The Distribution and Spreading of Rare Variants in the Histone Multigene Family of Drosophila Melanogaster

We surveyed the distribution of rare variant restriction sites within and among histone gene arrays of Drosophila melanogaster using restriction fragment length polymorphism (RFLP) analysis. Seventy-three naturally occurring arrays were digested with restriction enzymes that had no recognition sites in the published histone sequence. Of the arrays surveyed, 68.5% had at least two nonconsensus restriction sites present as indicated by the presence of a small band or bands on the autoradiographs. These bands were almost always the length of a single repeat in the histone multigene family or a multiple of this length. In arrays with more than one band, intensity of the bands almost always decreased with increasing size. This shows that within these arrays variant restriction sites were predominantly located on adjacent repeats. If these bands are caused by spreading of variant sites, as is most likely, then variants spread along the array as an inverse function of distance. Overall, if a sequence spread it had a 92% probability of ending up in its nearest neighbor. This pattern may result from the noncontiguous nature of the histone family.     

A new family of tandem repetitive early histone genes in the sea urchin Lytechinus pictus: evidence for concerted evolution within tandem arrays.

We have isolated and characterized a third nonallelic tandemly arrayed histone cluster (LpE) from the sea urchin Lytechinus pictus. Although this tandem array is not intermingled with the other two early histone gene families also found in the L. pictus genome, the order and polarity of the five histone coding sequences in this family are the same as every other well characterized sea urchin early histone gene family. Heteroduplex analysis and restriction endonuclease mapping experiments indicate that the LpE family is more closely related to the B-C than the A-D family of early histone genes. Examination of several individual sperm DNA samples has revealed considerable polymorphism in each of the three tandem repeat families. Within an individual, however, each family is remarkably homogeneous. Thus, our results indicate that rapid fixation of variants acts to homogenize the members of a single tandem array at a considerably faster rate within a family than between families. However, at least some exchange of sequences between families is evident based on the conservation of many restriction endonuclease recognition sites and from analysis of a a cosmid clone in which the A-D and E tandem repeats are found adjacent to one another. These differences in the rate of fixation of variants within and between these families are likely to be responsible for the maintenance of diversity between the different families.     

Structure of the sea urchin U1 RNA repeat.

The genes coding for U1 RNA in the sea urchin L. variegatus are present in a 1400 base pair tandem repeat. One member of the repeat has been cloned and its sequence determined. The repeat unit contains a single copy of the gene for L. variegatus U1 RNA. This gene encodes an RNA which is 75% homologous to mammalian U1 RNA. The L. variegatus U1 RNA could assume a secondary structure similar to that proposed for other U1 RNAs. In addition the L. variegatus U1 RNA is precipitated by anti-SM and anti-RNP antisera. Analysis of the L. variegatus genomic DNA using the cloned U1 gene as a probe reveals a major and a minor type of repeat unit. The two repeated units are the same length but differ in a number of restriction enzyme sites clustered 200-500 bases down-stream from the gene. The monomer we have cloned and sequenced is a representative of the minor repeat. A sequence (GATAA) which is -41 to -37 bases 5' to the gene has homology to the putative RNA polymerase II promoter. Fifteen bases 3' of the gene is a sequence (CAAAGAAAGAAAA) which is very similar to the sequence found 3' of the sea urchin histone genes. The two Hha I, Hpa II and Ava I sites in the repeat are all unmethylated in sperm DNA.     

Polymorphism and stability in the histone gene cluster of Drosophila melanogaster

Histone genes in Drosophila melanogaster are organized into repeats of 4.8 and 5.0 kb (Lifton et al., 1978). We find these repeat sizes in every one of the more than 20 Drosophila strains we have examined. Strains differ in the relative amounts of the two repeat types, with ratios varying from 11 to 14, the 5.0 kb repeat always present in equal or greater amounts than the 4.8 kb repeat. Restriction enzyme digestion and blotting analysis reveals that the strains also differ in a number of far less abundant fragments containing histone DNA sequences. In the Amherst and Samarkand strains, there are, in addition, many copies of 4.0 and 5.5 kb repeat-like fragments respectively. A series of stocks were made isogenic for single second chromosomes from the Amherst strain. The hybridization patterns of the histone DNA from these stocks containing different Amherst chromosomes are very similar but a number of differences in the minor fragments were seen. The stability of the histone locus restriction pattern was tested by following the DNA derived from a single second chromosome of the b Adhn² pr cn strain over a two year period. The restriction pattern of major and minor bands remained identical. Finally, histone loci distinguishable by their restriction pattern on blots were recombined with visible markers. These chromosomes will be useful in tracing the fate of specific histone loci during genetic manipulations.     

On the role of repeated sequences 5' to variant surface glycoprotein genes in African trypanosomes

In African trypanosomes, the DNA region situated upstream from all active and some silent variant surface glycoprotein genes (VSG genes) has a repetitive structure. This region is composed of a variable number of tandem repeats of an A + T-rich sequence which lacks the recognition sites for most commonly used restriction endonucleases, and is thus called 'barren region'. The length of the barren regions varies in different trypanosome variants from 0.2 to many kb. We have characterized the barren region upstream from the active VSG gene in two independent Trypanosoma equiperdum variants expressing the same VSG gene in the same expression site. To analyse the junction point between the expression site and the inserted gene, these two barren regions were cloned and sequenced. The longer barren region contains 14 repeats and the other contains two repeats. In both cases the junction point has been shown to lie within a repeat but different repeats were used in each case. These results argue that the repeats are important for the insertion of the duplicated-transposed gene into the expression site and that any repeat can be used.     

Two polymorphic microsatellites in a coding segment of the canine androgen receptor gene

A 0.6-kb segment of exon 1 of the canine androgen receptor gene contains two polymorphic CAG tandem repeats which encode strings of glutamine homopolymers. The number of CAGs in each tandem repeat was determined by (1) polymerase chain reaction (PCR) amplification of a gene segment containing both repeats, (2) cleavage between repeats with restriction enzyme EcoO109I and (3) fractionation of the restriction fragments containing individual CAG repeats by denaturing polyacrylamide gel electrophoresis (PAGE). Individual genomic DNA samples from 80 unrelated dogs (53 males plus 27 females for a total of 107 X chromosomes) contained 10–12 CAGs in the 5′ repeats and 10–13 CAGs in the 3′ repeats. Thirteen distinct androgen receptor genotypes were identified. Eleven (or 41%) of the 27 unrelated females were heterozygous in one or both repeat regions, whereas all male samples produced single bands as expected for X chromosome markers. A total of seven distinct haplotypes contributed to the 13 genotypes. The ‘polymorphism information content’ or PIC for this seven-allele X chromosome marker was 0.67.     

Mouse genomic DNA sequences homologous to sea urchin TU elements are genetically stable polydispersed repeats useful for analysis of multiple RFLPs.

Segments of the murine genome that hybridize to the inverted repeat regions of the transposable TU elements of sea urchins include tandem repeats of a sequence (CTCC) that encodes the recognition site for the restriction enzyme Mnl1, as do the analogous polypurine/polypyrimidine (pPu/pPy) stretches in humans. The Mnl1-sensitive repeats, which exist as a microsatellite sequence 200-300 bp in length, lack the terminal dyad symmetry characteristic of the TU elements and are structurally and functionally distinct from these elements. DNA fragments containing these repeat units that are isolated from different generations of isogenic (or congenic) mice or from different tissues of genetically identical individuals are indistinguishable by RFLP analysis; however, they show restriction fragment length polymorphism in different strains. This polymorphism appears to reflect DNA sequence changes occurring at sites flanking the repeats rather than variability in the number of repeats. Their genetic stability and occurrence in a wide variety of animal species make the Mnl1 repeats useful in studying genetic variation that has occurred over an evolutionary time scale of greater duration than can be examined conveniently by VNTR analysis.     

The sequence arrangement of Drosophila melanogaster 5s DNA cloned in recombinant plasmids.

Segments of Drosophila melanogaster DNA containing 5S rRNA genes have been propagated in recombinant plasmids using E. coli as a host and Col E1 as a vector. Electron microscope partial denaturation mapping, mapping by ferritin labeling and restriction enzyme-gel electrophoresis analysis all indicate that the Drosophila DNA inserts of these plasmids consist of tandem repeats of 5S genes and spacer regions. The repeat length is approximately 380 nucleotide pairs (ntp), corresponding to a gene of length 120 ntp and a spacer of length 260 ntp. The insert in one plasmid (pCIT9) consists of 32 contiguous repeats. Restriction enzyme-gel electrophoresis analysis shows that all these repeats have the same length within ± 5 nucleotides. This repeat length is estimated as 370 ± 20 ntp by gel electrophoresis and 390 ± 40 ntp by partial denaturation mapping. A second plasmid (pCIT19) contains three complete genes, two complete spacers and incomplete flanking spacer sequences. The two complete repeat units released by suitable restriction endonuclease digestions differ in length by 20 ± 5 ntp, with estimated lengths of 370 and 390 ntp. The positions and spacings of the genes on this plasmid have been observed directly by ferritin labeling and by partial denaturation mapping. The A+T content of the 5S DNA spacer region is calculated to be 68%. By in situ hybridization, cRNA transcribed from one plasmid hybridizes to polytene chromosomes only at band 56F, the known locus of the 5S rRNA genes. Spontaneous excision of some of the tandem repeat units from the recombinant plasmids occurs during growth in E. coli; the frequency of excision does not depend upon the recA character of the host, but is greatly increased by chloramphenicol treatment.     

The heterochromatin of grasshoppers from the Caledia captiva species complex. I. Sequence evolution and conservation in a highly repeated DNA family

The restriction enzyme TaqI digests 0.2% of the genomic DNA from the grasshopper Caledia captiva to a family of sequences 168 bp in length (length of consensus sequence). The sequence variation of this "Taq family" of repeat units was examined among four races from C. captiva to assay the pattern of evolution within this highly repeated DNA. The Taq-family repeats are located in C-banded heterochromatin on at least one member of each homologous pair of chromosomes; the locations range from centromeric to telomeric. Thirty-nine cloned repeats isolated from two population 1A individuals along with 11 clones from seven populations taken from three of the races demonstrated sequence variation at 72 positions. Pairwise comparisons of the cloned repeats, both within an individual and between different races, indicate that levels of intraspecific divergence, as measured by reproductive incompatibility, do not correlate with sequence divergence among the 168-bp repeats. A number of subsequences within the repeat remain unchanged among all 50 clones; the longest of these is 18 bp. That the same 18-bp subsequence is present in all clones examined is a finding that departs significantly (P less than 0.01) from what would be expected to occur at random. Two other cloned repeats, from a reproductively isolated race of C. captiva, have sequences that show 56% identity with this 18-bp conserved region. An analysis showed that the frequency of occurrence of an RsaI recognition site within the 168- bp repeat in the entire Taq family agreed with that found in the cloned sequences. These data, along with a partial sequence for the entire Taq family obtained by sequencing uncloned repeats, suggest that the consensus sequence from the cloned copies is representative of this highly repeated family and is not a biased sample resulting from the cloning procedure. The 18-bp conserved sequence is part of a 42-bp sequence that possesses dyad symmetry typical of protein-binding sites. We speculate that this may be significant in the evolution of the Taq family of sequences.      

A unique AT-rich hypervariable minisatellite 3' to the ApoB gene defines a high information restriction fragment length polymorphism

A DNA restriction fragment length polymorphism has been found immediately 3' to the human apoB gene. Digestion of many different human DNAs at sites flanking the region and Southern blotting analysis reveal that this region can vary in length by approximately 300 base pairs with five alleles readily distinguishable. The length polymorphism is due to a unique AT-rich minisatellite that consists primarily of a 30-base pair tandem repeat with two structurally related subunit sequences, x (ATAATTAAATATTTT) and y (ATAATTAAAATATTT). In general, the sequences repeat in an x-y order. The AT-rich region also contains variant x and y sequences that result from C or G for A substitution. Sequence analysis of one large allele revealed the expected increased number of xy repeats. In addition, similar analysis of three different smaller alleles with the same apparent size on Southern blotting analysis showed that all were of slightly different size due to minor differences in the number of xy repeats. The heterogeneity of this AT-rich minisatellite provides the basis for a highly informative restriction fragment length polymorphism of the apoB gene and should be very useful in association and linkage analysis studies of the contribution of this locus to atherosclerosis susceptibility.     

In vivo topoisomerase II cleavage of the Drosophila histone and satellite III repeats: DNA sequence and structural characteristics.

We have identified two classes of in vivo topoisomerase II cleavage sites in the Drosophila histone gene repeat. One class co-localizes with DNase I-hypersensitive regions and another novel class maps to a subset of consecutive nucleosome linker sites in the scaffold-associated region (SAR) of the histone gene loop. Prominent topoisomerase II cleavage is also observed in one of the linker regions of the two nucleosomes spanning satellite III, a centromeric SAR-like DNA sequence with a repeat length of 359 bp. At the sequence level, in vivo topoisomerase II cleavage is highly site specific. Comparison of 10 nucleosome linker sites defines an in vivo cleavage sequence whose major characteristic is a prominent GC-rich core. These GC-rich cleavage sites are flanked by extensive arrays of oligo(dA).oligo(dT) tracts characteristic of SAR sequences. Treatment of cells with distamycin selectively enhances cleavage at nucleosome linker sites of the SAR and satellite regions, suggesting that AT-rich sequences flanking cleavage sites may be involved in determining topoisomerase II activity in the cell. These observations provide evidence for the association of topoisomerase II with SARS in vivo.     

Comparative structure and evolution of goat and sheep satellite I DNAs.

The satellite I DNAs of domestic goat (Capra hircus) and domestic sheep (Ovis aries) have been studied using molecular hybridisation and restriction enzyme analysis. Both satellite DNAs are composed of repeat units of 820 base pairs in length, but their restriction maps, although similar, differ in certain respects. Thus the majority of sheep satellite I repeat units have two EcoRI sites and one AluI site, whereas the majority of goat satellite I repeat units have one EcoRI site and two AluI sites. The sheep satellite I repeat units with the two EcoRI sites are much more homogeneous than the repeats forming the remainder of the satellite, as judged by the difference in the melting temperatures of native and reassociated molecules. DNAs from species of wild sheep and goats were screened for the presence of these repeat units, and they appear to have been amplified during the radiation of the Ovis genus. Goat satellite I is composed of a single sequence type which has changed through base substitution until the sequence now shows considerable heterogeneity. It is proposed that the major sequence types of these two satellite DNAs were amplified by different saltatory replication events at different times in the evolution of the group.     

A new type of illegitimate recombination is dependent on restriction and homologous interaction.

Illegitimate (nonhomologous) recombination requires little or no sequence homology between recombining DNAs and has been regarded as being a process distinct from homologous recombination, which requires a long stretch of homology between recombining DNAs. Under special conditions in Escherichia coli, we have found a new type of illegitimate recombination that requires an interaction between homologous DNA sequences. It was detected when a plasmid that carried 2-kb-long inverted repeats was subjected to type II restriction in vitro and type I (EcoKI) restriction in vivo within a delta rac recBC recG ruvC strain. Removal of one of the repeats or its replacement with heterologous DNA resulted in a reduction in the level of recombination. The recombining sites themselves shared, at most, a few base pairs of homology. Many of the recombination events joined a site in one of the repeats with a site in another repeat. In two of the products, one of the recombining sites was at the end of one of the repeats. Removal of one of the EcoKI sites resulted in decreased recombination. We discuss the possibility that some structure made by homologous interaction between the long repeats is used by the EcoKI restriction enzyme to promote illegitimate recombination. The possible roles and consequences of this type of homologous interaction are discussed.     

Isolation and sequence organization of human ribosomal DNA.

The genes coding for 28 S and 18 S ribosomal RNA have been purified from leukemic leukocytes of one human individual by density gradient centrifugation. The purified ribosomal DNA was analyzed by restriction endonuclease digestion and electron microscopy. The location of cleavage sites for the restriction endonuclease EcoRI was established by R-loop mapping of restriction fragments by electron microscopy. The results are in agreement with gel analysis and gel transfer hybridization. One type of ribosomal DNA repeating unit contains four cleavage sites for EcoRI. Two of these cuts are located in the genes coding for 28 S and 18 S rRNA, while the other two are in the non-transcribed spacer. Thus, one of the restriction fragments generated contains non-transcribed spacer sequences only and is not detected by gel transfer hybridization if labeled rRNA is used as the hybridization probe. A second type of repeating unit lacks one of the EcoRI cleavage sites within the non-transcribed spacer. This indicates that sequence heterogeneity exists in human rDNA spacers. R-loop mapping of high molecular weight rDNA in the electron microscope reveals that the majority of repeats are rather uniform in length. The average size of 22 repeats was 43.65(±1.27) kb. Two repeats were found with lengths of 28.6 and 53.9 kb, respectively. This, and additional evidence from gels, indicates that some length heterogeneity does exist in the non-transcribed spacer. The structure of the human rDNA repeat is summarized in Figure 10.