Tcl transposition and mutator activity in a Bristol strain of Caenorhabditis elegans

Summary In most strains of Caenorhabditis elegans with a low copy number of Tc1 transposable elements, germline transposition is rare or undetectable. We have observed low-level Tel transposition in the genome of the C. elegans var. Bristol strain KR579 (unc-13[e51]) resulting in an increase in Tc1 copy number and subsequent mutator activity. Examination of genomic blots from KR579 and KR579derived strains revealed that more Tc1-hybridizing bands were present than in other Bristol strains. A novel Tc1-hybridizing fragment was cloned from a KR579-derived strain. Unique sequence DNA flanking the Tc1 element identified a 1.6 kb restriction fragment length difference between the KR579 and N2 strains consistent with a Tc1 insertion at a new genomic site. The site of insertion of this Tel was sequenced and is similar to the published Tel insertion site consensus sequence. Several isolates of KR579 were established and maintained on plates for a period of 3 years in order to determine if Tc1 copy number would continue to increase. In one isolate, KR1787, a further increase in Tc1 copy number was observed. Examination of the KR1787 strain has shown that it also exhibits mutator activity as assayed by the spontaneous mutation frequency at the unc-22 (twitcher) locus. The KR579 strain differs from most low copy number strains in that it exhibits low-level transposition which has developed into mutator activity.     

Somatic excision of transposable element Tc1 from the Bristol genome of Caenorhabditis elegans.

We investigated the ability of the transposable element Tc1 to excise from the genome of the nematode Caenorhabditis elegans var. Bristol N2. Our results show that in the standard lab strain (Bristol), Tc1 excision occurred at a high frequency, comparable to that seen in the closely related Bergerac strain BO. We examined excision in the following way. We used a unique sequence flanking probe (pCeh29) to investigate the excision of Tc1s situated in the same location in both strains. Evidence of high-frequency excision from the genomes of both strains was observed. The Tc1s used in the first approach, although present in the same location in both genomes, were not known to be identical. Thus, a second approach was taken, which involved the genetic manipulation of a BO variant, Tc1(Hin). The ability of this BO Tc1(Hin) to excise was retained after its introduction into the N2 genome. Thus, we conclude that excision of Tc1 from the Bristol genome occurs at a high frequency and is comparable to that of Tc1 excision from the Bergerac genome. We showed that many Tc1 elements in N2 were apparently functionally intact and were capable of somatic excision. Even so, N2 Tc1s were prevented from exhibiting the high level of heritable transposition displayed by BO elements. We suggest that Bristol Tc1 elements have the ability to transpose but that transposition is heavily repressed in the gonadal tissue.     

Isolation and mapping of DNA probes within the linkage group I gene cluster of Caenorhabditis elegans

We have isolated probes for DNA polymorphisms across the linkage group I gene cluster in Caenorhabditis elegans, using Tc1-linkage selection. The probes detect strain polymorphism between the wild-type strains of var. Bristol and var. Bergerac. As a result of mapping the sites hP4, hP5, hP6, hP7, hP9, and sPl, more than 1000 kilobases (kb) of cloned cosmid DNA has been positioned on the genetic map. We found there is more DNA per map unit in the center of the gene cluster than expected on the basis of the genomic average. Furthermore, the amount is not constant across the entire region but reaches a peak in the hP9 unc-13 interval. To find the coding regions, we examined DNA cross-homology between two species, Caenorhabditis elegans and Caenorhabditis briggsae. Approximately one-third of the DNA in the hP5 hP9 interval was examined for coding regions and 21 sequences were identified within 318 kb of DNA.     

Isolation and sequence analysis ofCaenorhabditis briggsae repetitive elements related to theCaenorhabditis elegans transposon Tc1

Summary We have identified two repetitive element families in the genome of the nematodeCaenorhabditis briggsae with extensive sequence identity to theCaenorhabditis elegans transposable element Tc1. Five members each of the TCb1 (previously known as Barney) and TCb2 families were isolated by hybridization to a Tc1 probe. Tc1-hybridizing repetitive elements were grouped into either the TCb1 or TCb2 family based on cross-hybridization intensities among theC. briggsae elements. The genomic copy number of the TCb1 family is 15 and the TCb2 family copy number is 33 in theC. briggsae strain G16. The two transposable element families show numerous genomic hybridization pattern differences between twoC. briggsae strains, suggestive of transpositional activity. Two members of the TCb1 family, TCb1#5 and TCb1#10, were sequenced. Each of these two elements had suffered an independent single large deletion. TCb1#5 had a 627-bp internal deletion and TCb1#10 had lost 316 bp of one end. The two sequenced TCb1 elements were highly conserved over the sequences they shared. A 1616-bp composite TCb1 element was constructed from TCb1#5 and TCb1#10. The composite TCb1 element has 80-bp terminal inverted repeats with three nucleotide mismatches and two open reading frames (ORFs) on opposite strands. TCb1 and the 1610-bp Tc1 share 58% overall nucleotide sequence identity, and the greatest similarity occurs in their ORF1 and inverted repeat termini.     

Cloning within the unc-43 to unc-31 interval (linkage group IV) of the Caenorhabditis elegans genome using Tc1 linkage selection

The region around the twitcher gene, unc-22, flanked by unc-43 on the left and by unc-31 on the right, has been intensively studied in our laboratory over the period of the last 8 years. In this paper we describe the identification and isolation of probes specific for several restriction fragment length differences (RFLDs) which lie within this region. Many RFLDs in Caenorhabditis elegans are caused by the insertion of a transposable element, Tc1. The method we used involved the isolation of Tc1-containing genomic fragments. These were recovered from a lambda gt 10 library of DNA from a specially constructed genetic strain containing the unc-43 to unc-31 interval from the BO strain and the rest of the genome from N2. Because the BO strain is rich in Tc1 insertion sites and the N2 strain has few, the majority of Tc1-bearing genomic fragments in the constructed strain were derived from the unc-22 region. Of nine such Tc1-bearing genomic fragments isolated, six were found which mapped within the region of interest. The 350 kilobases of genomic sequences isolated as a result of these studies are being used to study the molecular organization of this region. The method described here for Tc1 linkage selection is one that is rapid, general, and may be targeted to any genetically characterized region of the C. elegans genome.     

The Ds1 controlling element family in maize andTripsacum

Summary Hybridization experiments indicated that the maize genome contains a family of sequences closely related to the Ds1 element originally characterized from theAdh1-Fm335 allele of maize. Examples of these Ds1-related segments were cloned and sequenced. They also had the structural properties of mobile genetic elements, i.e., similar length and internal sequence homology with Ds1, 10- or 11-bp terminal inverted repeats, and characteristic duplications of flanking genomic DNA. All sequences with 11-bp terminal inverted repeats were flanked by 8-bp duplications, but the duplication flanking one sequence with 10-bp inverted repeats was only 6 bp. Similar Ds1-related sequences were cloned fromTripsacum dactyloides. They showed no more divergence from the maize sequences than the individual maize sequences showed when compared with each other. No consensus sequence was evident for the sites at which these sequences had inserted in genomic DNA.     

Evidence for a transposon in caenorhabditis elegans

The C. elegans genome contains a 1.7 kb repeated DNA sequence (Tc1) that is present in different numbers in various strains. In strain Bristol and 10 other strains analyzed, there are 20 ± 5 copies of Tc1, and these are located at a nearly constant set of sites in the DNA. In Bergerac, however, there are 200 ± 50 interspersed copies of Tc1 that have arisen by insertion of Tc1 elements into new genomic sites. The interspersed copies of Tc1 have a conserved, nonpermuted structure. The structure of genomic Tc1 elements was analyzed by the cloning of a single Tc1 element from Bergerac and the comparison of its structure with homologous genomic sequences in Bristol and Bergerac. Tc1 elements at three sites analyzed in Bergerac undergo apparently precise excision from their points of insertion at high frequency.     

A second gene in a Balbiani ring. Chironomus salivary glands contain a 6.5-kb poly(A)+ RNA that is transcribed from a hierarchy of tandem repeated sequences in Balbiani ring 1

A second gene has been discovered at a previously studied Balbiani ring in Chironomus. Northern hybridizations demonstrated that cDNA clone pCt35 originated from a salivary gland specific 6.5-kilobase (kb) RNA that was abundant, nonribosomal, and apparently poly(A)+. pCt35 had a 120-base pair (bp) insert with 1.6 copies of a 75-bp sequence that contained two open reading frames. Southern hybridizations indicated that pCt35 was homologous to at least a 4-kb block of genomic DNA organized as a hierarchy of 150- and 300-bp tandem repeats. In situ hybridization localized these sequences to Balbiani ring 1. From these results we postulated that a 6.5-kb RNA gene may have evolved by stepwise duplication and amplification of a 75-bp ancestral sequence.     

Role of a phenazine antibiotic from Pseudomonas fluorescens in biological control of Gaeumannomyces graminis var. tritici.

Pseudomonas fluorescens 2-79 (NRRL B-15132) and its rifampin-resistant derivative 2-79RN10 are suppressive to take-all, a major root disease of wheat caused by Gaeumannomyces graminis var. tritici. Strain 2-79 produces the antibiotic phenazine-1-carboxylate, which is active in vitro against G. graminis var. tritici and other fungal root pathogens. Mutants defective in phenazine synthesis (Phz-) were generated by Tn5 insertion and then compared with the parental strain to determine the importance of the antibiotic in take-all suppression on wheat roots. Six independent, prototrophic Phz- mutants were noninhibitory to G. graminis var. tritici in vitro and provided significantly less control of take-all than strain 2-79 on wheat seedlings. Antibiotic synthesis, fungal inhibition in vitro, and suppression of take-all on wheat were coordinately restored in two mutants complemented with cloned DNA from a 2-79 genomic library. These mutants contained Tn5 insertions in adjacent EcoRI fragments in the 2-79 genome, and the restriction maps of the region flanking the insertions and the complementary DNA were colinear. These results indicate that sequences required for phenazine production were present in the cloned DNA and support the importance of the phenazine antibiotic in disease suppression in the rhizosphere.     

Isolation of a variant family of mouse minor satellite DNA that hybridizes preferentially to chromosome 4

Two cosmids (HRS-1 and HRS-2) containing mouse minor satellite DNA sequences have been isolated from a mouse genomic library. In situ hybridization under moderate stringency conditions to metaphase chromosomes from RCS-5, a tumor cell line derived from the SJL strain, mapped both HRS-1 and HRS-2 to the centromeric region of chromosome 4. Sequence data indicate that these cloned minor satellite DNA sequences have a basic higher order repeat of 180 bp, composed of three diverged 60-bp monomers. Digestion of mouse genomic DNA with several restriction enzymes produces a ladder of minor satellite fragments based on a 120-bp repeat. The restriction enzyme NlaIII (CATG) digests all the minor satellite DNA into three prominent bands of 120, 240, and 360 bp and a weak band of 180 bp. Thus, the majority of minor satellite sequences in the genome are arranged in repeats based on a 120-bp dimer, while the family of minor satellite sequences described here represents a rare variant of these sequences. Our results raise the possibility that there may be other variant families of minor satellites analogous to those of alphoid DNA present in humans.     

Molecular cloning of a gene region from Bradyrhizobium japonicum essential for lipopolysaccharide synthesis

The gene region cloned from a lipopolysaccharide (LPS) mutant carrying the Tn5 and flanking DNA sequences was used as a probe to screen a gene bank prepared from wild-type Bradyrhizobium japonicum strain 61A101C and to isolate the corresponding wild-type LPS-gene region. By cross-hybridization experiments the LPS-gene region did not appear to be closely linked to previously cloned nodulation genes. A detailed restriction map of the LPS-gene region (5.5-kb EcoRI genomic fragment) was established and the mutation site was localized to be in a 300-bp PvuI/PstI restriction fragment. In genomic Southern-blot analysis of various rhizobia, the LPS-gene region was found to be conserved among all the slow-growing bradyrhizobia, but not the fast-growing rhizobia. The different groups of slow-growing bradyrhizobia are polymorphic for restriction-fragment length at the LPS-gene region.     

Cloning and characterization of variable-sized gypsy mobile elements in Drosophila melanogaster

A cosmid genomic library from a known gypsy-induced forked mutation, f1, was screened by 32P-labeled gypsy transposable element. Of more than 250 positive clones we randomly selected 21 for in situ hybridization to wild-type polytene chromosomes. Two clones hybridized to region 15F on the X-chromosome, the cytological position of forked. A third clone hybridized to at least 17 sites on the chromosomes indicating the presence of repetitive sequences in the gypsy flanking DNA. All clones labeled the centromeric regions heavily. Ten clones, including the two hybridizing at 15F, were chosen for further analysis, and restriction mapping allowed us to place them into three groups: (1) full-length, (2) slightly diverging, and (3) highly diverging gypsy elements. Group (2) is missing the XbaI site in both their long terminal repeats (LTRs) as well as the middle HindIII site; four of these gypsy elements also have a approximately 100-bp deletion at the 5' LTR. The group (3) gypsy transposons are missing one LTR and also have highly diverging DNA sequences. The restriction analyses further imply that most of these different gypsy elements are present in more than one copy in the genome of the f1 stock used in this study. The results raise intriguing questions regarding the significance of transposable elements in evolution and biological functions.     

Genomic representation of the Hind II 1.9 kb repeated DNA.

The genomic representation and organization of sequences homologous to a cloned Hind III 1.9 kb repeated DNA fragment were studied. Approximately 80% of homologous repeated DNA was contained in a genomic Hind III cleavage band of 1.9 kb. Double digestion studies indicated that the genomic family, in the majority, followed the arrangement of the sequenced clone, with minor restriction cleavage variations compatible with a few base changes. Common restriction sites external to the 1.9 kb sequence were mapped, and hybridization of segments of the cloned sequence indicated the 1.9 kb DNA was itself not tandemly repeated. Kpn I bands which were homologous to the sequence contained specific regions of the repeat, and the molecular weight of these larger fragments could be simply explained. Mapping of common external restriction sites indicated that in some but not all cases the repeat could be organized in larger defined blocks of greater than or equal to 5.5 kb. In some instances, flanking regions adjacent to the repeat may contain common DNA elements such as other repeated DNA sequences, or possibly rearranged segments of the 1.9 kb sequence. It is suggested that although the 1.9 kb sequence is not strictly contiguous, at least some of these repeated sequences in the human genome are arranged in clustered or intercalary arrays. A region of the 1.9 kb sequence hybridized to a mouse repeated DNA, indicating homology beyond the primates.     

Structure and genomic organization of proretrovirus-like elements partially eliminated from the somatic genome of Ascaris lumbricoides.

A clone containing a middle repetitive element next to satellite DNA has been isolated from a germ line genomic library of the chromatin eliminating nematode Ascaris lumbricoides var. suum. The structure of this element has been elucidated by comparison of several clones containing the element in different environments. It is flanked by 256-bp-long terminal repeats (LTRs) and has an internal region of approximately 7 kb. The nucleotide sequences of both the 5' and the 3' LTRs have been determined. The element has a strong structural similarity with retroviral proviruses and related mobile elements. It was therefore named 'Tas', for transposon-like element of Ascaris. Approximately 50 Tas copies are dispersed over approximately 20 different chromosomal sites. Their genomic distribution varies between individuals, indicating that Tas elements are mobile in the Ascaris genome. Two variant forms, Tas-1 and Tas-2, present in a ratio of approximately 2 to 1 in the germ line genome, have been characterized. They differ not only in their restriction pattern, but also in their elimination behaviour. While only about one-fourth of the Tas-1 elements are expelled from the somatic cell lineage, all Tas-2 copies are specifically eliminated and are thus confined to the germ line cells. We have demonstrated that a cloned representative of Tas-1 elements is expelled concomitantly with its flanking DNA sequences during the chromatin elimination process.     

Organization of the Epstein-Barr virus DNA molecule. II. Fine mapping of the boundaries of the internal repeat cluster of B95-8 and identification of additional small tandem repeats adjacent to the HR-1 deletion.

We used cloned BamHI fragments from Epstein-Barr virus strain B95-8 [EBV(B95-8)]DNA to obtain detailed restriction maps of the region of the genome adjacent to the large internal repeat cluster. These maps together with the results of hybridization experiments using a 3.1-kilobase repeat probe defined more precisely the location of the injection between the internal repeat cluster and the flanking unique-sequence DNA. On one side (UL), the repeat sequences extended 600 +/- 80 base pairs (bp) into BamHI-Y; on the other side (US), they extended 1,300 +/- 200 bp into BamHI-C. Therefore, EBV(B95-8) DNA contained a nonintegral number of 3.1-kilobase repeat units, namely, 12.6 copies. The mapping studies also revealed a second series of internal tandem repetitions in EBV(B95-8) DNA located within the BamHI-H fragment. This cluster comprised 11 copies of a 135-bp repeat unit which contained a single site for the NotI restriction endonuclease. Hybridization to these cloned EBV(B95-8) fragments using total EBV(HR-1) DNA as probe indicated that the deletion in EBV(HR-1) removed all 3,000 bp of unique-sequence DNA which lay between the large 3.1-kilobase and the small 135-bp repeat clusters. Thus, the deletion which destroyed the transforming ability in the EBV(HR-1) virus was bounded on either side by tandem repetitions.     

Controlled expression of tagged proteins in Drosophila using a new modular P-element vector system

We have developed a new modular vector system that facilitates the combination of various DNA fragments as functional modules for P element-mediated transformation of Drosophila melanogaster. The basic vector pP?GS? contains unique sites for 17 restriction enzymes, including three 8-bp cutters, that allow one to combine various promoter elements, cDNAs and genomic DNA fragments, as well as protein tags and selectable marker genes, for a wide spectrum of transgene analyses. With this new vector system we analysed the chromosomal distribution of the Drosophila SU(VAR)3-9 protein tagged with EGFP, using hsp70-cDNA and genomic Su(var)3-9 constructs. We found preferential association of the tagged SU(VAR)3-9 with centric heterochromatin.     

Alterations in the number of rRNA operons within the Bacillus subtilis genome

Deletions and additions of rRNA gene sets in Bacillus subtilis were observed by Southern hybridizations using cloned radiolabeled rDNA sequences. Of the ten rRNA gene sets found in B. subtilis 168M or NCTC3610, one was deleted in strains possessing the leuB1, ilvC1, argA2 and pheA1 mutations. Among EcoRI restriction fragments of genomic DNA products, a 2.9-kb 23S rRNA homolog was missing. In HindIII digest, both 5.5- and 5.1-kb hybrid bands were lost with 16S and 23S probes, respectively. Similarly, genomic DNAs digested with SmaI showed the absence of both 2.1- and 2.0-kb fragments that hybridized to 16S and 5S sequences, respectively, in wild-type genomes. In contrast, B. subtilis strain 166 and its derivatives displayed a gain of a 3.3-kb HindIII fragment homologous to 16S rRNA. Transforming the ilvC1 and leuB1 mutations into new genetic backgrounds revealed in some clones the concomitant introduction of the ribosomal defect. Transformations with the slightly heterologous donor DNA from strain W23 yielded some Leu+ and Arg+ transformants with altered hybridization patterns when probed with cloned sequences. We propose that the deletion of the rRNA operon occurred in the ilv-leu gene cluster of the B. subtilis genome as a result of unequal recombination between redundant sequences.