[Show abstract][Hide abstract] ABSTRACT: Zucchini yellow mosaic virus (ZYMV) is one of the most economically important potyviruses infecting cucurbit crops worldwide. Using a candidate gene approach, we cloned and sequenced eIF4E and eIF(iso)4E gene segments in watermelon. Analysis of the nucleotide sequences between the ZYMV-resistant watermelon plant introduction PI 595203 (Citrullus lanatus var. lanatus) and the ZYMV-susceptible watermelon cultivar 'New Hampshire Midget' ('NHM') showed the presence of single nucleotide polymorphisms (SNPs). Initial analysis of the identified SNPs in association studies indicated that SNPs in the eIF4E, but not eIF(iso)4E, were closely associated to the phenotype of ZYMV-resistance in 70 F(2) and 114 BC(1R) progenies. Subsequently, we focused our efforts in obtaining the entire genomic sequence of watermelon eIF4E. Three SNPs were identified between PI 595203 and NHM. One of the SNPs (A241C) was in exon 1 and the other two SNPs (C309A and T554G) were in the first intron of the gene. SNP241 which resulted in an amino acid substitution (proline to threonine) was shown to be located in the critical cap recognition and binding area, similar to that of several plant species resistance to potyviruses. Analysis of a cleaved amplified polymorphism sequence (CAPS) marker derived from this SNP in F(2) and BC(1R) populations demonstrated a cosegregation between the CAPS-2 marker and their ZYMV resistance or susceptibility phenotype. When we investigated whether such SNP mutation in the eIF4E was also conserved in several other PIs of C. lanatus var. citroides, we identified a different SNP (A171G) resulting in another amino acid substitution (D71G) from four ZYMV-resistant C. lanatus var. citroides (PI 244018, PI 482261, PI 482299, and PI 482322). Additional CAPS markers were also identified. Availability of all these CAPS markers will enable marker-aided breeding of watermelon for ZYMV resistance.
[Show abstract][Hide abstract] ABSTRACT: The three genomes of cucumber show different modes of transmission, nuclear DNA bi-parentally, plastid DNA maternally, and mitochondrial DNA paternally. The mosaic (MSC) phenotype of cucumber is associated with mitochondrial DNA rearrangements and is a valuable tool for studying mitochondrial transmission. A nuclear locus (Psm) has been identified in cucumber that controls sorting of paternally transmitted mitochondrial DNA. Comparative sequencing and mapping of cucumber and melon revealed extensive synteny on the recombinational and sequence levels near Psm and placed this locus on linkage group R of cucumber and G10 of melon. However, the cucumber genomic region near Psm was surprisingly monomorphic with an average of one SNP every 25 kb, requiring that a family from a more diverse cross is produced for fine mapping and eventual cloning of Psm. The cucumber ortholog of Arabidopsis mismatch repair (MSH1) was cloned and it segregated independently of Psm, revealing that this candidate gene is not Psm.
[Show abstract][Hide abstract] ABSTRACT: Sequencing of the onion (Allium cepa) genome is challenging because it has one of the largest nuclear genomes among cultivated plants. We undertook pilot sequencing of onion genomic DNA to estimate gene densities and investigate the nature and distribution of repetitive DNAs. Complete sequences from two onion BACs were AT rich (64.8%) and revealed long tracts of degenerated retroviral elements and transposons, similar to other larger plant genomes. Random BACs were end sequenced and only 3 of 460 ends showed significant (e < -25) non-organellar hits to the protein databases. The BAC-end sequences were AT rich (63.4%), similar to the completely sequenced BACs. A total of 499,997 bp of onion genomic DNA yielded an estimated mean density of one gene per 168 kb, among the lowest reported to date. Methyl filtration was highly effective relative to random shotgun reads in reducing frequencies of anonymous sequences from 82 to 55% and increasing non-organellar protein hits from 4 to 42%. Our results revealed no evidence for gene-dense regions and indicated that sequencing of methyl-filtered genomic fragments should be an efficient approach to reveal genic sequences in the onion genome.