Summary Capsaicinoids are responsible for the spicy flavor of pungent peppers (Capsicum). The cultivar CH‐19 Sweet is a non‐pungent pepper mutant derived from a pungent pepper strain, Capsicum annuum CH‐19. CH‐19 Sweet biosynthesizes capsaicinoid analogs, capsinoids. We determined the genetic and metabolic mechanisms of capsinoid biosynthesis in this cultivar. We analyzed the putative aminotransferase (pAMT) that is thought to catalyze the formation of vanillylamine from vanillin in the capsaicinoid biosynthetic pathway. Enzyme assays revealed that pAMT activity catalyzing vanillylamine formation was completely lost in CH‐19 Sweet placenta tissue. RT‐PCR analysis showed normal mRNA transcription of the pAMT gene; however, SNP analysis of the cDNA sequence showed a T nucleotide insertion at 1291 bp in the pAMT gene of CH‐19 Sweet. This insertion formed a new stop codon, TGA, that prevented normal translation of the gene, and the pAMT protein did not accumulate in CH‐19 Sweet as determined using Western blot analysis. We developed a dCAPS marker based on the T insertion in the pAMT gene of CH‐19 Sweet, and showed that the pAMT genotype co‐segregated with the capsinoid or capsaicinoid fruit phenotype in the F2 population. The T insertion was not found in other pungent and non‐pungent Capsicum lines, suggesting that it is specific to CH‐19 Sweet. CH‐19 Sweet’s pAMT gene mutation is an example of a nonsense mutation in a single gene that alters a secondary metabolite biosynthetic pathway, resulting in the biosynthesis of analogs. The dCAPS marker will be useful in selecting lines with capsinoid‐containing fruits in pepper‐breeding programs.
When inoculated with the dimorphic smut fungus Microbotryum violaceum (Pers.) G. Deml and Oberwinkler, the female flower of the dioecious plant Silene latifolia (Miller) E.H.L. Krause develops anther-like structures filled with spores instead of pollen grains. Using natural scanning electron microscopy, Nomarski interference microscopy, and fluorescence microscopy, we investigated the morphological modifications of the host plant resulting from this parasitism and the localization of smut hyphae in the flower bud. Flowers of infected plants lasted significantly longer than those of healthy plants, probably because the infection strengthened floral organs, such as the flower base and the anther filaments. Smut hyphae were observed throughout all organs of the young flower buds of infected plants, including sepals, petals, stamens, and pistil primordia. In healthy female flowers, anthers initiated sporogenous cell formation, but lacked parietal cell layers. By contrast, the parietal cell layers of infected female flowers differentiated into tapetal tissue, middle cell layers, and endothecial layers, as in the anthers of healthy male flowers. Smut spore formation in the infected anther was initiated in intercellular regions between the sporogenous cells, resulting in degeneration of premature sporogenous cells, tapetal tissue, and middle cell layers. The development of the endothecial layers and epidermis in the infected anther were morphologically normal.
Eukaryotic chromosomal ends are protected by telomeres, which are thought to play an important role in ensuring the complete replication of chromosomes. On the other hand, non-functional telomere-like repeats in the interchromosomal regions (interstitial telomeric repeats; ITRs) have been reported in several eukaryotes. In this study, we identified eight ITRs in the Arabidopsis thaliana genome, each consisting of complete and degenerate 300-to 1200-bp sequences. The ITRs were grouped into three classes (class IA-B, class II, and class IIIA-E) based on the degeneracy of the telomeric repeats in ITRs. The telomeric repeats of the two ITRs in class I were conserved for the most part, whereas the single ITR in class II, and the five ITRs in class III were relatively degenerated. In addition, degenerate ITRs were surrounded by common sequences that shared 70-100% homology to each other; these are named ITR-adjacent sequences (IAS). Although the genomic regions around ITRs in class I lacked IAS, those around ITRs in class II contained IAS (IASa), and those around five ITRs in class III had nine types of IAS (IASb, c, d, e, f, g, h, i, and j). Ten IAS types in classes II and III showed no significant homology to each other. The chromosomal locations of ITRs and IAS were not category-related, but most of them were adjacent to, or part of, a centromere. These results show that the A. thaliana genome has undergone chromosomal rearrangements, such as end-fusions and segmental duplications.
The satellite DNA (satDNA) on the ends of chromosomes has been isolated and characterized in the dioecious plant Silene latifolia. BAC clones containing large numbers of repeat units of satDNA in a tandem array were isolated to examine the clustering of the repeat units. satDNA repeat units were purified from each isolated BAC clone and sequenced. To investigate pairwise similarities among the repeat units, a phylogenetic tree was constructed using the neighbor-joining algorithm. The repeat units derived from 7 BAC clones were grouped into SacI, KpnI, #11F02, and #16E07 subfamilies. The SacI and KpnI subfamilies have been reported previously. Multicolored fluorescence in situ hybridization (FISH) using SacI or KpnI subfamily probes resulted in different signal intensities and locations at the chromosomal ends, indicating that each chromosomal end has a unique composition of subfamilies of satDNA. For example, the p arm of the X chromosome exhibited signal composition similar to that on the pseudo autosomal region (PAR) of the Y chromosome, but not to that on the q arm of the X chromosome. The satDNA has not been completely homogenized in the S. latifolia genome. Each subfamily is available for a probe of FISH karyotyping.
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