Mapping QTLs for blight resistance and morpho-phenological traits in inter-species hybrid families of chestnut ( spp.).

Chestnut blight (caused by ), together with root rot (caused by ), has nearly extirpated American chestnut () from its native range. In contrast to the susceptibility of American chestnut, many Chinese chestnut () genotypes are resistant to blight. In this research, we performed a series of genome-wide association studies for blight resistance originating from three unrelated Chinese chestnut trees (Mahogany, Nanking and M16) and a Quantitative Trait Locus (QTL) study on a Mahogany-derived inter-species F2 family.

Defining the 'HoneySweet' insertion event utilizing NextGen sequencing and a de novo genome assembly of plum (Prunus domestica).

'HoneySweet' plum (Prunus domestica) is resistant to Plum pox potyvirus, through an RNAi-triggered mechanism. Determining the precise nature of the transgene insertion event has been complicated due to the hexaploid genome of plum. DNA blots previously indicated an unintended hairpin arrangement of the Plum pox potyvirus coat protein gene as well as a multicopy insertion event.

Dissecting Resistance to in Interspecific Hybrid Chestnut Crosses Using Sequence-Based Genotyping and QTL Mapping.

The soilborne oomycete -which causes root rot, trunk cankers, and stem lesions on an estimated 5,000 plant species worldwide-is a lethal pathogen of American chestnut () as well as many other woody plant species. is particularly damaging to chestnut and chinquapin trees ( spp.) in the southern portion of its native range in the United States due to relatively mild climatic conditions that are conductive to disease development.

The American cranberry: first insights into the whole genome of a species adapted to bog habitat.

Background: The American cranberry (Vaccinium macrocarpon Ait.) is one of only three widely-cultivated fruit crops native to North America- the other two are blueberry (Vaccinium spp.) and native grape (Vitis spp.

The first genetic map of the American cranberry: exploration of synteny conservation and quantitative trait loci.

The first genetic map of cranberry (Vaccinium macrocarpon) has been constructed, comprising 14 linkage groups totaling 879.9 cM with an estimated coverage of 82.2 %.

Mapping with a few plants: using selective mapping for microsatellite saturation of the Prunus reference map.

The concept of selective (or bin) mapping is used here for the first time, using as an example the Prunus reference map constructed with an almond x peach F2 population. On the basis of this map, a set of six plants that jointly defined 65 possible different genotypes for the codominant markers mapped on it was selected. Sixty-three of these joint genotypes corresponded to a single chromosomal region (a bin) of the Prunus genome, and the two remaining corresponded to two bins each.

Candidate gene database and transcript map for peach, a model species for fruit trees.

Peach (Prunus persica) is a model species for the Rosaceae, which includes a number of economically important fruit tree species. To develop an extensive Prunus expressed sequence tag (EST) database for identifying and cloning the genes important to fruit and tree development, we generated 9,984 high-quality ESTs from a peach cDNA library of developing fruit mesocarp. After assembly and annotation, a putative peach unigene set consisting of 3,842 ESTs was defined.

Comparison of peach and Arabidopsis genomic sequences: fragmentary conservation of gene neighborhoods.

We examined the degree of conservation of gene order in two plant species, Prunus persica (peach) and Arabidopsis thaliana (thale cress), whose lineages diverged more than 90 million years ago. In the three peach genomic regions studied, segments with a gene order congruent with A. thaliana were short (two to three genes in length); and for any peach region, corresponding segments were found in diverse locations in the A.

High-throughput targeted SSR marker development in peach (Prunus persica).

Simple sequence repeats (SSRs) have proven to be highly polymorphic, easily reproducible, codominant markers. However, developing an SSR map is very time consuming and expensive, and most SSRs are not specifically linked to gene loci of immediate interest. The ideal situation would be to combine a high-throughput, relatively inexpensive mapping technique with rapid identification of SSR loci in mapped regions of interest.