The purpose of this study was to examine the potential utility of marker-assisted selection (MAS) based on storability-associated molecular markers in apple breeding and to provide genotype information for the markers Md-ACS1, Md-ACO1, and Md-PG1 in apple genetic resources as basic data for the use of breeding materials. We analyzed 750 apple genetic resources to assess the allelic composition of Md-ACS1 and Md-ACO1, which play roles in the ethylene biosynthesis pathway, and Md-PG1, which is involved in cell wall degradation. For 108 of the genetic resources used for genotyping, we measured fruit firmness using a texture analyzer (10 mm plunger) at harvest and after 20 days of room temperature (20~25℃) storage. Md-ACS1 and Md-PG1 were found to be associated with changes in fruit firmness (the difference between firmness at harvest and after storage), with ACS1-2/2, PG1-1/1, and PG1-2/2 showing the lowest changes in fruit firmness. In addition, we found that changes in fruit firmness were smallest in late-harvest species, even for the same genotype. In contrast, Md-ACO1 appeared to be unrelated to the storability of fruit. Of the 750 apple genetic resources screened, the genotypes ACS1-2/2, and PG1-1/1 or PG1-2/2 were detected in 3.6% of accessions, including ‘Fuji’, bud mutation cultivars of ‘Fuji’, ‘Chubu’, and ‘Iwakami’. The Md-ACS1 and Md-PG1 markers could have potential utility in assessments of storability and applied in MAS to improve the efficiency of apple breeding.

APETALA2/ethylene response factor (AP2/ERF) transcription factors are involved in biological and abiotic stress response, plant development, and growth. AP2/ERF genes are classified into five families (AP2, DREB, ERF, RAV, and soloist), and most genes belong to DREB and ERF families. So far, genomic analysis of DREB and ERF family genes of various plant species has been performed, and classifications based on the homology of AP2/ERF-specific DNA binding domain, arrangement of exons and introns, and similarity of group-specific conserved motifs have been conducted. These classifications provide plausible information for the prediction of AP2/ERF gene function. In this paper, an overview of the classification, structure, evolution, and function of AP2/ERF genes is described, and the functional properties and regulatory mechanisms of ERF family genes that have been identified are summarized by group according to the functional classification of Arabidopsis ERF family genes. This shows that group-specific conserved motifs of Arabidopsis ERF family genes are closely linked with group-specific functions and regulatory mechanisms, indicating that the effective functional prediction of ERF family genes through such a classification scheme can be usefully applied to the trait improvements of various plants.