Structures of ubiquitin insertion mutants support site-specific reflex response to insertions hypothesis

We previously concluded that, judging from NMR chemical shifts, the effects of insertions into ubiquitin on its conformation appear to depend primarily on the site of insertion rather than the sequence of the insertion. To obtain a more complete and atomic-resolution understanding of how these insertions modulate the conformation of ubiquitin, we have solved the crystal structures of four insertional mutants of ubiquitin. Insertions between residues 9 and 10 of ubiquitin are minimally perturbing to the remainder of the protein, while larger alterations occur when the insertion is between residues 35 and 36. Further, the alterations in response to insertions are very similar for each mutant at a given site. Two insertions, one at each site, were designed from structurally homologous proteins. Interestingly, the secondary structure within these five to seven amino acid residue insertions is conserved in the new protein. Overall, the crystal structures support the previous conclusion that the conformational effects of these insertions are determined largely by the site of insertion and only secondarily by the sequence of the insert.     

Predicting the magnitude of the reflex response to insertions in ubiquitin

The ability to predict the structural response of a protein to an insertion would be a significant advance for the fields of homology modeling and protein design. However, the effects of insertions on protein conformation are not well understood. Previous work has demonstrated that for two loops in ubiquitin, the primary determinant of the structural adaptation to insertions is the insertion site rather than the sequence of the insertion; this phenomenon was termed the reflex response of loops to insertions. We report herein the analysis of ubiquitin mutants with insertions in two other loops. This study demonstrates that the insertion site is the primary determinant of the response to insertions for these two new loops as well, which further supports the reflex response hypothesis. We also attempted to predict the relative magnitudes of the responses at each site but were unsuccessful. Using the additional data collected in this work, we have refined our predictive hypothesis.     

Sequential reorganization of beta-sheet topology by insertion of a single strand

Insertions, duplications, and deletions of sequence segments are thought to be major evolutionary mechanisms that increase the structural and functional diversity of proteins. Alternative splicing, for example, is an intracellular editing mechanism that is thought to generate isoforms for 30%-50% of all human genes. Whereas the inserted sequences usually display only minor structural rearrangements at the insertion site, recent observations indicate that they may also cause more dramatic structural displacements of adjacent structures. In the present study we test how artificially inserted sequences change the structure of the beta-sheet region in T4 lysozyme. Copies of two different beta-strands were inserted into two different loops of the beta-sheet, and the structures were determined. Not surprisingly, one insert "loops out" at its insertion site and forms a new small beta-hairpin structure. Unexpectedly, however, the second insertion leads to displacement of adjacent strands and a sequential reorganization of the beta-sheet topology. Even though the insertions were performed at two different sites, looping out occurred at the C-terminal end of the same beta-strand. Reasons as to why a non-native sequence would be recruited to replace that which occurs in the native protein are discussed. Our results illustrate how sequence insertions can facilitate protein evolution through both local and nonlocal changes in structure.     

A collection of sequenced and mapped Ds transposon insertion sites in Arabidopsis thaliana

Insertional mutagenesis is a powerful tool for generating knockout mutations that facilitate associating biological functions with as yet uncharacterized open reading frames (ORFs) identified by genomic sequencing or represented in EST databases. We have generated a collection of Dissociation (Ds) transposon lines with insertions on all 5 Arabidopsis chromosomes. Here we report the insertion sites in 260 independent single-transposon lines, derived from four different Ds donor sites. We amplified and determined the genomic sequence flanking each transposon, then mapped its insertion site by identity of the flanking sequences to the corresponding sequence in the Arabidopsis genome database. This constitutes the largest collection of sequence-mapped Ds insertion sites unbiased by selection against the donor site. Insertion site clusters have been identified around three of the four donor sites on chromosomes 1 and 5, as well as near the nucleolus organizers on chromosomes 2 and 4. The distribution of insertions between ORFs and intergenic sequences is roughly proportional to the ratio of genic to intergenic sequence. Within ORFs, insertions cluster near the translational start codon, although we have not detected insertion site selectivity at the nucleotide sequence level. A searchable database of insertion site sequences for the 260 transposon insertion sites is available at http://sgio2.biotec.psu.edu/sr. This and other collections of Arabidopsis lines with sequence-identified transposon insertion sites are a valuable genetic resource for functional genomics studies because the transposon location is precisely known, the transposon can be remobilized to generate revertants, and the Ds insertion can be used to initiate further local mutagenesis.     

A collection of sequenced and mapped Ds transposon insertion sites in Arabidopsis thaliana

Insertional mutagenesis is a powerful tool for generating knockout mutations that facilitate associating biological functions with as yet uncharacterized open reading frames (ORFs) identified by genomic sequencing or represented in EST databases. We have generated a collection of Dissociation(Ds) transposon lines with insertions on all 5 Arabidopsischromosomes. Here we report the insertion sites in 260 independent single-transposon lines, derived from four different Ds donor sites. We amplified and determined the genomic sequence flanking each transposon, then mapped its insertion site by identity of the flanking sequences to the corresponding sequence in the Arabidopsisgenome database. This constitutes the largest collection of sequence-mapped Ds insertion sites unbiased by selection against the donor site. Insertion site clusters have been identified around three of the four donor sites on chromosomes 1 and 5, as well as near the nucleolus organizers on chromosomes 2 and 4. The distribution of insertions between ORFs and intergenic sequences is roughly proportional to the ratio of genic to intergenic sequence. Within ORFs, insertions cluster near the translational start codon, although we have not detected insertion site selectivity at the nucleotide sequence level. A searchable database of insertion site sequences for the 260 transposon insertion sites is available at http://sgio2.biotec.psu.edu/sr. This and other collections of Arabidopsislines with sequence-identified transposon insertion sites are a valuable genetic resource for functional genomics studies because the transposon location is precisely known, the transposon can be remobilized to generate revertants, and the Ds insertion can be used to initiate further local mutagenesis.     

IS1 insertion generates duplication of a nine base pair sequence at its target site.

Three independent integrations of the E. coli insertion sequence, IS1, into the gal operon have been analyzed. DNA sequences of portions of the wild-type galT gene which act as the target sites for these insertions, as well as the corresponding gal/IS1 junctions, are reported. Two features are particularly noteworthy. First, similar sequences appearing in inverted orientation consitute the ends of IS1: 18 of the terminal 23 base pairs at each end are identical. Second, in all three insertions, a 9 base pair segment found once in the wild-type sequence at the site of insertion is duplicated and appears in the same orientation at each end of the inserted element. The sequence of this 9 base pair repeat is different for each insertion analyzed. No homology between the inverted repeat sequences at the ends of IS1 and the sequences of the target sites is observed. Models for the mechanism of IS1 insertion are proposed.     

Characterisation of complete type II insertions in cloned segments of ribosomal DNA from Drosophila melanogaster

We have isolated cloned segments of ribosomal DNA that have EcoRI restrictable (type II) insertions in their 28 S genes. The type II insertions in these plasmids are homologous sequences and have three characteristic cleavage sites for EcoRI. One of these clones is unusual in that it has undergone a deletion of part of the 28 S gene at or near the site of the type II insertion. A second is unusual in that, in addition to the type II insertion in the rDNA, the transcribed spacer sequences are interrupted by an unidentified sequence. This sequence differs in its arrangement of restriction sites from the sequence that interrupts the transcribed spacer of cDm207 (Glover, 1977). The type II sequences in all these clones share homology with the unusually long ‘insertion’ that interrupts the 28 S gene of cDm207. We have re-examined the nature of the additional sequences linked to the type II sequences of cDm207 and find them to be related to type I rDNA insertion sequences.     

Target site choice of the related transposable elements Tc1 and Tc3 of Caenorhabditis elegans.

We have investigated the target choice of the related transposable elements Tc1 and Tc3 of the nematode C. elegans. The exact locations of 204 independent Tc1 insertions and 166 Tc3 insertions in an 1 kbp region of the genome were determined. There was no phenotypic selection for the insertions. All insertions were into the sequence TA. Both elements have a strong preference for certain positions in the 1 kbp region. Hot sites for integration are not clustered or regularly spaced. The orientation of the integrated transposon has no effect on the distribution pattern. We tested several explanations for the target site preference. If simple structural features of the DNA (e.g. bends) would mark hot sites, we would expect the patterns of the two related transposons Tc1 and Tc3 to be similar; however we found them to be completely different. Furthermore we found that the sequence at the donor site has no effect on the choice of the new insertion site, because the insertion pattern of a transposon that jumps from a transgenic donor site is identical to the insertion pattern of transposons jumping from endogenous genomic donor sites. The most likely explanation for the target choice is therefore that the primary sequence of the target site is recognized by the transposase. However, alignment of the Tc1 and Tc3 integration sites does not reveal a strong consensus sequence for either transposon.     

Homologies in the primary structure of GTP-binding proteins: the nucleotide-binding site of EF-Tu and p21

An examination of the available amino acid sequences of GTP-binding proteins has revealed that each contains a polypeptide essentially homologous for all of them. These sequences for elongation factor-Tu (EF-Tu) and the human bladder protein p21 exhibit a singular degree of homology (50%). Chemical and structural evidence indicates that this sequence in EF-Tu constitutes part of the nucleotide-binding site. The homologous sequences may therefore contribute to the GTP-binding sites of the other proteins.     

Ribosomal DNA in Drosophila melanogaster. II. Heteroduplex mapping of cloned and uncloned rDNA.

Sequences in the cloned Drosophila melanogaster rDNA fragments described by Dawid et al. (1978) were compared by heteroduplex mapping. The nontranscribed spacer regions in all fragments are homologous but vary in length. Deletion loops were observed at variable positions in the spacer region suggesting that spacers are internally repetitious.Many rDNA repeats in D. melanogaster have a 28 S gene interrupted by a region named the ribosomal insertion. Insertions of 0.5, 1 and 5 kb were found in repeat-length EcoRI fragments. These DNA regions, named type 1 insertions, are homologous at their right ends. Although 1 kb insertions are quite precisely twice as large as 0.5 kb insertions they do not represent a duplication of the shorter sequence. Some insertions have at least one EcoRI site and therefore yield EcoRI fragments which are only part of a repeat. The sequences in two cloned right-hand partial insertion sequences are homologous, but the sequences in two lefthand partial insertions are not. None of the EcoRI-restrictable insertion sequences has any homology to any part of type 1 insertions; they are thus grouped together as type 2. Evidence for insertion sequences of at least two types in uncloned rDNA was obtained by annealing a cloned fragment with a 1 kb insertion to genomic rDNA. About 15% of the rDNA repeats show substitution type loops between the 1 kb type 1 insertion derived from the cloned fragment and type 2 insertions in the rDNA.     

Transposition of elements of the 412, copia and 297 dispersed repeated gene families in Drosophila.

The stability of elements of three different dispersed repeated gene families in the genome of Drosophila tissue culture cells has been examined. Different amounts of sequences homologous to elements of 412, copia and 297 dispersed repeated gene families are found in the genomes of D. melanogaster embryonic and tissue culture cells. In general the amount of these sequences is increased in the cell lines. The additional sequences homologous to 412, copia and 297 occur as intact elements and are dispersed to new sites in the cell culture genome. It appears that these elements can insert at many alternative sites. We also describe a DNA sequence arrangement found in the D. melanogaster embryo genome which appears to result from a transposition of an element of the copia dispersed repeated gene family into a new chromosomal site. The mechanism of insertion of this copia element is precise to within 90 bp and may involve a region of weak sequence homology between the site of insertion and the direct terminal repeats of the copia element.     

Transfer RNA Genes Are Genomic Targets for De Novo Transposition of the Yeast Retrotransposon Ty3

Insertions of the yeast element Ty3 resulting from induced retrotransposition were characterized in order to identify the genomic targets of transposition. The DNA sequences of the junctions between Ty3 and flanking DNA were determined for two insertions of an unmarked element. Each insertion was at position -17 from the 5' end of a tRNA-coding sequence. Ninety-one independent insertions of a marked Ty3 element were studied by Southern blot analysis. Pairs of independent insertions into seven genomic loci accounted for 14 of these insertions. The DNA sequence flanking the insertion site was determined for at least one member of each pair of integrated elements. In each case, insertion was at position -16 or -17 relative to the 5' end of one of seven different tRNA genes. This proportion of genomic loci used twice for Ty3 integration is consistent with that predicted by a Poisson distribution for a number of genomic targets roughly equivalent to the estimated number of yeast tRNA genes. In addition, insertions upstream of the same tRNA gene in one case were at different positions, but in all cases were in the same orientation. Thus, genomic insertions of Ty3 in a particular orientation are apparently specified by the target, while the actual position of the insertion relative to the tRNA-coding sequence can vary slightly.     

A cloned immunoglobulin cDNA fragment enhances transposition of IS elements into recombinant plasmids.

Evidence is presented indicating that a novel DNA sequence arrangement generated by in vitro recombination may elicit high frequency transpositions of IS elements. A 109 bp Bam HI fragment of the cDNA for the immunoglobulin kappa light chain from MOPC 321 myeloma was cloned into the Bam HI site of pBR313. The cloned fragment extends from the codon for Gly 57 to the V-J junction. Insertions of IS1 or IS5 were identified in 6 of 50 plasmid DNAs isolated from freshly transformed clones. Additional transposition events were detected after subculturing for several growth cycles. Three independent insertions of IS1 occurred in the promoter region of the TcR operon. All IS5 and the remaining IS1 insertions were located in the TcR region upstream to the cloned DNA sequence. Sequences homologous to the ends of IS1, or corresponding to the consensus sequence at the target site of IS5 are present near the estimated sites of insertion of IS1 or IS5 respectively. Bacteria harboring recombinant plasmids carrying the cloned DNA in either orientation grew at a reduced rate relative to cells harboring pBR313, suggesting that fused gene products made from the two types of plasmid were inhibitory to cell growth. IS insertions, which relieved this inhibitory effect and thereby provided a selective advantage, were found exclusively in plasmids carrying the cloned DNA in only one of the two orientations. The fact that IS elements were not observed in the other type of recombinant plasmid indicates that selective pressure alone is not sufficient to account for the frequent IS insertions observed and that sequences at a distance from the site of IS insertion may be critical in the regulation of transposition frequency.     

Chloroplast DNA insertions into the nuclear genome of rice: the genes,sites and ages of insertion involved

Rice (Oryza sativa) is one of three predominant grain crops, and its nuclear and organelle genomes have been sequenced. Following genome analysis revealed many exchanges of DNA sequences between the nuclear and organelle genomes. In this study, a total of 45 chloroplast DNA insertions more than 2 kb in length were detected in rice nuclear genome. A homologous recombination mechanism is expected for those chloroplast insertions with high similarity between their flanking sequences. Only five chloroplast insertions with high sequence similarity between two flanking sequences from an insertion were found in the 45 insertions, suggesting that rice might follow the non-homologous end-joining (NHEJ) repair of double-stranded breaks mechanism, which is suggested to be common to all eukaryotes. Our studies indicate that the most chloroplast insertions occurred at a nuclear region characterized by a sharp change of repetitive sequence density. One potential explanation is that regions such as this might be susceptible target sites or “hotspots” of DNA damage. Our results also suggest that the insertion of retrotransposon elements or non-chloroplast DNA into chloroplast DNA insertions may contribute significantly to their fragmentation process. Moreover, based on chloroplast insertions in nuclear genomes of two subspecies (indica and japonica) of cultivated rice, our results strongly suggest that they diverged during 0.06–0.22 million years ago. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

DNA sequence analysis of Tn10 insertions: origin and role of 9 bp flanking repetitions during Tn10 translocation.

The sequences of insertions of the translocatable tetracycline-resistance element Tn10 into the repressor (cl) gene of bacteriophage lambda have been analyzed. Each insertion contains the same discrete set of Tn10 sequences flanked by a direct repetition of a 9 bp cl-gene sequence. The flanking repititions are generated by duplication of information present only in the target DNA molecule rather than by a Campbell-type recombination event between one 9 bp sequence on the target DNA and a second one provided on the incoming element. The repetitions do not contain genetic or structural information important for translocation. A genetically constructed Tn10 insertion which lacks flanking repetitions is fully functional in translocation to a new position. Tn10 insertions cluster at preferred positions along a target DNA (Kleckner et al., 1979). Sequence analysis shows that four independently isolated cl::Tn10 insertions occur at identical positions in the cl gene. We speculate that homology between Tn10 and its target, at some distance from the site of the actual recombination event, could be relevant to the preference of Tn10 for particular insertion sites.     

Cloning and study of inserted sequences of gene 28S in Drosophila melanogaster ribosomal RNA

Cloning of fragments of ribosomal genes containing insertions in the 28S RNA gene has been reported earlier. Subcloning of DNA fragments corresponding to insertion sequences and their hybridization with DNA, RNA and polytene chromosomes from different flies is described. Type 1 insertions (containing BamI sites) are highly heterogeneous in length and sequence even in homozygotes. Type 2 insertions (with EcoRI sites) are rather homogeneous. Two types of insertions are represented in the D. melanogaster genome by 50 and 30 copies, respectively. Restriction fragments with insertions significantly differ in DNA from embryos and larvae. D. simulans and D. virilis also contain the sequences of both types of insertions, though in fewer number of copies. Type 1 insertions seem to be poorly transcribed, and type 2 insertions are not transcribed at all. Among 2000 recombinant clones screened a number of DI plasmids hybridizing to isolated insertions were obtained. Six of them were mapped with restriction endonucleases and hybridized with insertion fragments. rRNA and polytene chromosomes. All of these DI plasmids hybridize with the nucleoli, one with the chromocenter and one with the 79F 3L site. In LI9, not coding for rRNA, the sequences, corresponding to two types on insertions are located only a few kilobases apart. D17a does not encode for rRNA, but hybridizes in situ only with the nucleoli.     

Prediction and identification of a permissive epitope insertion site in the vesicular stomatitis virus glycoprotein

We developed a rational approach to identify a site in the vesicular stomatitis virus (VSV) glycoprotein (G) that is exposed on the protein surface and tolerant of foreign epitope insertion. The foreign epitope inserted was the six-amino-acid sequence ELDKWA, a sequence in a neutralizing epitope from human immunodeficiency virus type 1. This sequence was inserted into six sites within the VSV G protein (Indiana serotype). Four sites were selected based on hydrophilicity and high sequence variability identified by sequence comparison with other vesiculovirus G proteins. The site showing the highest variability was fully tolerant of the foreign peptide insertion. G protein containing the insertion at this site folded correctly, was transported normally to the cell surface, had normal membrane fusion activity, and could reconstitute fully infectious VSV. The virus was neutralized by the human 2F5 monoclonal antibody that binds the ELDKWA epitope. Additional studies showed that this site in G protein tolerated insertion of at least 16 amino acids while retaining full infectivity. The three other insertions in somewhat less variable sequences interfered with VSV G folding and transport to the cell surface. Two additional insertions were made in a conserved sequence adjacent to a glycosylation site and near the transmembrane domain. The former blocked G-protein transport, while the latter allowed transport to the cell surface but blocked membrane fusion activity of G protein. Identification of an insertion-tolerant site in VSV G could be important in future vaccine and targeting studies, and the general principle might also be useful in other systems.