Plant trichomes serve as a highly suitable model for investigating cell differentiation at the single-cell level.The regulatory genes involved in unicellular trichome development in Arabidopsis thaliana have been intensively studied,but genes regulating multicellular trichome development in plants remain unclear.Here,we characterized Cucumis sativus(cucumber) trichomes as representative multicellular and unbranched structures,and identified Micro-trichome(Mict),using map-based cloning in an F_2 segregating population of7,936 individuals generated from a spontaneous mict mutant.In mict plants,trichomes in both leaves and fruits,are small,poorly developed,and denser than in the wild type.Sequence analysis revealed that a 2,649-bp genomic deletion,spanning the first and second exons,occurred in a plant-specific class I homeodomain-leucine zipper gene.Tissue-specific expression analysis indicated that Mict is strongly expressed in the trichome cells.Transcriptome profiling identified potential targets of Mict including putative homologs of genes known in other systems to regulate trichome development,meristem determinacy,and hormone responsiveness.Phylogenic analysis charted the relationships among putative homologs in angiosperms.Our paper represents initial steps toward understanding the development of multicellular trichomes. Plant trichomes serve as a highly suitable model for investigating cell differentiation at the single-cell level. The regulatory genes involved in unicellular trichome development in Arabidopsis thaliana have been intensively studied, but genes regulating multicellular trichome development in plants remain unclear. Here, we characterized Cucumis sativus (cucumber) trichomes as representative multicellular and unbranched structures, and identified Micro-trichome (Mict), using map-based cloning in an F2 segregating population of 7,936 individuals generated from a spontaneous mict mutant. In mict plants, trichomes in both leaves and fruits, are small, poorly developed, and denser than in the wild type. Sequence analysis revealed that a 2,649-bp genomic deletion, spanning the first and second exons, occurred in a plant-specific class I homeodomain-leucine zipper gene. Tissue-specific expression analysis indicated that Mict is strongly expressed in the trichome cells. Transcriptome profiling identified poten tial targets of Mict including putative homologs of genes known in other systems to regulate trichome development, meristem determinacy, and hormone responsiveness. Phylogenic analysis charted the relationships among putative homologs in angiosperms. Our paper represents initial steps toward understanding the development of multicellular trichomes.