Clustering of mandibular organ-inhibiting hormone and moult-inhibiting hormone genes in the crab, Cancer pagurus, and implications for regulation of expression

Abstract

Development and reproduction of crustaceans is regulated by a combination of neuropeptide hormones, ecdysteroids (moulting hormones) and the isoprenoid, methyl farnesoate (MF), the unepoxidised analogue of insect juvenile hormone-III (JH-III). MF and the ecdysteroids are respectively synthesised under the negative control of the sinus gland-derived mandibular organ-inhibiting hormones (MO-IHs) and moult-inhibiting hormone (MIH) that are produced in eyestalk neural ganglia. Previous work has demonstrated the existence of two isoforms of MO-IH, called MO-IH-1 and -2, that differ by a single amino acid in the mature peptide and one in the putative signal peptide. To study the structural organisation of the crab MIH and MO-IH genes, a genomic DNA library was constructed from DNA of an individual female crab and screened with both MO-IH and MIH probes. The results from genomic Southern blot analysis and library screening indicated that the Cancer pagurus genome contains at least two copies of the MIH gene and three copies of the MO-IH genes. Upon screening, two types of overlapping genomic clone were isolated. Each member of one type of genomic clone contains a single copy of each of the convergently transcribed MO-IH-1 and MIH genes clustered within 6.5 kb. The other type contains only the MO-IH-2 gene, which is not closely linked to an MIH gene. There are three exons and two introns in all MIH and MO-IH genes analysed. The exon–intron boundary of the crab MIH and MO-IH genes follows Chambon's rule (GT–AG) for the splice donor and acceptor sites. The first intron occurs within the signal peptide region and the second intron occurs in the coding region of the mature peptide. Sequence analysis of upstream regions of MO-IH and MIH genes showed that they contained promoter elements with characteristics similar to other eukaryotic genes. These included sequences with high degrees of similarity to the arthropod initiator, TATA box and cAMP response element binding protein. Additionally, putative CF1/USP and Broad Complex Z2 transcription factor elements were found in the upstream regions of MIH and MO-IH genes respectively. The implications of the presence of the latter two putative transcription factor binding-elements for control of expression of MIH and MO-IH genes is discussed. Phylogenetic analysis and gene organisation show that MO-IH and MIH genes are closely related. Their relationship suggests that they represent an example of evolutionary divergence of crustacean hormones.