P element mediated germ line transformation of Drosophila melanogaster with the Tc1 transposable DNA element from Caenorhabditis elegans

Questions relating to the origin and regulation of mobile genetic elements are currently of considerable interest. Since it is now possible to address more precisely issues concerning the entry, dispersion, and regulation of elements within a virgin genome, one approach that may afford a better understanding of transposable elements in general could be provided by interspecific DNA transformation. Therefore, the Tc1 transposable DNA element from Caenorhabditis elegans was chosen as a proposed invading element of the Drosophila melanogaster genome. The basis for this selection resided in the inherent structural and functional similarities, as well as sequence identities, between the Caenorhabditis element and elements innate to Drosophila (e.g., P, HB1, and Uhu). Initial investigations were carried out to define a clone carrying an intact Tc1 element. This Tc1 element was inserted into a P transposon vector and two P–Tc1–ry+ constructs, differing only in insert orientation, were identified. P element mediated germ line transfer was then used to generate a transformant that was genetically and molecularly identified as containing a single, structurally intact Tc1 element at cytological location 64C4-5 on the third chromosome. The single P[(Tc1, ry+)]SAS-B insertion was thereafter mobilized by using a P[ry+Δ2-3] element as a transposase source, and the genetic and molecular data suggested that the insertion had been successfully reintegrated to a variety of genomic locations. On the basis of genetic and molecular analyses, the Tc1 element in the P[(Tc1, ry+)] transformed stock is not highly unstable in germ line and somatic tissues.Key words: Tc1 transposable element, transformation, Drosophila melanogaster, Caenorhabditis elegans, P elements.

Molecular and genetic analysis of unc-7, a Caenorhabditis elegans gene required for coordinated locomotion.

Mutations in the Caenorhabditis elegans gene unc-7 confer an uncoordinated phenotype. Wild-type animals trace smooth, sinuous waves as they move; unc-7 mutants make irregular bends or kinks along their bodies, particularly when they move forward. The unc-7 locus has also been implicated in the nematode's response to volatile anesthetics. We have cloned unc-7 by transposon tagging: an unc-7 mutation was correlated with the insertion of the transposon Tc1, and reversion of the mutant phenotype was correlated with loss of the Tc1 element. We have physically mapped the region flanking the sites of Tc1 insertion and identified DNA rearrangements corresponding to eight additional unc-7 alleles. Northern analysis indicates that a 2.7-kb unc-7 message is present in all developmental stages but is most abundant in L1-L3 larvae. The 5' end of the message contains a trans-spliced leader SL1. An 18-kb intron is located upstream of the predicted translational start site of the gene, and DNA breakpoints of four gamma-ray-induced alleles were located within this intron. We determined the sequence of a cDNA corresponding to the unc-7 message. The message may encode a 60-kd protein whose amino acid sequence is unrelated to any other available protein sequence; a transmembrane location for the unc-7 protein is predicted. We predict from our analysis of unc-7 genetic mosaics that the unc-7 gene product is not required in muscle cells for wild-type coordination but is probably required in motor neurons (although a hypodermal role has not been excluded). We speculate that unc-7 may be involved in the function of neuronal ion channels.

A genetic mapping system in Caenorhabditis elegans based on polymorphic sequence-tagged sites.

We devised an efficient genetic mapping system in the nematode Caenorhabditis elegans which is based upon the differences in number and location of the transposable element Tc1 between the Bristol and Bergerac strains. Using the nearly completed physical map of the C. elegans genome, we selected 40 widely distributed sites which contain a Tc1 element in the Bergerac strain, but not in the Bristol strain. For each site a polymerase chain reaction assay was designed that can distinguish between the Bergerac Tc1-containing site and the Bristol "empty" site. By combining appropriate assays in a single reaction, one can score multiple sites within single worms. This permits a mutation to be rapidly mapped, first to a linkage group and then to a chromosomal subregion, through analysis of only a small number of progeny from a single interstrain cross.