Positional cloning of a Bombyx pink-eyed white egg locus reveals the major role of cardinal in ommochrome synthesis.

Ommochromes are major insect pigments involved in coloration of compound eyes, eggs, epidermis and wings. In the silkworm Bombyx mori, adult compound eyes and eggs contain a mixture of the ommochrome pigments such as ommin and xanthommatin. Here, we identified the gene involved in ommochrome biosynthesis by positional cloning of B. mori egg and eye color mutant pink-eyed white egg (pe). The recessive homozygote of pe has bright red eyes and white or pale pink eggs instead of a normal dark coloration due to the decrease of dark ommochrome pigments. By genetic linkage analysis, we narrowed down the pe-linked region to ~258 kb, containing 17 predicted genes. RNA sequencing analyses showed that the expression of one candidate gene, the ortholog of Drosophila haem peroxidase cardinal, coincided with egg pigmentation timing, similar to other ommochrome-related genes such as Bm-scarlet and Bm-re. In two pe strains, a common missense mutation was found within a conserved motif of B. mori cardinal homolog (Bm-cardinal). RNA interference-mediated knockdown and transcription activator-like effector nuclease (TALEN)-mediated knockout of the Bm-cardinal gene produced the same phenotype as pe in terms of egg, adult eye and larval epidermis coloration. A complementation test of the pe mutant with the TALEN-mediated Bm-cardinal-deficient strain showed that the mutant phenotype could not be rescued, indicating that Bm-cardinal is responsible for pe. Moreover, knockdown of the cardinal homolog in Tribolium castaneum also induced red compound eyes. Our results indicate that cardinal plays a major role in ommochrome synthesis of holometabolous insects.

Imaging of silkworm meiotic chromosome by atomic force microscopy.

Although structural information of mitotic chromosomes has been accumulated, little information is available for meiotic chromosome structures. Here, we applied atomic force microscopy (AFM) to investigate the ultrastructures of the silkworm, Bombyx mori, meiotic pachytene chromosome in its native state with nanometer scale resolution. Two levels of DNA folding were observed on the meiotic chromosome surface, 50-70 nm granules, which were considered to be 30 nm chromatin fibers, and spherical protrusions of 400-600 nm, which were considered to be chromomeres and arranged on the surface of the chromosome parallel to the chromosome longitudinal axis. These observations suggested that AFM study is an excellent approach for obtaining information concerning the silkworm pachytene chromosome higher order structure.