Mutation of Drosophila melanogaster glass-like suppress expression of mini-white transgenes and dependence on their genomic environment

Pleiotropic recessive mutation glass-like (gl-l) found in region 8C-10E of the X chromosome was shown to cause glass-like eyes having no boundaries between facets and a nonuniform pigment distribution in the presence of the endogenous white gene. The gl-l mutation completely inhibited expression of the mini-white transgene contained in several constructs, but the effect depended on the site of construct integration in the genome. The mutation had no effect on the expression of the white transgene having the enhancer and flanked by insulators. The gl-l mutation did not affect the extent of mosaic eye pigmentation when a construct with mini-white was inserted in the telomeric or pericentric region. However, in most cases it completely inhibited the mosaic mini-white expression when cloned heterochromatic repeats were adjacent to the reporter gene in a construct. The gl-l gene was assumed to play a role in the formation of the chromatin structure, because the effect of its mutation on expression of the white transgene depended on the transgene insertion site, the presence of insulators or an enhancer in the vicinity of the transgene, and on the adjacent heterochromatic repeats.     

Inactivation of Reporter Genes by Cloned Heterochromatic Repeats of Drosophila melanogaster is Accompanied by Chromatin Compaction

Cloned Stellate heterochromatic repeats caused unstable mosaic inactivation (position effect variegation; PEV) of the reporter genemini-white. A number of known protein modifiers of the classical position effect induced by large heterochromatin blocks do not affect the expression of mini-white. This raises the question as to the specificity of chromatin compaction around the reporter gene. The inactivation of themini-white gene has been found to be accompanied by a decrease in its methylation catalyzed by Escherichia coli dam-methyltransferase expressed in the genome of Drosophila. However, no changes in the nucleosome organization of mini-whitehave been found.     

Red flag on the white reporter: a versatile insulator abuts the white gene in Drosophila and is omnipresent in mini-white constructs

Much of the research on insulators in Drosophila has been done with transgenic constructs using the white gene (mini-white) as reporter. Hereby we report that the sequence between the white and CG32795 genes in Drosophila melanogaster contains an insulator of a novel kind. Its functional core is within a 368 bp segment almost contiguous to the white 3′UTR, hence we name it as Wari (white-abutting resident insulator). Though Wari contains no binding sites for known insulator proteins and does not require Su(Hw) or Mod(mdg4) for its activity, it can equally well interact with another copy of Wari and with unrelated Su(Hw)-dependent insulators, gypsy or 1A2. In its natural downstream position, Wari reinforces enhancer blocking by any of the three insulators placed between the enhancer and the promoter; again, Wari–Wari, Wari–gypsy or 1A2–Wari pairing results in mutual neutralization (insulator bypass) when they precede the promoter. The distressing issue is that this element hides in all mini-white constructs employed worldwide to study various insulators and other regulatory elements as well as long-range genomic interactions, and its versatile effects could have seriously influenced the results and conclusions of many works.     

Human Matrix Attachment Regions Insulate Transgene Expression from Chromosomal Position Effects in Drosophila melanogaster

Germ line transformation of white⁻ Drosophila embryos with P-element vectors containing white expression cassettes results in flies with different eye color phenotypes due to position effects at the sites of transgene insertion. These position effects can be cured by specific DNA elements, such as the Drosophila scs and scs′ elements, that have insulator activity in vivo. We have used this system to determine whether human matrix attachment regions (MARs) can function as insulator elements in vivo. Two different human MARs, from the apolipoprotein B and α1-antitrypsin loci, insulated white transgene expression from position effects in Drosophila melanogaster. Both elements reduced variability in transgene expression without enhancing levels of white gene expression. In contrast, expression of white transgenes containing human DNA segments without matrix-binding activity was highly variable in Drosophila transformants. These data indicate that human MARs can function as insulator elements in vivo.     

The Heterochromatic ABO Locus May Overlap with the Region Containing Repeats Encompassing Mobile Elements andStellate Genes on the X Chromosome of Drosophila melanogaster

A deficiency of certain heterochromatic regions (ABO loci) of various chromosomes dramatically distorts the early embryo development in the progeny of females carrying mutation in the abnormal oocyte (abo) gene, which is located in euchromatin of chromosome 2. One ABO locus (X-ABO) is in X-heterochromatin distal to the nucleolus organizer. A cluster of the Stellate repeats is located in the same heterochromatic block. Deletions of various fragments from distal heterochromatin were tested for the effect on expression of the abo mutation. The X-ABO locus was assigned to X-chromosomal heterochromatin segment h26 and may include repeats consisting mostly of mobile elements and defective Stellate copies. A major part of the regular Stellate tandem repeats proved to be distal of the X-ABO locus.     

Characterization of sequences associated with position-effect variegation at pericentric sites in Drosophila heterochromatin

In a variety of organisms, euchromatic genes brought into juxtaposition with pericentric heterochromatin show position-effect variegation (PEV), a silencing of gene expression in a subset of the cells in which the gene is normally expressed. Previously, a P-element mobilization screen identified transgenic Drosophila stocks showing PEV of an hsp70-white ⁺ reporter gene; transgenes in many of these stocks map to the chromocenter of polytene chromosome. A screen at an elevated temperature identified two stocks that under standard culture temperatures show complete repression of the hsp70-white ⁺ transgene. The transgenes in both cases map to the chromocenter of polytene chromosomes. Different types of middle repetitive elements are adjacent to seven pericentric transgenes; unique sequences are adjacent to two of the perimetric transgenes. All of the transgenes show suppression of PEV in response to a mutation in the gene encoding heterochromatin protein 1 (HP1). This suppression correlates with a more accessible chromatin structure. The results indicate that a pericentric transgene showing PEV can be associated with different types of DNA sequences, while maintaining a common association with the chromosomal protein HP1. Received: 15 January 1998; in revised form: 27 May 1998 / Accepted: 4 September 1998     

Hairy Root-activation Tagging: a High-throughput System for Activation Tagging in Transformed Hairy Roots

Activation tagging is a powerful technique for generating gain-of-function mutants in plants. We developed a new vector system for activation tagging of genes in “transformed hairy roots”. The binary vector pHR-AT (Hairy Root-Activation Tagging) and its derivative pHR-AT-GFP contain a cluster of rol (rooting locus) genes together with the right border facing four tandem repeats of the cauliflower mosaic virus (CaMV) 35S enhancer element on the same T-DNA. Transformation experiments using Arabidopsis, potato, and tobacco as model plants revealed that upon inoculating plants with Agrobacterium tumefaciens harboring these vectors, a large number of independently transformed roots could be induced from explants within a short period of time, and root culture lines were subsequently established. Molecular analyses of the pHR-AT-GFP-transformed Arabidopsis lines showed that expression of the genes adjacent to the T-DNA insertion site was significantly increased. This system may facilitate application of the activation-tagging approach to plant species that are recalcitrant to the regeneration of transgenic plants. High-throughput metabolic profiling of activation-tagged root culture lines will offer opportunities for identifying regulatory or biosynthetic genes for the production of valuable secondary metabolites of interest.