initially identified in the South American species S. venturii Hawkes and Hjert. were reported, for the first time, in the North American series of Petota species.

Genome-specific SCAR markers help solve taxonomy issues: a case study with Sinapis arvensis (Brassiceae, Brassicaceae).

PREMISE OF THE STUDY: Traditional taxonomy and nomenclature of Brassiceae (Brassicaceae) species do not reflect their phylogeny. Revision of the species and generic limits supported by extensive molecular data seems crucial. METHODS AND RESULTS: Genome-specific polymorphisms extracted from non-coding and coding sequences were used to develop 14 sequence characterized amplified region (SCAR) markers specific for the Brassica B genome. These SCARs were verified against 77 accessions of six U-triangle Brassica species and used to screen 23 accessions of seven wild Brassiceae species to test for their cross-species amplification. SCARs were found in all B-genome Brassica species and also in Sinapis arvensis. CONCLUSIONS: SCAR markers can be employed for discerning B-genome chromosomes in Brassica species and S. arvensis to reliably identify B-genome species and their natural hybrids. The combined molecular evidence supports the suggestion to revise the generic limits of Brassica and Sinapis.

The structure of two CONSTANS-LIKE1 genes in potato and its wild relatives.

Day length controls development in many plants. In Arabidopsis thaliana, the CONSTANS (CO) gene has been firmly established as a key component in the photoperiodic pathway of floral transition; less is known about CONSTANS-LIKE1 (COL1) orthologues of this gene in Arabidopsis and several other species. The CONSTANS protein comprises two B-box-type zinc fingers, CCT domain, and a variable middle region (MR) which corresponds to exon 2 in the COL1 genes of Solanum species. Solanum COL1 proteins are over 85% identical within the genus and about 50% similar to Arabidopsis CO. Comparative COL1 analysis in several cultivated and wild Solanum species discerned two gene variants, which differed in the structures of exon 2 and introns 1 and 2. In exon 2, two variants were primarily discerned by the numbers of AAC/AAT and CAA/CAG repeats coding for polyasparagine and polyglutamine tracts in MR; therefore two variants were dubbed short and long COL1 genes (sCOL1 and lCOL1). However, intron 1 in lCOL1 was shorter than in sCOL1 due to three indels, whereas intron 2 in available COL1 sequences was represented by three different variants. The temporal profiles of sCOL1 and lCOL1 expression in tuberosum potato dramatically differed under short and long day, and the level of sCOL1 expression exceeded that of lSOL1 by an order of magnitude. Both sCOL1 and lCOL1 were found in each Solanum genome under study and in each individual plant, and the ratio of their copy numbers was not related to plant ploidy and photoperiodic response. Evidently the evolution of two COL1 genes preceded Solanum speciation, and the day-length response of diverse Solanum genotypes does not stem from the primary COL1 structure.