Organization, structure, and polymorphisms of the human profilaggrin gene

Profilaggrin is a major protein component of the keratohyalin granules of mammalian epidermis. It is initially expressed as a large polyprotein precursor and is subsequently proteolytically processed into individual functional filaggrin molecules. We have isolated genomic DNA and cDNA clones encoding the 5'- and 3'-ends of the human gene and mRNA. The data reveal the presence of likely "CAT" and "TATA" sequences, an intron in the 5'-untranslated region, and several potential regulatory sequences. While all repeats are of the same length (972 bp, 324 amino acids), sequences display considerable variation (10-15%) between repeats on the same clone and between different clones. Most variations are attributable to single-base changes, but many also involve changes in charge. Thus, human filaggrin consists of a heterogeneous population of molecules of different sizes, charges, and sequences. However, amino acid sequences encoding the amino and carboxyl termini are more conserved, as are the 5' and 3' DNA sequences flanking the coding portions of the gene. The presence of unique restriction enzyme sites in these conserved flanking sequences has enabled calculations on the size of the full-length gene and the numbers of repeats in it: depending on the source of genomic DNA, the gene contains 10, 11, or 12 filaggrin repeats that segregate in kindred families by normal Mendelian genetic mechanisms. This means that the human profilaggrin gene system is also polymorphic with respect to size due to simple allelic differences between different individuals. The amino- and carboxyl-terminal sequences of profilaggrin contain partial or truncated repeats with unusual un-filaggrin-like sequences on the termini.(ABSTRACT TRUNCATED AT 250 WORDS)     

Distinct characteristics of loop sequences of two Drosophila foldback transposable elements.

A few foldback (FB) transposable elements have, between their long terminal inverted repeats, central loop sequences which have been shown to be different from FB inverted repeat sequences. We have investigated loop sequences from two such FB elements by analyzing their genomic distribution and sequence conservation and, in particular, by determining if they are normally associated with FB elements. One of these FB loop sequences seems to be present in a few conserved copies found adjacent to FB inverted repeat sequences, suggesting that it represents an integral component of some FB elements. The other loop sequence is less well-conserved and not usually associated with FB inverted repeats. This sequence is a member of another family of transposable elements, the HB family, and was found inserted in an FB element only by chance. We compare the complete DNA sequences of two HB elements and examine the ends of four HB elements.     

TU elements: a heterogeneous family of modularly structured eucaryotic transposons.

We describe here a family of foldback transposons found in the genome of the higher eucaryote, the sea urchin Strongylocentrotus purpuratus. Two major classes of TU elements have been identified by analysis of genomic DNA and TU element clones. One class consists of largely similar elements with long terminal inverted repeats (IVRs) containing outer and inner domains and sharing a common middle segment that can undergo deletions. Some of these elements contain insertions. The second class is highly heterogeneous, with many different middle segments nonhomologous to those of the first-class and variable-sized inverted repeats that contain only an outer domain. The middle and insertion segments of both classes carry sequences that also are found unassociated from the inverted repeats at many other genomic locations. We conclude that the TU elements are modular structures composed of inverted repeats plus other sequence domains that are themselves members of different families of dispersed repetitive sequences. Such modular elements may have a role in the dispersion and rearrangement of genomic DNA segments.     

Sequence of a genomic DNA clone for the small subunit of ribulose bis-phosphate carboxylase-oxygenase from tobacco.

We have cloned and sequenced a gene for the small subunit (SS) of ribulose bis-phosphate carboxylase-oxygenase from Nicotiana tabacum. The tobacco gene is most closely related to the SS genes from the dicots soybean and pea, and less so to the monocots wheat and Lemna; the deduced amino acid sequence of the mature protein is in all cases more closely conserved than is its chloroplast transit sequence. Unlike the genomic sequences of the two monocots, which have one intron, and the two other dicots, which have two introns, the tobacco gene has three introns. The third tobacco intron lies within a highly conserved region of the protein. Its position coincides with the boundary of a 12 amino acid insertion in the SS genes of higher plants, relative to those of blue green algae. The 5' flanking end of the gene carries 67 bp inverted repeats, which flank a series of eight direct repeats; the direct repeats themselves each carry inverted repeats. The 3' untranslated end of this gene differs by only 2 bp from that of an N. sylvestris SS gene.     

Inverted DNA repeats channel repair of distant double-strand breaks into chromatid fusions and chromosomal rearrangements

Inverted DNA repeats are known to cause genomic instabilities. Here we demonstrate that double-strand DNA breaks (DSBs) introduced a large distance from inverted repeats in the yeast (Saccharomyces cerevisiae) chromosome lead to a burst of genomic instability. Inverted repeats located as far as 21 kb from each other caused chromosome rearrangements in response to a single DSB. We demonstrate that the DSB initiates a pairing interaction between inverted repeats, resulting in the formation of large dicentric inverted dimers. Furthermore, we observed that propagation of cells containing inverted dimers led to gross chromosomal rearrangements, including translocations, truncations, and amplifications. Finally, our data suggest that break-induced replication is responsible for the formation of translocations resulting from anaphase breakage of inverted dimers. We propose a model explaining the formation of inverted dicentric dimers by intermolecular single-strand annealing (SSA) between inverted DNA repeats. According to this model, anaphase breakage of inverted dicentric dimers leads to gross chromosomal rearrangements (GCR). This "SSA-GCR" pathway is likely to be important in the repair of isochromatid breaks resulting from collapsed replication forks, certain types of radiation, or telomere aberrations that mimic isochromatid breaks.     

Human DNA sequences isolated with an immunoglobulin switch region probe: sequence,chromosomal localization,and restriction fragment length polymorphisms

Summary We have screened a human genomic DNA library with an immunoglobulin (Ig) derived switch (S) region specific probe for homologous sequences. Five Ig independent phage clones were isolated and characterized. The S sequence homologous DNA fragments are short compared to the S region sequences. Ig independent S sequences are flanked by highly repetitive DNA elements and perfect inverted repeats can be demonstrated in their close vicinity. Using subclones of S homologous sequences restriction fragment length polymorphisms were shown within DNA of different T cell leukemias. Burkitt lyphhomas, lymphoblastoid cell lines, and DNA of healthy individuals. One of the five clones isolated with the S region probe was evidently localized to chromosome 2 and/or 40 and showed a complex hybridisation pattern with several different human DNAs. S homologous sequences of another clone are most likely localized on chromosome 1. It is possible that these Ig indenpendent S sequences have arisen by amplification and transposition and that they are involved in genetic recombination.     

Inverted repeat sequences can influence the melting transitions of linear DNAs

The influence of inverted repeat sequences on the melting transitions of linear DNAs has been examined. Derivative melting curves (DMC) of a 514 base pair (bp) DNA, seven subfragments of this DNA, and four other DNAs have been compared to predictions of DNA melting theory. The 514-bp DNA contains three inverted repeat sequences that can form cruciform structures in supercoiled DNA. We refer to these sequences as c-inverted repeats. Previous work showed that the DMC of this DNA, unlike a number of other DNAs, is not accurately predicted by DNA melting theory. Since the theoretical model does not include hairpin-like structures, it was suggested that hairpin or cruciform formation in these inverted repeats may be responsible for this discrepancy. Our results support this hypothesis. Predicted DMCs are in good agreement with DNAs with no inverted repeats, or inverted repeats not evident in supercoiled DNA. Differences between the theoretical and experimental Tm's are less than or equal to 0.3 degrees C. DNA molecules that contain one or more of the three c-inverted repeats are not as accurately predicted. Experimental Tm values are lower than predicted values by 0.7-3.8 degrees C. It is concluded that some inverted repeat sequences can form hairpin-like structures during the melting of linear DNAs. These structures appear to lower overall DNA stability.     

The organization of repetitive sequences in a cluster of rabbit β-like globin genes

Several complementary procedures were used to identify and characterize DNA sequences which are repeated within a 44 kilobase (kb) segment of rabbit chromosomal DNA containing four different rabbit β-like globin genes (β1–β4). Cross-hybridization between cloned DNAs from different regions of the gene cluster indicates the presence of a complex array of repeat sequences interspersed with the globin genes. We classified 20 different repeat sequences into five families whose members cross-hybridize. Electron microscopy was used to determine the location, size and relative orientations of many of the repeat sequences. Both direct and inverted repeats were identified, with sizes ranging from 140 to 1400 base pairs (bp). Each of the four closely linked globin genes is flanked by at least one pair of inverted repeats of 140–400 bp, and the entire set of four genes is flanked by an inverted repeat of 1400 bp. Two of the five repeat families contain repeat sequences of different sizes. We found that the smaller sequence elements can occur individually or in association with the larger repeat sequences, suggesting that the larger repeats may be composed of more than one smaller repeat sequence. The restriction fragments containing the intracluster repeats also contain sequences which are repeated many times in total rabbit genomic DNA, but it is not known whether the genomic and intracluster repeats are the same sequences. The results provide the first demonstration of the relationship between single-copy and repetitive DNA sequences in a large segment of chromosomal DNA containing a well characterized set of developmentally regulated genes.     

A complete and a truncated U1 snRNA gene of Drosophila melanogaster are found as inverted repeats at region 82E of the polytene chromosomes.

A phage containing two sequences homologous to U1 snRNA was isolated from a Drosophila melanogaster genomic library, and identified with a previously cloned D. melanogaster U1 snRNA gene. DNA sequence analysis showed that complete and truncated U1 snRNA genes are present, both of which have base substitutions relative to U1 snRNA. These genes show conservation of 5' and 3' flanking regions relative to other U1 and U2 snRNA genes of Drosophila. Intramolecular renaturation experiments and electron microscope mapping demonstrates that the two U1 snRNA sequences are present as inverted repeats about 2.7kb apart, separated by a smaller pair of inverted repeats of an unrelated sequence. These U1 snRNA sequences were located by in situ hybridization at 82E, and related sequences were found at 21D and 95C on the polytene chromosome map. The results are discussed with reference to the origin and function of snRNAs.     

Assaying chromosomal inversions by single-molecule haplotyping

Inversions are an important form of structural variation, but they are difficult to characterize, as their breakpoints often fall within inverted repeats. We have developed a method called 'haplotype fusion' in which an inversion breakpoint is genotyped by performing fusion PCR on single molecules of human genomic DNA. Fusing single-copy sequences bracketing an inversion breakpoint generates orientation-specific PCR products, exemplified by a genotyping assay for the int22 hemophilia A inversion on Xq28. Furthermore, we demonstrated that inversion events with breakpoints embedded within long (>100 kb) inverted repeats can be genotyped by haplotype-fusion PCR followed by bead-based single-molecule haplotyping on repeat-specific markers bracketing the inversion breakpoint. We illustrate this method by genotyping a Yp paracentric inversion sponsored by >300-kb-long inverted repeats. The generality of our methods to survey for, and genotype chromosomal inversions should help our understanding of the contribution of inversions to genomic variation, inherited diseases and cancer.     

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.     

Eucaryotic transposable genetic elements with inverted terminal repeats

DNA carrying inverted repeats was tested for transposition within the Drosophila genome. Five Bam HI segments containing related inverted repeats were isolated from D. melanogaster and analyzed by electron microscopy and restriction mapping. Southern blot experiments using single-copy flanking sequences as probes allowed the study of DNA arrangements at specific sites in the genomes of five closely related strains. We found that in some genomes the sequences with inverted repeats were present at a particular site, whereas in other genomes they were absent from this site. These results indicated that three of the sequences are transposable genetic elements. In one case we have purified the two corresponding DNA segments, with and without the sequence containing inverted repeats, thereby confirming the mobility of this sequence. These DNA elements were found to be distinct in two ways from copia and others previously described: first, they contain inverted terminal repeats, and second, they have a more heterogeneous construction.     

Indel seeds for homology search

We are interested in detecting homologous genomic DNA sequences with the goal of locating approximate inverted, interspersed, and tandem repeats. Standard search techniques start by detecting small matching parts, called seeds, between a query sequence and database sequences. Contiguous seed models have existed for many years. Recently, spaced seeds were shown to be more sensitive than contiguous seeds without increasing the random hit rate. To determine the superiority of one seed model over another, a model of homologous sequence alignment must be chosen. Previous studies evaluating spaced and contiguous seeds have assumed that matches and mismatches occur within these alignments, but not insertions and deletions (indels). This is perhaps appropriate when searching for protein coding sequences (<5% of the human genome), but is inappropriate when looking for repeats in the majority of genomic sequence where indels are common. In this paper, we assume a model of homologous sequence alignment which includes indels and we describe a new seed model, called indel seeds, which explicitly allows indels. We present a waiting time formula for computing the sensitivity of an indel seed and show that indel seeds significantly outperform contiguous and spaced seeds when homologies include indels. We discuss the practical aspect of using indel seeds and finally we present results from a search for inverted repeats in the dog genome using both indel and spaced seeds.     

Inverted repeats as genetic elements for promoting DNA inverted duplication: implications in gene amplification

Inverted repeats are important genetic elements for genome instability. In the current study we have investigated the role of inverted repeats in a DNA rearrangement reaction using a linear DNA substrate. We show that linear DNA substrates with terminal inverted repeats can efficiently transform Escherichia coli. The transformation products contain circular inverted dimers in which the DNA sequences between terminal inverted repeats are duplicated. In contrast to the recombination/rearrangement product of circular DNA substrates, which is exclusively one particular form of the inverted dimer, the rearrangement products of the linear DNA substrate consist of two isomeric forms of the inverted dimer. Escherichia coli mutants defective in RecBCD exhibit much reduced transformation efficiency, suggesting a role for RecBCD in the protection rather than destruction of these linear DNA substrates. These results suggest a model in which inverted repeats near the ends of a double-strand break can be processed by a helicase/exonuclease to form hairpin caps. Processing of hairpin capped DNA intermediates can then yield inverted duplications. Linear DNA substrates containing terminal inverted repeats can also be converted into inverted dimers in COS cells, suggesting conservation of this type of genome instability from bacteria to mammalian cells.     

Rapid detection of CA polymorphisms in cloned DNA: application to the 5'' region of the dystrophin gene.

To identify CA repeats in genomic sequences which had been previously subcloned into plasmids, we performed PCR using a (CA)n primer and a flanking vector primer on the genomic inserts. By incorporation of a restriction enzyme site into the (CA)n primer, we have been able to subclone the genomic DNA so that the sequence flanking the CA repeat is readily determined. Primers can then be designed to amplify across the CA repeat in patient DNA samples. Application of this technique to genomic DNAs surrounding the upstream "brain" promoter of the dystrophin gene has led to the discovery of four new CA repeats. Three of these repeats are highly polymorphic, with PICs ranging from .586 to .768. The location of these markers at the extreme 5' terminus of the dystrophin gene, together with their high degree of polymorphism and ease of assay, makes them ideal for linkage analysis in families with Duchenne muscular dystrophy.