Correlative changes in homoeotic and segmentation gene expression in Krüppel mutant embryos of Drosophila

Mutations of the segmentation gene Krüppel (Kr) cause deletions of contiguous sets of body segments from the middle region of the Drosophila embryo. We have monitored expression in situ of three other genes implicated in the establishment of the body plan, namely hairy (h), fushi tarazu (ftz) and engrailed (en), in mutant Kr embryos. Our results show that the pattern of expression of all three genes depends upon Kr⁺ activity and are consistent with a hierarchical model of segmentation gene activity. In addition, we find that the initial expression of the homoeotic selector gene Ultrabithorax(Ubx) follows a novel pattern in Kr^- embroys indicating a close integration of the spatial control of homoeotic and segmantation gene expression.     

Krüppel homolog (Kr h) is a dosage-dependent modifier of gene expression in Drosophila

A lethal mutation in the Krüppel homolog (Kr h) was isolated in screens of P-element insertion mutations for modifiers of white gene expression. The mutation occurs in the 5' untranslated region of the Kr h gene and causes a lightening of the eye colour for several alleles of white due to a decrease in white steady-state mRNA levels at pupal stages. Two related genes, scarlet and brown, were significantly affected as well in early pupae. Genetic analysis of different white alleles suggests that enhancer sequences are necessary for interaction with KR H. Thus, the Kr h gene is a member of the dosage-dependent hierarchy effective upon white.     

Gradients of Krüppel and knirps gene products direct pair-rule gene stripe patterning in the posterior region of the Drosophila embryo

Abdominal segmentation of the Drosophila embryo requires the activities of the gap genes Krüppel (Kr), knirps (kni), and tailless (tll). They control the expression of the pair-rule gene hairy (h) by activating or repressing independent cis-acting units that generate individual stripes. Kr activates stripe 5 and represses stripe 6, kni activates stripe 6 and represses stripe 7, and tll activates stripe 7. Kr and kni proteins bind strongly to h control units that generate stripes in areas of low concentration of the respective gap gene products and weakly to those that generate stripes in areas of high gap gene expression. These results indicate that Kr and kni proteins form overlapping concentration gradients that generate the periodic pair-rule expression pattern.     

Pole region-dependent repression of the Drosophila gap gene Krüppel by maternal gene products

We examined the protein domain of the gap gene Krüppel (Kr) in mutants that affect the establishment of different regions of the segment pattern along the longitudinal axis of the Drosophila embryo. Our data suggest that Kr provides cues for establishing the "central" pattern elements at the blastoderm stage, and that Kr activity is controlled by maternal effect genes acting at the poles. The formation of the Kr protein domain may involve ubiquitous activation of Kr gene expression which, however, is limited by region-specific repression through the action of the maternal anterior and posterior pattern organizer genes. In addition, the formation of the Kr protein domain depends on the activity of gap genes acting adjacent to the Kr domain, but it is independent of subordinate pair-rule gene activities.     

Changes in protein synthetic activity in early Drosophila embryos mutant for the segmentation gene Krüppel

We have identified early embryo proteins related to the segmentation gene Krüppel by [35S]methionine pulse labelling and two-dimensional gel electrophoresis. Protein synthesis differences shared by homozygous embryos of two Krüppel alleles when compared to heterozygous and wild-type embryos are reported. The study was extended to syncytial blastoderm stages by pulse labelling and gel analysis of single embryos, using Krüppel-specific proteins from gastrula stages as molecular markers for identifying homozygous Krüppel embryos. Localized expression of interesting proteins was examined in embryo fragments. The earliest differences detected at nuclear migration stages showed unregulated synthesis in mutant embryos of two proteins that have stage specific synthesis in normal embryos. At the cellular blastoderm stage one protein was not synthesized and two proteins showed apparent shifts in isoelectric point in mutant embryos. Differences observed in older embryos included additional proteins with shifted isoelectric points and a number of qualitative and quantitative changes in protein synthesis. Five of the proteins with altered rates of synthesis in mutant embryos showed localized synthesis in normal embryos. The early effects observed are consistent with the hypothesis that the Krüppel product can be a negative or positive regulator of expression of other loci, while blastoderm and gastrula stage shifts in isoelectric point indicate that a secondary effect of Krüppel function may involve post-translational modification of proteins.     

Analysis of maternal effect mutant combinations elucidates regulation and function of the overlap of hunchback and Krüppel gene expression in the Drosophila blastoderm embryo

The metameric organisation of the Drosophila embryo is generated early during development, due to the action of maternal effect and zygotic segmentation and homeotic genes. The gap genes participate in the complex process of pattern formation by providing a link between the maternal and the zygotic gene activities. Under the influence of maternal gene products they become expressed in distinct domains along the anteroposterior axis of the embryo; negative interactions between neighboring gap genes are thought to be involved in establishing the expression domains. The gap gene activities in turn are required for the correct patterning of the pair-rule genes; little is known, however, about the underlying mechanisms. We have monitored the distribution of gap and pair-rule genes in wild-type embryos and in embryos in which the anteroposterior body pattern is greatly simplified due to combinations of maternal effect mutations (staufen exuperantia, vasa exuperantia, vasa exuperantia, bicoid oskar, bicoid oskar torsolike, vasa torso exuperantia). We show that the domains of protein distribution of the gap genes hunchback and Krüppel overlap in wild-type embryos. Based on the analysis of the maternal mutant combinations, we suggest an explanation of how this overlap is generated. Furthermore, our data show that different constellations of gap gene activities provide different input for the pair-rule genes, and thus strongly suggest that the overlap of hunchback and Krüppel in wild-type is functional in the formation of the patterns of pair-rule genes.     

Regulatory interactions and role in cell type specification of the Malpighian tubules by the cut, Krüppel, and caudal genes of Drosophila.

Krüppel and caudal genes are both required for normal segmentation of the embryo, and the developmental regulatory gene cut is necessary for the normal specification of external sensory organs. These three genes are also expressed in the Malpighian tubules before and during differentiation. Two of the genes, Krüppel and cut, are known to be required for development of the tubules. We report that the absence of maternal and zygotic caudal function reduces their normal growth and elongation. Normal Krüppel function, which is known to be required for caudal expression, is also required for cut expression, while cut and caudal are expressed independently of each other. Cell type transformations of Malpighian tubules were studied by examining the effects of mutations on the expression of markers specific to Malpighian tubules, hindgut, or midgut of normal embryos. Loss of Krüppel activity confers hindgut characteristics on those cells that normally form the Malpighian tubules with all markers tested. Loss of cut function alters the expression of some markers but not others. The pathway of tissue specific gene regulation, apparently, branches beyond Krüppel to form at least a cut and a caudal branch.     

Recombinogenic activity of Pantoprazole? in somatic cells of Drosophila melanogaster

Pantoprazole^® is one of the leading proton pump inhibitors (PPIs) used inthe treatment of a variety of diseases related to the upper gastrointestinal tract.However, studies have shown an increased risk of developing gastric cancer,intestinal metaplasia and hyperplasia of endocrine cells with prolonged use. In thepresent study, the somatic mutation and recombination test (SMART) was employed todetermine the mutagenic effects of Pantoprazole on Drosophilamelanogaster. Repeated treatments with Pantoprazole were performed on72-hour larvae of the standard (ST) and high bioactivation (HB) crosses atconcentrations of 2.5, 5.0, and 10.0 μM. In addition, doxorubicin (DXR) wasadministered at 0.4 mM, as a positive control. When administered to ST descendants,total number of spots were statistically significant at 2.5 and 5.0 μMconcentrations. For HB descendants, a significant increase in the total number ofspots was observed among the marked transheterozygous (MH) flies. Through analysis ofbalancer heterozygous (BH) descendants, recombinogenic effects were observed at allconcentrations in descendants of the HB cross. In view of these experimentalconditions and results, it was concluded that Pantoprazole is associated withrecombinogenic effects in Drosophila melanogaster.