We also found 11 unique alleles linked to virulence, and six link

We also found 11 unique alleles linked to virulence, and six linked to avirulent isolates (Table 3). The unique allele GA-SSR7 210 bp HM781-36B in vivo was detected only within the highly pathogenic isolate T17G1 (27), to which 17 out of 19 differentials were susceptible. The 79 R. secalis isolates grouped into 64 distinct haplotypes by the seven loci, and distributed into two main clusters (Fig. 2). The distribution of these clusters by host showed that most isolates sampled from the

same host grouped together. Cluster I distributed the farthest from the second, and included five isolates (35, 76, 33, 32 and 75) that all originated from the Rihane host, but were genetically well differentiated. The second cluster was subdivided into 14 subgroups. The haplotypes (55, 44, 8, 2), (74, 49, 45, 23), (51, 7), (18, 16), (60, 19), (61, PD0325901 supplier 58, 43, 11) and (63, 29, 1) belonged to subgroups 1, 4, 5, 6, 11, 12 and 13, respectively, and were genetically similar. The unique 127 bp allele size of the TAC-SSR1 locus (Table 3) might have contributed to the genetic distinctiveness of pathotypes grouped in cluster I (Fig. 2). This allele was detected only within this set of isolates. The relationship between

variation in pathogenicity and microsatellite markers’ haplotype was assessed by comparing isolates with the same haplotype to their reaction spectra from the 19 differential cultivars (Table 4). A total of 25 isolates were compared, with two to four isolates having the same haplotype. The degree of coincidence ranged from 0.31 to 0.84, with a mean of 0.52. The highest coincidence of 0.84 was seen for the isolates T21H3 (61), T21E3 (58), clustered in subgroup 12 (Fig. 2), originating from the Zalfana population

(Table 1). Thus, microsatellite marker fingerprinting Metalloexopeptidase identified pathogenicity in 52% of the investigated isolates (Table 4). In this study, high pathogenicity and genetic variability at microsatellite loci was revealed for Tunisian R. secalis isolates collected from two different barley hosts: Rihane cv. and local barley landraces. This is consistent with the results from Bouajila et al. (2007), for molecular diversity in different agroecological zones by means of AFLP markers. We retraced patterns of pathogenicity within 79 Tunisian R. secalis isolates according to the reaction spectra of 19 differential cultivars (Fig. 1). This allowed classification into three virulence groups, with the isolate T10A1 (16) found to be the most virulent. Such a complex variation in pathogenicity creates a difficult environment for breeding resistance cultivars using major genes based on the gene-for-gene theory. We found that the resistance gene BRR2 carried by Astrix may be effective for breeding for resistance against scald, demonstrated by the low level of susceptibility of this cultivar (Table 2).

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