Interchromosomal duplications are especially important for the study of X-linked genes. Males inheriting a mutation in a vital X-linked gene cannot survive unless there is a wild-type copy of the gene duplicated elsewhere in the genome. Rescuing the lethality of an X-linked mutation with a duplication allows the mutation to be used experimentally in complementation tests and other genetic crosses and it maps the mutated gene to a defined chromosomal region. Duplications can also be used to screen for dosage-dependent enhancers and suppressors of mutant phenotypes as a way to identify genes involved in the same biological process. We describe an ongoing project in Drosophila melanogaster to generate comprehensive coverage and extensive breakpoint subdivision of the X chromosome with megabase-scale X segments borne on Y chromosomes. The in vivo method involves the creation of X inversions on attached-XY chromosomes by FLP-FRT site-specific recombination technology followed by irradiation to induce large internal X deletions. The resulting chromosomes consist of the X tip, a medial X segment placed near the tip by an inversion, and a full Y. A nested set of medial duplicated segments is derived from each inversion precursor. We have constructed a set of inversions on attached-XY chromosomes that enable us to isolate nested duplicated segments from all X regions. To date, our screens have provided a minimum of 78% X coverage with duplication breakpoints spaced a median of nine genes apart. These duplication chromosomes will be valuable resources for rescuing and mapping X-linked mutations and identifying dosage-dependent modifiers of mutant phenotypes. M ANY eukaryotes of biomedical and agricultural importance-including humans, other mammals, birds, and Drosophila-are heterogametic. Their sex chromosomes differ drastically in size and genetic composition. In species with X and Y chromosomes, males carry only one copy of each X-linked gene. This poses a serious challenge for experimental geneticists, because males inheriting a mutation in a vital X-linked gene die before they can be used in genetic crosses. In fact, the hemizygosity of X-linked genes in males has been a significant barrier to the functional analysis of many X-linked genes and is largely responsible for the poor genetic characterization of X chromosomes relative to autosomes in most organisms.The lethality of X-linked mutations can be rescued by providing a wild-type copy of the mutated gene elsewhere in the genome. This can be accomplished with a transgenic construct if the molecular identity of the mutated gene is known. In many cases, however, the mutated gene has not been identified and it is necessary to provide wildtype function with a multigene interchromosomal duplication, i.e., a segment of the X inserted in another chromosome. If the proximal and distal extents of the duplicated segment are known, phenotypic rescue maps the mutated gene to the defined X chromosome region.Multigene deletions can also be used to map X-linked mutations ...
Key messageThe choice of promoter regulating the selectable marker gene impacts transformation efficiency, copy number and the expression of selectable marker and flanking genes in maize.AbstractViral or plant-derived constitutive promoters are often used to regulate selectable marker genes. We compared two viral promoters, cauliflower mosaic virus (CaMV 35T) and sugarcane bacilliform virus (SCBV) with two plant promoters, rice actin1 (OsAct1) and maize ubiquitin 1 (ZmUbi1) to drive aryloxyalkanoate dioxygenase (aad-1) selectable marker gene in maize inbred line B104. ZmUbi1- and OsAct1-containing constructs demonstrated higher transformation frequencies (43.8 and 41.4%, respectively) than the two viral promoter constructs, CaMV 35T (25%) and SCBV (8%). Interestingly, a higher percentage of single copy events were recovered for SCBV (82.1%) and CaMV 35T (59.3%) promoter constructs, compared to the two plant-derived promoters, OsAct1 (40.0%), and ZmUbi1 (27.6%). Analysis of protein expression suggested that the viral promoter CaMV 35T expressed significantly higher AAD-1 protein (174.6 ng/cm2) than the OsAct1 promoter (12.6 ng/cm2) in T0 leaf tissue. When measured in T2 callus tissue, the two viral promoters both had higher expression and more variability than the two plant-derived promoters. A potential explanation for why viral promoters produce lower transformation efficiencies but higher percentages of low copy number events is discussed. In addition, viral promoters regulating aad-1 were found to influence the expression of upstream flanking genes in both T0 leaf and T2 callus tissue.
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