Role of hunchback in segment patterning of Locusta migratoria manilensis revealed by parental RNAi

In long germ embryos, all body segments are specified simultaneously during the blastoderm stage. In contrast, in short germ embryos, only the anterior segments are specified during the blastoderm stage, leaving the rest of the body plan to be specified later. The striking embryological differences between short and long germ segmentation imply fundamental differences in patterning at the molecular level. To gain insights into the segmentation mechanisms of short germ insects, we have investigated the role of the homologue of the Drosophila gap gene hunchback (hb) in a short germ insect Locusta migratoria manilensi by paternal RNA interference (RNAi). Phenotypes resulting from hb knockdown were categorized into three classes based on severity. In the most extreme case, embryos developed the most anterior structures only, including the labrum, antennae and eyes. The following conclusions were drawn: (i) L. migratoria manilensis hb (Lmm'hb) controls germ band morphogenesis and segmentation in the anterior region; (ii) Lmm'hb may function as a gap gene in a wide domain including the entire gnathum and thorax; and (iii) Lmm'hb is required for proper growth of the posterior germ band. These findings suggest a more extensive role for L. migratoria manilensis hunchback in anterior patterning than those described in Drosophila.     

Hunchback IS REQUIRED FOR ABDOMINAL IDENTITY SUPPRESSION AND GERMBAND GROWTH IN THE PARTHENOGENETIC EMBRYOGENESIS OF THE PEA APHID,Acyrthosiphon pisum

Aphid, a short germband insect, displays an embryogenesis different from that of long germband insect species. Furthermore, the development of its parthenogenetic and viviparous embryo is different from that of the embryo resulting from sexual reproduction. To better understand the genetic regulation of this type of embryogenesis, the functions of hunchback in asexual Acyrthosiphon pisum were investigated by parental RNAi. Microinjection of Aphb double‐stranded RNA yielded several defective phenotypes. Quantitative real‐time PCR analysis revealed that these defects resulted from reduction of Aphb mRNA level in injected aphids. All these results suggested that the hb gene in parthenogenetic and viviparous Acyrthosiphon pisum was involved in abdominal identity suppression and germband growth as its homologue does in sexual insects.     

Segmentation gene expression in the mothmidge Clogmia albipunctata (Diptera, Psychodidae) and other primitive dipterans

 To obtain a clearer understanding of the evolutionary transition between short- and long-germ modes of embryogenesis in insects, we studied the expression of two gap genes hunchback (hb) and Krüppel (Kr) as well as the pair-rule gene even-skipped (eve) in the dipteran Clogmia albipunctata (Nematocera, Psychodidae). This species has features of both short- and long-germ mode of embryogenesis. In Clogmia hb expression deviates from that known in Drosophila in two main respects: (1) it shows an extended dorsal domain that is linked to the large serosa anlage, and (2) it shows a terminal expression in the proctodeal region. These expression patterns are reminiscent of the hb expression pattern in the beetle Tribolium, which has a short germ mode of embryogenesis. Krüppel expression, on the other hand, was found to be rather similar to the Drosophila expression, both at early and late stages. eve expression starts with six stripes formed at blastoderm stage, while the seventh is only formed after the onset of gastrulation and germband extension. Surprisingly, no segmental secondary Eve stripes could be observed in Clogmia although such segmental stripes are known from higher dipterans, beetles and hymenopterans. We therefore also studied another nematoceran, Coboldia, to address this question and found that some segmental stripes form by intercalation as in Drosophila, although belatedly. Our results suggest that Clogmia embryogenesis, both with respect to morphological and molecular characteristics represents an intermediate between the long-germ mode known from higher dipterans such as Drosophila, and the short-germ mode found in more ancestral insects. Received: 24 August 1998 / Accepted: 29 October 1998     

Co-occupancy of two Pumilio molecules on a single hunchback NRE

Pumilio controls a number of processes in eukaryotes, including the translational repression of hunchback (hb) mRNA in early Drosophila embryos. The Pumilio Puf domain binds to a pair of 32 nucleotide (nt) Nanos response elements (NRE1 and NRE2) within the 3′ untranslated region of hb mRNA. Despite the elucidation of structures of human Pumilio Puf domain in complex with hb RNA elements, the nature of hb mRNA recognition remains unclear. In particular, the site that mediates regulation in vivo is significantly larger than the 8–10-nt RNA elements bound to single Puf molecules in crystal structures. Here we present biophysical and biochemical data that partially resolve the paradox. We show that each NRE is composed of two binding sites (Box A and Box B) and that two Puf domains can co-occupy a single NRE. The Puf domains have a higher affinity for the 3′ Box B site than the 5′ Box A site; binding to the intact NRE appears to be cooperative (at least in some experiments). We suggest that the 2 Pumilio:1 NRE complex is the functional regulatory unit in vivo.     

Optimization of parental RNAi conditions for hunchback gene in Locusta migratoria manilensis (Meyen)

An investigation on the optimization of parental RNA interference (RNAi) conditionsfor hunchback {hb) gene in Locusta migratoria manilensis (Meyen) was conducted.Double stranded RNA (dsRNA) corresponding to hb gene was injected into haemocoel offemale adults of L.migratoria manilensis.Embryos developed from the eggs laid by theinjected adults on the 7th day after eclosion showed observable effects of RNAi for hb.Thesilencing effect after delivery treatment of dsRNA for hb gene was maintained for moretha...     

Pretranslational control of Menkes disease gene expression

The gene for Menkes disease codes for a Cu-transporting ATPase that regulates Cu homeostasis in all tissues with the exception of adult liver. The basis for developmental or tissue-specific regulation at present is not understood. To learn if the regulation is associated with the promoter, we cloned and sequenced a 2.2 kb genomic DNA fragment flanking exon 1. When ligated into a pGL2 luciferase reporter gene construct, the 2.2 kb showed promoter activity, but not nearly to the extent of a 1.3 kb fragment previously reporter by Levinson et al. Sequence analysis of the nucleotides spanning the region between 1.3 kb and 2.2 kb revealed a 13-nucleotide motif ACACAAAAAAATA 2059 bp upstream from the start site that duplicated the `hunchback' binding site, a key site controlling developmental gene expression in Drosophila. Eliminating 129 bp containing the hunchback site (Hb) from the 5 end of the 2.2 kb stimulated promoter activity, suggesting the Hb site was basically suppressive. When ligated upstream of an SV40 and tested in SY5Y cells, however, the SV40 promoter activity was strongly stimulated, which conflicts with the site being suppressive. Mutating the site in the 2.2 kb weakened the promoter activity in SY5Y and HepG2 cells and a fragment with mutated sequence ligated upstream of the SV40 cancelled the activation of SV40 promoter activity. All data suggested the Hb site was a positive controlling site for Cu-ATPase expression. Nuclear extracts from SY5Y and HepG2 cells were observed to bind to a 106 bp probe with the Hb site in a gel-shift assay. Only SY5Y proteins, however, showed a slower moving shift band indicative of a secondary interaction. A probe with mutated sequences displayed the same shift pattern, suggesting other sites in the 106 bp DNA strand were also recognizing the nuclear proteins. A Southwestern analysis suggested that proteins of 125 kD, 70 kD, 50 kD and 42 kD bound to the wild type probe; a 60 kD and all with the exception of the 42 kD bound to the mutant probe. The data support the conclusion that the distal promoter of the Menkes disease gene contains elements that interact in combinatorial fashion to regulate Cu-ATPase expression and that tissue specificity may lie with the quantity or types of distinct DNA binding proteins in the nucleus.