Molecular structure and genetic stability of human hypoxanthine phosphoribosyltransferase (HPRT) gene duplications.

We have determined the genetic stability of three independent intragenic human HPRT gene duplications and the structure of each duplication at the nucleotide sequence level. Two of the duplications were isolated as spontaneous mutations from the HL60 human myeloid leukemia cell line, while the third was originally identified in a Lesch-Nyhan patient. All three duplications are genetically unstable and have a reversion rate approximately 100-fold higher than the rate of duplication formation. The molecular structures of these duplications are similar, with direct duplication of HPRT exons 2 and 3 and of 6.8 kb (HL60 duplications) or 13.7 kb (Lesch-Nyhan duplication) of surrounding HPRT sequence. Nucleotide sequence analyses of duplication junctions revealed that the HL60-derived duplications were generated by unequal homologous recombination between clusters of Alu repeats contained in HPRT introns 1 and 3, while the Lesch-Nyhan duplication was generated by the nonhomologous insertion of duplicated HPRT DNA into HPRT intron 1. These results suggest that duplication substrates of different lengths can be generated from the human HPRT exon 2-3 region and can undergo either homologous or nonhomologous recombination with the HPRT locus to form gene duplications.     

Occurrence of Repeat Induced Point Mutation in Long Segmental Duplications of Neurospora

Previous studies of repeat induced point mutation (RIP) have typically involved gene-size duplications resulting from insertion of transforming DNA at ectopic chromosomal positions. To ascertain whether genes in larger duplications are subject to RIP, progeny were examined from crosses heterozygous for long segmental duplications obtained using insertional or quasiterminal translocations. Of 17 distinct mutations from crossing 11 different duplications, 13 mapped within the segment that was duplicated in the parent, one was closely linked, and three were unlinked. Half of the mutations in duplicated segments were at previously unknown loci. The mutations were recessive and were expressed both in haploid and in duplication progeny from Duplication X Normal, suggesting that both copies of the wild-type gene had undergone RIP. Seven transition mutations characteristic of RIP were found in 395 base pairs (bp) examined in one ro-11 allele from these crosses and three were found in ~750 bp of another. A single chain-terminating C to T mutation was found in 800 bp of arg-6. RIP is thus responsible. These results are consistent with the idea that the impaired fertility that is characteristic of segmental duplications is due to inactivation by RIP of genes needed for progression through the sexual cycle.     

Direct and inverted DNA repeats associated with P-glycoprotein gene amplification in drug resistant Leishmania.

The H circle of Leishmania species contains a 30 kb inverted duplication separated by two unique DNA segments, a and b. The corresponding H region of chromosomal DNA has only one copy of the duplicated DNA. We show here that the chromosomal segments a and b are flanked by inverted repeats (198 and 1241 bp) and we discuss how these repeats could lead to formation of H circles from chromosomal DNA. Selection of Leishmania tarentolae for methotrexate resistance indeed resulted in the de novo formation of circles with long inverted duplication, but two mutants selected for arsenite resistance contained new H region plasmids without such duplications. One of these plasmids appears due to a homologous recombination between two P-glycoprotein genes with a high degree of sequence homology. Our results show how the same DNA region in Leishmania may be amplified to give plasmids with or without long inverted duplications and apparently by different mechanisms.     

Spontaneous sequence duplication within an open reading frame of the pneumococcal type 3 capsule locus causes high-frequency phase variation

The molecular genetic basis of high-frequency serotype 3 capsule phase variation in Streptococcus pneumoniae (the pneumococcus) was investigated. Pneumococci were grown in sorbarod biofilms at 34 degrees C to mimic nasopharyngeal carriage. Different type 3 pneumococci commonly associated with invasive disease generated apparently random tandem duplications of 11-239 bp segments within the cap3A gene of the type 3 capsule locus. These duplications alone were found to be responsible for high-frequency capsule phase variation, in which (phase off) acapsular variants possessed duplications within cap3A, and (phase on) capsular revertants possessed wild-type cap3A genes, indicating the precise excision of the duplication. Additionally, the frequency of phase reversion (off to on) was found to exhibit a linear relationship between (log) frequency of reversion and (log) length of duplication. This apparently random duplication giving rise to phase variation is in stark contrast to the 'preprogrammed' contingency genes in many Gram-negative organisms that possess homopolymeric sequence repeats or motifs for site-specific recombination.     

Isolation of novel herpes simplex virus type 1 derivatives with tandem duplications of DNA sequences encoding immediate-early mRNA-5 and an origin of replication.

Two naturally occurring variations of herpes simplex virus type 1 (Patton strain) with novel tandem DNA sequence duplications in the S component were isolated, and the DNA was characterized. These variants were identified among a number of plaque isolates by the appearance of new restriction enzyme fragments that hybridized with radiolabeled DNA from the BamHI Z fragment (map coordinates 0.936 to 0.949) located in the unique S region. One isolate, SP26-3, carried a 3.1-kilobase-pair duplication defined by recombination between a site in the BamHI Z fragment and a site near the origin of replication in the inverted repeat sequence of the S component carried by the EcoRI H fragment. The other isolate, SP22-4, carried a 3.5-kilobase-pair duplication defined by a recombination event between a tandem repeat array in the BamHI Z fragment and a site near the amino terminus of the Vmw175 gene in the S-region inverted repeat sequence contained in the EcoRI K fragment. Both duplicated segments contained the entire immediate early mRNA-5 coding region as well as the origin of replication located in the inverted repeat sequence of the S component. The DNA sequence of each duplication joint was determined.     

Action of repeat-induced point mutation on both strands of a duplex and on tandem duplications of various sizes in Neurospora.

In Neurospora crassa, DNA sequence duplications are detected and altered efficiently during the sexual cycle by a process known as RIP (repeat-induced point mutation). Affected sequences are subjected to multiple GC-to-AT mutations. To explore the pattern in which base changes are laid down by RIP we examined two sets of strains. First, we examined the products of a presumptive spontaneous RIP event at the mtr locus. Results of sequencing suggested that a single RIP event produces two distinct patterns of change, descended from the two strands of an affected DNA duplex. Equivalent results were obtained using an exceptional tetrad from a cross with a known duplication flanking the zeta-eta (zeta-eta) locus. The mtr sequence data were also used to further examine the basis for the differential severity of C-to-T mutations on the coding and noncoding strands in genes. The known bias of RIP toward CpA/TpG sites in conjunction with the sequence bias of Neurospora accounts for the differential effect. Finally, we used a collection of tandem repeats (from 16 to 935 bp in length) within the mtr gene to examine the length requirement for RIP. No evidence of RIP was found with duplications shorter than 400 bp while all longer tandem duplications were frequently affected. A comparison of these results with vegetative reversion data for the same duplications is consistent with the idea that reversion of long tandem duplications and RIP share a common step.     

Molecular description of three macro-deletions and an Alu-Alu recombination-mediated duplication in the HPRT gene in four patients with Lesch-Nyhan disease

Mutations in the HPRT gene cause a spectrum of diseases that ranges from hyperuricemia alone to hyperuricemia with profound neurological and behavioral dysfunction. The extreme phenotype is termed Lesch-Nyhan syndrome. In 271 cases in which the germinal HPRT mutation has been characterized, 218 different mutations have been found. Of these, 34 (13%) are large- (macro-) deletions of one exon or greater and four (2%) are partial gene duplications. The deletion breakpoint junctions have been defined for only three of the 34 macro-deletions. The molecular basis of two of the four duplications has been defined. We report here the breakpoint junctions for three new deletion mutations, encompassing exons 4-8 (20033bp), exons 4 and 5 (13307bp) and exons 5 and 6 (9454bp), respectively. The deletion breakpoints were defined by a combination of long polymerase chain reaction (PCR) amplifications, and conventional PCR and DNA sequencing. All three deletions are the result of non-homologous recombinations. A fourth mutation, a duplication of exons 2 and 3, is the result of an Alu-mediated homologous recombination between identical 19bp sequences in introns 3 and 1. In toto, two of three germinal HPRT duplication mutations appear to have been caused by Alu-mediated homologous recombination, while only one of six deletion mutations appears to have resulted from this type of recombination mechanism. The other five deletion mutations resulted from non-homologous recombination. With this admittedly limited number of characterized macro-mutations, Alu-mediated unequal homologous recombinations account for at least 8% (3 of 38) of the macro-alterations and 1% (3 of 271) of the total HPRT germinal mutations.     

C1 inhibitor gene sequence facilitates frameshift mutations.

Mutations disrupting the function or production of C1 inhibitor cause the disease hereditary angioneurotic edema. Patient mutations identified an imperfect inverted repeat sequence that was postulated to play a mechanistic role in the mutations. To test this hypothesis, the inverted repeat was cloned into the chloramphenicol acetyltransferase gene in pBR325 and its mutation rate was studied in four bacterial strains. These strains were selected to assay the effects of recombination and superhelical tension on mutation frequency. Mutations that revert bacteria to chloramphenicol resistance (Cmr) were scored. Both pairs of isogenic strains had reversion frequencies of approximately 10(-8). These rare reversion events in bacteria were most often a frameshift that involved the imperfect inverted repeat with a deletion or a tandem duplication, an event very similar to the human mutations. Increased DNA superhelical tension, which would be expected to enhance cruciform extrusion, did not accentuate mutagenesis. This finding suggests that the imperfect inverted repeat may form a stem-loop structure in the single-stranded DNA created by the duplex DNA melting prior to replication. Models explaining the slippage can be drawn using the lagging strand of the replication fork. In this model, the formation of a stem-loop structure is responsible for bringing the end of the deletion or duplication into close proximity.     

Mechanism of reversion of the gal3 mutation of Escherichia coli

The gal3 mutation is an insertion of a DNA sequence in the operator-promoter region of the galactose operon of E. coli. It reverts spontaneously to produce three kinds of gal+ revertants, which are: (i) stable and inducible, (ii) stable and constitutive, and (iii) unstable and constitutive. The constitutive revertants also show drastically reduced frequencies of transduction with lambda. The mechanism by which these reversions occur has remained unknown. It is proposed that the stable and inducible revertants arise by accurate excision of the insertion sequence. The unstable and constitutive revertants arise by tandem duplications of the gal operon in such a way that the structural genes of the extra copy of gal operon become connected to a different promoter. The resulting tandem configuration (gal3 ETK...P'E'T'K') permits constitutive expression and gal3 segregation (by internal recombination) simultaneously. The proposal was tested by comparison of the buoyant densities in CsCl of derivatives of a lambdagal phage carrying gal+, gal3, and the inducible and constitutive revertants. The densities of the inducible revertants were identical to the wild type, and the slight increase in density found to be associated with the gal3 insertion was missing. It was concluded that inducible revertants arise by excision of the inserted sequence. In contrast, lysates of a constitutive revertant exhibited several anomalous properties. The lysates contained a small quantity of phage whose density was identical to lambdagal3, produced few gal+ transductants (10(-3)-10(-4) of a normal HFT lysate), and the transductants were stable and constitutive. In turn, these abnormal transductants produced lysates which showed no lambdagal particles on centrifugation, and no transducing activity whatsoever. These anomalous properties of the constitutive revertant were attributed to the failure of lambda to package the DNA duplication efficiently. Transduction experiments with P1 (which can package more DNA than lambda) show that the unstable, constitutive reversions were located adjacent to prophage lambda. Segregation of the gal and lambda markers among the gal+ transductants was in accordance with the pattern expected for a duplication. Introduction of a recA marker resulted in stabilization of the reversion without affecting its constitutive expression. It was concluded that the unstable, constitutive reversion was a tandem duplication. It is further proposed that the stable, constitutive class of revertants might represent inverted (gal3 ETK...K'T'E'P') or partial tandem (gal3 ET...E'T'K') duplications of the gal operon.     

High Frequency Repeat-Induced Point Mutation (Rip) Is Not Associated with Efficient Recombination in Neurospora

Duplicated DNA sequences in Neurospora crassa are efficiently detected and mutated during the sexual cycle by a process named repeat-induced point mutation (RIP). Linked, direct duplications have previously been shown to undergo both RIP and deletion at high frequency during premeiosis, suggesting a relationship between RIP and homologous recombination. We have investigated the relationship between RIP and recombination for an unlinked duplication and for both inverted and direct, linked duplications. RIP occurred at high frequency (42-100%) with all three types of duplications used in this study, yet recombination was infrequent. For both inverted and direct, linked duplications, recombination was observed, but at frequencies one to two orders of magnitude lower than RIP. For the unlinked duplication, no recombinants were seen in 900 progeny, indicating, at most, a recombination frequency nearly three orders of magnitude lower than the frequency of RIP. In a direct duplication, RIP and recombination were correlated, suggesting that these two processes are mechanistically associated or that one process provokes the other. Mutations due to RIP have previously been shown to occur outside the boundary of a linked, direct duplication, indicating that RIP might be able to inactivate genes located in single-copy sequences adjacent to a duplicated sequence. In this study, a single-copy gene located between elements of linked duplications was inactivated at moderate frequencies (12-14%). Sequence analysis demonstrated that RIP mutations had spread into these single-copy sequences at least 930 base pairs from the boundary of the duplication, and Southern analysis indicated that mutations had occurred at least 4 kilobases from the duplication boundary.     

A comprehensive examination of protein sequences for evidence of internal gene duplication

Summary We have implemented a routine procedure for screening protein sequences for evidence of intragenic duplications. We tested 163 protein sequences representing 116 superfamilies of unrelated proteins. Twenty superfamilies contain proteins with internal gene duplications. The intragenic duplications detected can be divided into two major types. (1) One or more duplications of all or part of a gene produce a protein with two or several detectable regions of sequence homology. Sequences from 18 superfamilies contained this type of duplication. (2) Repeated reduplication of a small DNA segment can produce a protein that is repetitive over most of its length. Three superfamilies contain such repetitive sequences. We also investigated the limits of detection of ancient duplications using sequences derived by random mutation of a model sequence consisting of ten 10-residue repeats. The original repetitive nature of the sequence was usually detected after 250 point mutations even though the ancestral segment could not be accurately reconstructed.     

Instability of a Plasmid-Borne Inverted Repeat in Saccharomyces Cerevisiae

Inverted repeated DNA sequences are common in both prokaryotes and eukaryotes. We found that a plasmid-borne 94 base-pair inverted repeat (a perfect palindrome of 47 bp) containing a poly GT sequence is unstable in S. cerevisiae, with a minimal deletion frequency of about 10(-4)/mitotic division. Ten independent deletions had identical end points. Sequence analysis indicated that all deletions were the result of a DNA polymerase slippage event (or a recombination event) involving a 5-bp repeat (5' CGACG 3') that flanked the inverted repeat. The deletion rate and the types of deletions were unaffected by the rad52 mutation. Strains with the pms1 mutation had a 10-fold elevated frequency of instability of the inverted repeat. The types of sequence alterations observed in the pms1 background, however, were different than those seen in either the wild-type or rad52 genetic backgrounds.     

The invertible P-DNA segment in the chromosome of Escherichia coli.

In the chromosome of many strains of Escherichia coli K12 the excisable element e14 is found, which contains an invertible DNA region. This invertible P region, and the gene responsible for the inversion (pin) were cloned, together with other e14 sequences. The element e14 contains a gene which kills the host cell. This can be repressed by a function also coded by e14. The kil and repressor genes as well as the attachment site of the element were mapped in different regions of the element. The invertible segment and pin gene were sequenced. The invertible segment is 1794 bp long, and contains one large internal open reading frame of 879 bp and reading frames which overlap the end pont of the invertible segment. Although pin highly homologous to gin of phage Mu, neither the genetic organization of the P segment nor the sequence of the putative proteins resemble the invertible G segment of phage Mu (which codes for genes involved in tail fiber assembly). The complete DNA sequences of both invertible segments were screened for homology. No resemblance was found. The P segment is flanked by inverted repeat sequences of 16 bp. Comparison of these with related inversion systems points out that the recombination site maps probably within a 2-bp region. This cross-over site is contained within a short palindromic sequence (AAACC AA GGTTT) which is more or less conserved in the recombination sites of all related DNA invertases.     

The Influence of Primary and Secondary DNA Structure in Deletion and Duplication between Direct Repeats in Escherichia Coli

We describe a system to measure the frequency of both deletions and duplications between direct repeats. Short 17- and 18-bp palindromic and nonpalindromic DNA sequences were cloned into the EcoRI site within the chloramphenicol acetyltransferase gene of plasmids pBR325 and pJT7. This creates an insert between direct repeated EcoRI sites and results in a chloramphenicol-sensitive phenotype. Selection for chloramphenicol resistance was utilized to select chloramphenicol resistant revertants that included those with precise deletion of the insert from plasmid pBR325 and duplication of the insert in plasmid pJT7. The frequency of deletion or duplication varied more than 500-fold depending on the sequence of the short sequence inserted into the EcoRI site. For the nonpalindromic inserts, multiple internal direct repeats and the length of the direct repeats appear to influence the frequency of deletion. Certain palindromic DNA sequences with the potential to form DNA hairpin structures that might stabilize the misalignment of direct repeats had a high frequency of deletion. Other DNA sequences with the potential to form structures that might destabilize misalignment of direct repeats had a very low frequency of deletion. Duplication mutations occurred at the highest frequency when the DNA between the direct repeats contained no direct or inverted repeats. The presence of inverted repeats dramatically reduced the frequency of duplications. The results support the slippage-misalignment model, suggesting that misalignment occurring during DNA replication leads to deletion and duplication mutations. The results also support the idea that the formation of DNA secondary structures during DNA replication can facilitate and direct specific mutagenic events.     

Duplications between direct repeats stabilized by DNA secondary structure occur preferentially in the leading strand during DNA replication

To ascertain a leading or lagging strand preference for duplication mutations, several short DNA sequences, i.e. mutation inserts, were designed that should demonstrate an asymmetric propensity for duplication mutations in the two complementary DNA strands during replication. The design of the mutation insert involved a 7-bp quasi inverted repeat that forms a remarkably stable hairpin in one DNA strand, but not the other. The inverted repeat is asymmetrically placed between flanking direct repeats. This sequence was cloned into a modified chloramphenicol acetyltransferase (CAT) gene containing a −1 frameshift mutation. Duplication of the mutation insert restores the reading frame of the CAT gene resulting in a chloramphenicol resistant phenotype. The mutation insert showed greater than a 200-fold preference for duplication mutations during leading strand, compared with lagging strand, replication. This result suggests that misalignment stabilized by DNA secondary structure, leading to duplication between direct repeats, occurred preferentially during leading strand synthesis.     

A new type of insertion mutation in monkey cells: insertion accompanied by long target site duplication

Summary We have developed a system for the detection of a new type of insertion mutation in mammalian cells. We have used a shuttle vector, plasmid pNK1, which contains the SV40 and pBR322 replication origins, and Ap^R, galK, and neo ^R genes. This plasmid was introduced into monkey COS1 cells, allowed to replicate, and then recovered plasmids were reintroduced into Escherichia coli HB101 to detect insertion mutations in the galK gene. We selected galK ^– KM^R Ap^R mutants in order to eliminate galK ^– Km^S deletion mutants. Insertion mutations in the plasmids recovered were then screened by agarose gel electrophoresis. Finally, insertion mutants that had the following characteristics were selected. First, they had the ability to produce gal⁺ revertants caused by the precise excision of inserted DNA in E. coli, implying that they had a target site duplication on both sides of the insertion. Second, they contained some repetitive sequence(s) as judged by hybridization with a bulk monkey DNA probe. Nucleotide sequence analysis of one of the mutants, 15K-1, showed that it contained -satellite sequences within the coding region of the galK gene. It contained tandem repeat units of -satellite sequence and was flanked by a 64 bp target site duplication, indicating that the -satellite sequence had been translocated from the monkey genome into the plasmid by illegitimate recombination. Another insertion mutant, N11-1, contained an 11 kb insert which included an unknown repetitive sequence that was also flanked by a target site duplication of 353 bp. Since both of the insertion mutations contain long target site duplications, we concluded that the insertion mutations detected here are a new type of insertion mutation. A model for the formation of the insertion-duplication mutation is proposed, in which DNA replication plays a role in this illegitimate recombination.     

Tandem duplication. A novel type of triplet repeat instability

Triplet repeat sequence (TRS) inserts containing (CTG.CAG)(n) (17-175 units in length) were tandemly duplicated when propagated in plasmids in Escherichia coli. The products of this novel type of TRS genetic instability are tracts of as many as 34 multiple units, which contain the entire TRS as well as 129 base pairs of nonrepetitive flanking sequence. The duplication process required the presence of two or more TRS-containing units. Close proximity (170 base pairs) of the TRS to the R6K gamma origin of replication of the pUTminiTn5Cm-derived constructs stimulated the tandem duplication process. These events are proposed to occur due to secondary structure formation, stalling of DNA synthesis, and slippage-mediated misalignment of the complementary strands relative to each other during DNA replication. This mechanism may account for the TRS-associated duplications in protein kinase and metalloprotease genes in neuroblastomas and melanomas, as well as the massive repeat expansions in type II triplet repeat neurological diseases.     

Mutation of msh-2 in Neurospora crassa does not reduce the incidence of recombinants with multiple patches of donor chromosome sequence

The Neurospora homologue msh-2 of the Escherichia coli mismatch repair gene mutS was mutated by repeat-induced point mutation (RIP) of a 1.9-kb duplication covering 1661bp of the coding sequence and 302 bp 5' of the gene. msh-2(RIP-LK1) exhibited a mutator phenotype conferring a 17-fold increase in the frequency of spontaneous mitotic reversion of his-3 allele K458. In msh-2(RIP-LK1) homozygotes, recombination frequency at the his-3 locus increased up to 2.9-fold over that in msh-2(+) diploids. Progeny of crosses homozygous msh-2(RIP-LK1), like those from crosses homozygous msh-2(+) frequently had multiple patches of donor chromosome sequence, suggesting that patchiness in msh-2(+) crosses is not explained by incomplete repair of heteroduplex DNA by MSH-2. These findings are consistent with data from the analysis of events in a Neurospora translocation heterozygote that suggested multiple patches of donor chromosome sequence arising during recombination reflect multiple template switches during DNA repair synthesis.     

Multiple Pathways of Duplication Formation with and Without Recombination (RecA) in Salmonella enterica

Duplications are often attributed to “unequal recombination” between separated, directly repeated sequence elements (>100 bp), events that leave a recombinant element at the duplication junction. However, in the bacterial chromosome, duplications form at high rates (10⁻³–10⁻⁵/cell/division) even without recombination (RecA). Here we describe 1800 spontaneous lac duplications trapped nonselectively on the low-copy F′₁₂₈ plasmid, where lac is flanked by direct repeats of the transposable element IS3 (1258 bp) and by numerous quasipalindromic REP elements (30 bp). Duplications form at a high rate (10⁻⁴/cell/division) that is reduced only about 11-fold in the absence of RecA. With and without RecA, most duplications arise by recombination between IS3 elements (97%). Formation of these duplications is stimulated by IS3 transposase (Tnp) and plasmid transfer functions (TraI). Three duplication pathways are proposed. First, plasmid dimers form at a high rate stimulated by RecA and are then modified by deletions between IS3 elements (resolution) that leave a monomeric plasmid with an IS3-flanked lac duplication. Second, without RecA, duplications occur by single-strand annealing of DNA ends generated in different sister chromosomes after transposase nicks DNA near participating IS3 elements. The absence of RecA may stimulate annealing by allowing chromosome breaks to persist. Third, a minority of lac duplications (3%) have short (0–36 bp) junction sequences (SJ), some of which are located within REP elements. These duplication types form without RecA, Tnp, or Tra by a pathway in which the palindromic junctions of a tandem inversion duplication (TID) may stimulate deletions that leave the final duplication.