Nancy T. Eannetta

Identification, Analysis, and Utilization of Conserved Ortholog Set Markers for Comparative Genomics in Higher Plants

We have screened a large tomato EST database against the Arabidopsis genomic sequence and report here the identification of a set of 1025 genes (referred to as a conserved ortholog set, or COS markers) that are single or low copy in both genomes (as determined by computational screens and DNA gel blot hybridization) and that have remained relatively stable in sequence since the early radiation of dicotyledonous plants. These genes were annotated, and a large portion could be assigned to putative functional categories associated with basic metabolic processes, such as energy-generating processes and the biosynthesis and degradation of cellular building blocks. We further demonstrate, through computational screens (e.g., against a Medicago truncatula database) and direct hybridization on genomic DNA of diverse plant species, that these COS markers also are conserved in the genomes of other plant families. Finally, we show that this gene set can be used for comparative mapping studies between highly divergent genomes such as those of tomato and Arabidopsis. This set of COS markers, identified computationally and experimentally, may further studies on comparative genomes and phylogenetics and elucidate the nature of genes conserved throughout plant evolution.

cDNA cloning and expression of potato polyphenol oxidase

Polyphenol oxidases (PPOs) of plants are copper metalloproteins which catalyze the oxidation of mono- and o-diphenols to o-diquinones. Although PPOs are believed to be primarily responsible for the deleterious browning of many fruit and vegetable crops and are thought to be involved in plant-pest interactions, direct evidence for these roles is lacking. We report the cloning of two PPO cDNAs from Solanum tuberosum leaves. These cDNAs exhibit 97% and 98% sequence similarity at the DNA and deduced amino acid levels, respectively. Putative copper-binding regions of both cDNAs are very similar to those of mammalian, bacterial and Neurospora tyrosinases. Both leaf PPO cDNAs appear to encode polypeptides which are processed to a mature molecular weight of 57000. In potato leaves, petioles, roots, and flowers, PPO is encoded by ca. 2 kb transcripts. Leaf PPO mRNA is developmentally regulated and only detectable in young foliage. In contrast, the protein profile of immunologically detectable PPO remains constant from the apical node through the eleventh leaf node.

Organisation of the tomato polyphenol oxidase gene family

We report the isolation and characterization of seven nuclear genes encoding polyphenol oxidase (PPO) in tomato (Lycopersicon esculentum cv. VFNT Cherry). The seven genes (PPOs A, A′, B, C, D, E and F) fall into three structural classes (I, II, and III) based on Eco RI and Hind III restriction fragment length polymorphisms (RFLP). RFLP mapping and PFGE analysis demonstrated that the genes reside on chromosome 8, and may be clustered within a 165 kb region. Phage insert mapping demonstrated PPO E and PPO F (both class III), and PPOs B, D and A (classes I, II and I respectively) are grouped within separate 12.4 kb clusters. The complete nucleotide sequence was determined for each gene. Comparison to cDNAs revealed that the PPOs lack introns. A transcript of about 2 kb is expected for each PPO. Each PPO possesses a region encoding a transit peptide characteristic of polypeptides targeted to the thylakoid lumen. Predicted precursor polypeptides range in mass from 66 to 71 kDa and predicted mature polypeptides range from 57 to 62 kDa. All the PPOs encode two putative copper-binding sites characteristic of bacterial, fungal and mammalian tyrosinases. Five of the seven PPOs possess divergent DNA sequences in their 5′ promoter regions. These flanking sequence differences may regulate the differential expression of PPO genes.

Candidate gene analysis of anthocyanin pigmentation loci in the Solanaceae

Crop species in the Solanaceae, which includes tomato (Lycopersicon esculentum), potato (Solanum tuberosum), pepper (Capsicum spp.), and eggplant (S. melongena), exhibit natural variation in the types, levels, and tissue-specific expression patterns of anthocyanin pigments. While the identities of the genes underpinning natural variation in anthocyanin traits in these crops are largely unknown, many structural genes and regulators of anthocyanin biosynthesis have been isolated from the solanaceous ornamental species Petunia. To identify candidate genes that may correspond to loci controlling natural variation in the four crops, 13 anthocyanin-related genes were localized on a tomato F2 genetic map. Gene map positions were then compared to mapped mutants in tomato and through comparative genetic maps to natural variants in potato, eggplant, and pepper. Similar map positions suggest that the tomato mutants anthocyaninless, entirely anthocyaninless, and anthocyanin gainer correspond to flavonoid 3′5′-hydroxylase (f3′5′h), anthocyanidin synthase, and the Petunia Myb domain trancriptional regulatory gene an2, respectively. Similarly potato R, required for the production of red pelargonidin-based pigments, P, required for production of purple delphinidin-based pigments, and I, required for tissue-specific expression in tuber skin, appear to correspond to dihydroflavonol 4-reductase, f3′5′h and an2, respectively. The map location of an2 also overlaps pepper A and eggplant fap10.1, lla10.1, lra10.1, sa10.1, pa10.1 and ca10.1, suggesting that a homologous regulatory locus has been subjected to parallel selection in the domestication of many solanaceous crops. To test the hypothesis that tomato anthocyaninless corresponds to f3′5′h, a portion of the gene was sequenced. A premature stop codon was observed in an anthocyaninless mutant, but not in wild-type.

A detailed synteny map of the eggplant genome based on conserved ortholog set II (COSII) markers

We report herein the mapping of 115 PCR-based orthologous markers, including 110 conserved ortholog set or COSII markers, on the reference RFLP map of eggplant. The result permitted inference of a detailed syntenic relationship between the eggplant and tomato genomes. Further, the position of additional 522 COSII markers was inferred in the eggplant map via eggplant-tomato synteny, bringing the total number of markers in the eggplant genome to 869. Since divergence from their last common ancestor approximately 12 million years ago, the eggplant and tomato genomes have become differentiated by a minimum number of 24 inversions and 5 chromosomal translocations, as well as a number of single gene transpositions possibly triggered by transposable elements. Nevertheless, the two genomes share 37 conserved syntenic segments (CSSs) within which gene/marker order is well preserved. The high-resolution COSII synteny map described herein provides a platform for cross-reference of genetic and genomic information (including the tomato genome sequence) between eggplant and tomato and therefore will facilitate both applied and basic research in eggplant.

Comparative fine mapping of fruit quality QTLs on chromosome 4 introgressions derived from two wild tomato species

Despite their unsuitability for agricultural production, the wild relatives of crop species represent a largely untapped resource of novel QTLs potentially useful for crop plant improvement. In this regard, previous introgression studies, involving several different wild tomato species, have shown that the long arm of chromosome 4 contains QTLs for many horticulturally important traits including soluble solids content, fruit shape, lycopene content and biochemical composition. However, these earlier studies were unable to determine how many genes control these traits and whether genes affecting the same character from different wild species are allelic or not. In an effort to shed light on these issues,we have constructed a series of lines containing small, overlapping introgressions for portions of the long arm of chromosome 4 from L. peruvianum and L. hirsutum and tested these lines in replicated field trials. The results provide evidence for multiple, non-allelic loci controlling soluble solids and fruit weight. They also show that the loci controlling some traits (e.g. fruit shape, fruit weight, epidermal reticulation) co-localize to the same portions of chromosome 4, a result that maybe attributed to pleiotropy and/or gene dense areas with lower than average recombination. The implications of these finding for molecular breeding and utilization of exotic germplasm are discussed.

Development and application of a suite of non-pungency markers for the Pun1 gene in pepper (Capsicum spp.)

Pungency in peppers is due to the presence of capsaicinoid molecules, which are only produced in Capsicum species. The major gene Pun1 is required for the production of capsaicinoids. Three distinct mutant alleles of Pun1 have been found in three cultivated Capsicum species, one of which has been widely utilized by breeders. Although these mutations have been previously identified, a robust collection of molecular markers for the set of alleles is not available. This has been hindered by the existence of at least one paralogous locus that tends to amplify with Pun1. We present a suite of markers that can differentiate the four Pun1 alleles and test them on a diverse panel of pepper lines and in an F2 population segregating for pungency. These markers will be useful for pepper breeding, germplasm characterization, and seed purity testing.

Solanum berthaultii trichomes contain unique polyphenoloxidases and a peroxidase

Abstract Glandular trichomes of Solanum berthaultii leaves contain two unique forms of polyphenoloxidase (α- and β-PPO) and a separate peroxidase. The β-PPO appeared to be a polymer of α-PPO and exhibited a similar K m but an apparently higher specific activity with chlorogenic acid and caffeic acid. These data are directly related to studies on the insect defensive properties of the trichomes.