Insights into the mechanism of initial transcription in Escherichia coli RNA polymerase.

It has long been known that during initial transcription of the first 8-10 bases of RNA, complexes are relatively unstable, leading to the release of short abortive RNA transcripts. An early "stressed intermediate" model led to a more specific mechanistic model proposing "scrunching" stress as the basis for the instability. Recent studies in the single subunit T7 RNA polymerase have argued against scrunching as the energetic driving force and instead argue for a model in which pushing of the RNA-DNA hybrid against a protein element associated with promoter binding, while likely driving promoter release, reciprocally leads to instability of the hybrid. In this study, we test these models in the structurally unrelated multisubunit bacterial RNA polymerase. Via the targeted introduction of mismatches and nicks in the DNA, we demonstrate that neither downstream bubble collapse nor compaction/scrunching of either the single-stranded template or nontemplate strands is a major force driving abortive instability (although collapse from the downstream end of the bubble does contribute significantly to the instability of artificially halted complexes). In contrast, pushing of the hybrid against a mobile protein element (σ3.2 in the bacterial enzyme) results in substantially increased abortive instability and is likely the primary energetic contributor to abortive cycling. The results suggest that abortive instability is a by-product of the mechanistic need to couple the energy of nucleotide addition (RNA chain growth) to driving the timed release of promoter contacts during initial transcription.

The human hyaluronan synthase 2 (HAS2) gene and its natural antisense RNA exhibit coordinated expression in the renal proximal tubular epithelial cell.

Aberrant expression of the human hyaluronan synthase 2 (HAS2) gene has been implicated in the pathology of malignancy, pulmonary arterial hypertension, osteoarthritis, asthma, thyroid dysfunction, and large organ fibrosis. Renal fibrosis is associated with increased cortical synthesis of hyaluronan (HA), an extracellular matrix glycosaminoglycan, and we have shown that HA is a correlate of interstitial fibrosis in vivo. Our previous in vitro data have suggested that both HAS2 transcriptional induction and subsequent HAS2-driven HA synthesis may contribute to kidney fibrosis via phenotypic modulation of the renal proximal tubular epithelial cell (PTC). Post-transcriptional regulation of HAS2 mRNA synthesis by the natural antisense RNA HAS2-AS1 has recently been described in osteosarcoma cells, but the antisense transcript was not detected in kidney. In this study, PTC stimulation with IL-1ß or TGF-ß1 induced coordinated temporal profiles of HAS2-AS1 and HAS2 transcription. Constitutive activity of the putative HAS2-AS1 promoter was demonstrated, and transcription factor-binding sequence motifs were identified. Knockdown of Sp1/Sp3 expression by siRNA blunted IL-1ß induction of both HAS2-AS1 and HAS2, and Smad2/Smad3 knockdown similarly attenuated TGF-ß1 stimulation. Inhibition of IL-1ß-stimulated HAS2-AS1 RNA induction using HAS2-AS1-specific siRNAs also suppressed up-regulation of HAS2 mRNA transcription. The thermodynamic feasibility of HAS2-AS1/HAS2 heterodimer formation was demonstrated in silico, and locus-specific cytoplasmic double-stranded RNA was detected in vitro. In summary, our data show that transcriptional induction of HAS2-AS1 and HAS2 occurs simultaneously in PTCs and suggest that transcription of the antisense RNA stabilizes or augments HAS2 mRNA expression in these cells via RNA/mRNA heteroduplex formation.

[Region 1112-1123 in the central domain of 18S rRNA in 40S subunits of plant ribosomes: accessibility for complementary interactions and the functional role].

The binding of the 18S RNA of the 40S subunits of wheat germ ribosomes to an oligodeoxyribonucleotide complementary to the 1112-1123 region of the central domain of this RNA molecule has been studied. The selective binding of this oligomer to the complementary RNA fragment and the inhibition of the translation of uncapped chimeric RNA containing enhancer sequences in the 5'-untranslated region upstream of the reporter sequence coding for beta-glucuronidase has been shown in a cell-free protein-synthesizing system. The use of a derivative of the aforementioned oligomer containing an alkylating group at the 5' end allowed for the demonstration that the 1112-1123 region of 18S RNA can form a heteroduplex with the complementary sequence of the oligomer. The data obtained show that the 1112-1123 region in loop 27 of the central domain of 18S RNA of 40S ribosomal subunits is exposed on the subunit surface and probably participates in the cap-independent binding of the subunits to mRNA due to the complementary interaction with the enhancer sequences.

Dodecamer DNA duplex formation is characterized by second-order kinetics, positive activation energies, and a dependence on sequence and Mg2+ ion concentration.

This study provides quantitative information about the kinetics of formation of a complex between DNA oligomers having 12 bp. The DNA dodecamers were designed in such a way as to avoid the formation of hairpins or slipped duplex structures within single strands. The hybridization was carried out employing stopped-flow techniques. The reaction was studied in different buffers (phosphate or cacodylate), in the presence and absence of Mg2+ ions, and at different temperatures. Under all conditions, the reaction followed second-order kinetics. The association rate constants were on the order of 106 M(-1) s(-1) and were found to increase with an increase in temperature. Both the rate constants and the positive activation energies of the two dodecamers, which differ only by the presence of the TAGG tetrad either at the 3'end or at the 5' end, turned out to be significantly different. The presence of Mg2+ ions had a profound influence on the kinetics of association of either compound by substantially decreasing the activation energy of the process. The dependence on sequence of the kinetics of hybridization was manifest in all parameters under all the experimental conditions.

Concerted action of exonuclease and Gap-dependent endonuclease activities of FEN-1 contributes to the resolution of triplet repeat sequences (CTG)n- and (GAA)n-derived secondary structures formed during maturation of Okazaki fragments.

There is much evidence to indicate that FEN-1 efficiently cleaves single-stranded DNA flaps but is unable to process double-stranded flaps or flaps adopting secondary structures. However, the absence of Fen1 in yeast results in a significant increase in trinucleotide repeat (TNR) expansion. There are then two possibilities. One is that TNRs do not always form stable secondary structures or that FEN-1 has an alternative approach to resolve the secondary structures. In the present study, we test the hypothesis that concerted action of exonuclease and gap-dependent endonuclease activities of FEN-1 play a role in the resolution of secondary structures formed by (CTG)n and (GAA)n repeats. Employing a yeast FEN-1 mutant, E176A, which is deficient in exonuclease (EXO) and gap endonuclease (GEN) activities but retains almost all of its flap endonuclease (FEN) activity, we show severe defects in the cleavage of various TNR intermediate substrates. Precise knock-in of this point mutation causes an increase in both the expansion and fragility of a (CTG)n tract in vivo. Taken together, our biochemical and genetic analyses suggest that although FEN activity is important for single-stranded flap processing, EXO and GEN activities may contribute to the resolution of structured flaps. A model is presented to explain how the concerted action of EXO and GEN activities may contribute to resolving structured flaps, thereby preventing their expansion in the genome.

An efficient method for the preparation of long heteroduplex DNA as substrate for mismatch repair by the Escherichia coli MutHLS system.

We present a method that allows preparing long DNA containing defined mismatches without the use of gel electrophoretic or chromatographic purification steps. The preparation starts with the synthesis of two PCR products, which are identical except for those positions that will later form the mismatches. One of the PCR primers must be 5'-phosphorylated, such that in two separate reactions two PCR products are obtained, which are 5'-phosphorylated in one strand. After removal of the phosphorylated strands by lambda-exonuclease, the resulting single strands are hybridized to form the mismatch-containing heteroduplex. The application of this procedure is demonstrated for the analysis of the Escherichia coli MutHLS system.

RNA polymerase II complexes in the very early phase of transcription are not susceptible to TFIIS-induced exonucleolytic cleavage.

TFIIS is a transcription elongation factor for RNA polymerase II (pol II), which can suppress ribonucleotide misincorporation. We reconstituted transcription complexes in a highly purified pol II system on adenovirus Major-Late promoter constructs. We noted that these complexes have a high propensity for read-through upon GTP omission. Read-through occurred during the early stages at all registers analyzed. Addition of TFIIS reversed read-through of productive elongation complexes, which indicated that it was due to misincorporation. However, before register 13 transcription complexes were insensitive to TFIIS. These findings are discussed with respect to the structural models for pol II and we propose that TFIIS action is linked to the RNA:DNA hybrid.

Heteroduplexes in mixed-template amplifications: formation, consequence and elimination by 'reconditioning PCR'.

Although it has been recognized that PCR amplification of mixed templates may generate sequence artifacts, the mechanisms of their formation, frequency and potential elimination have not been fully elucidated. Here evidence is presented for heteroduplexes as a major source of artifacts in mixed-template PCR. Nearly equal proportions of homoduplexes and heteroduplexes were observed after co-amplifying 16S rDNA from three bacterial genomes and analyzing products by constant denaturing capillary electrophoresis (CDCE). Heteroduplexes became increasingly prevalent as primers became limiting and/or template diversity was increased. A model exploring the fate of cloned heteroduplexes during MutHLS-mediated mismatch repair in the Escherichia coli host demonstrates that the diversity of artifactual sequences increases exponentially with the number of both variable nucleotides and of original sequence variants. Our model illustrates how minimization of heteroduplex molecules before cloning may reduce artificial genetic diversity detected during sequence analysis by clone screening. Thus, we developed a method to eliminate heteroduplexes from mixed-template PCR products by subjecting them to 'reconditioning PCR', a low cycle number re-amplification of a 10-fold diluted mixed-template PCR product. This simple modification to the protocol may ensure that sequence richness encountered in clone libraries more closely reflects genetic diversity in the original sample.

Analysis of plus-strand primer selection, removal, and reutilization by retroviral reverse transcriptases.

The ability of reverse transcriptase to generate, extend, and remove the primer derived from the polypurine tract (PPT) is vital for reverse transcription, since this process determines one of the ends required for integration of the viral DNA. Based on the ability of the RNase H activity of Moloney murine leukemia virus reverse transcriptase to cleave a long RNA/DNA hybrid containing the PPT, it appears that cleavages that could generate the plus-strand primer can occur by an internal cleavage mechanism without any positioning by an RNA 5'-end, and such cleavages may serve to minimize cleavage events within the PPT itself. If the PPT were to be cleaved inappropriately just upstream of the normal plus-strand origin site, the resulting 3'-ends would not be extended by reverse transcriptase. Extension of the PPT primer by at least 2 nucleotides is sufficient for recognition and correct cleavage by RNase H at the RNA-DNA junction to remove the primer. Specific removal of the PPT primer after polymerase extension deviates from the general observation that primer removal occurs by cleavage one nucleotide away from the RNA-DNA junction and suggests that the same PPT specificity determinants responsible for generation of the PPT primer also direct PPT primer removal. Once the PPT primer has been extended and removed from the nascent plus-strand DNA, reinitiation at the resulting plus-strand primer terminus does not occur, providing a mechanism to prevent the repeated initiation of plus strands.

The meiosis-specific recombinase hDmc1 forms ring structures and interacts with hRad51.

Eukaryotic cells encode two homologs of Escherichia coli RecA protein, Rad51 and Dmc1, which are required for meiotic recombination. Rad51, like E.coli RecA, forms helical nucleoprotein filaments that promote joint molecule and heteroduplex DNA formation. Electron microscopy reveals that the human meiosis-specific recombinase Dmc1 forms ring structures that bind single-stranded (ss) and double-stranded (ds) DNA. The protein binds preferentially to ssDNA tails and gaps in duplex DNA. hDmc1-ssDNA complexes exhibit an irregular, often compacted structure, and promote strand-transfer reactions with homologous duplex DNA. hDmc1 binds duplex DNA with reduced affinity to form nucleoprotein complexes. In contrast to helical RecA/Rad51 filaments, however, Dmc1 filaments are composed of a linear array of stacked protein rings. Consistent with the requirement for two recombinases in meiotic recombination, hDmc1 interacts directly with hRad51.

Crystal structure of an eight-base pair duplex containing the 3'-DNA-RNA-5' junction formed during initiation of minus-strand synthesis of HIV replication.

During initiation of minus-strand synthesis by HIV-1 reverse transcriptase, a 3'-DNA-RNA-5' junction is formed involving the 3'-end of tRNAlys,3. The HIV-RT-associated RNase H cleaves the RNA template strand specifically, opposite the newly synthesized DNA strand. We have determined the crystal structure at 1.9 A resolution of an eight-base pair hybrid duplex representing the junction to identify global or local structural perturbations which may be recognized by HIV-RT RNase H. The junction octamer is in a global A-type conformation throughout. A base pair step with distinct stacking geometry and variable backbone conformation is located next to the main endonucleolytic cleavage site. This base pair step may serve as a recognition site for HIV-RT RNase H.

Mucosal transmission of pathogenic CXCR4-utilizing SHIVSF33A variants in rhesus macaques.

Infection of macaques with chimeric simian/human immunodeficiency virus (SHIV) expressing the envelope protein of HIV-1 provides a model system for studying HIV-1 infection in humans. To this end, four rhesus macaques (Macaca mulatta) were given a single intravaginal (IVAG) inoculation of cell-free SHIVSF33A and longitudinal samples of peripheral blood and lymph nodes were analyzed for viremia, antigenemia, and various T-cell populations. Rhesus macaques infected IVAG with SHIVSF33A demonstrated a dramatic decrease in the CD4(+) PBMC subset in the initial weeks after viral exposure, a time that corresponded to peak in plasma viremia and antigenemia. Within 4 months of SHIVSF33A inoculation, partial to complete rebound of the CD4(+) PBMC was seen in these animals. Notably, the regeneration of the CD4(+) subset was associated with regeneration of the naive T-cell population and was concordant with clearance of plasma viremia. DNA heteroduplex tracking assays revealed transmission of minor variants within the SHIVSF33A inoculum to the IVAG-inoculated animals. The cell-free SHIVSF33A inoculum as well as virus isolated from animals early after transmission used the chemokine molecule CXCR4 as the primary cellular coreceptor, demonstrating that viruses expressing envelope glycoproteins of the syncytia inducing (SI) phenotype can be transported across the vaginal mucosa. Although none of the animals has yet to develop clinical symptoms of simian AIDS (SAIDS), infectious virus and viral nucleic acids could be persistently isolated from each animal. Furthermore, animals transfused with blood from IVAG-infected macaques drawn 2 weeks after inoculation suffered a more profound and sustained CD4(+) T-cell loss, persistent plasma viremia, and the development of SAIDS in one animal, indicating that IVAG-passaged SHIVSF33A was pathogenic. Taken together, these results establish that a pathogenic CXCR4-utilizing SHIVSF33A species crossed the cervicovaginal mucosa. Different courses of infection in the IVAG versus transfusion animals suggest that host-mediated responses elicited upon transmission across mucosal barriers may serve to limit viral replication and delay disease progression in the IVAG-infected animals.

Comprehensive, rapid and sensitive detection of sequence variants of human mitochondrial tRNA genes.

In the present study, a comprehensive, rapid and sensitive method for screening sequence variation of the human mitochondrial tRNA genes has been developed. For this purpose, the denaturing gradient gel electrophoresis (DGGE) technique has been appropriately modified for simultaneous mutation analysis of a large number of samples and adapted so as to circumvent the problems caused by the anomalous electrophoretic behavior of DNA fragments encoding tRNA genes. Eighteen segments of mitochondrial DNA (mtDNA), each containing a single uniform melting domain, were selected to cover all tRNA-encoding regions using the computer program MELT94. All 18 segments were simultaneously analyzed by electrophoresis through a single broad range denaturing gradient gel under rigorously defined conditions, which prevent band broadening and other migration abnormalities from interfering with detection of sequence variants. All base substitutions tested, which include six natural mutations and 14 artificially introduced ones, have been detected successfully in the present study. Several types of evidence strongly suggest that the anomalous behavior in DGGE of tRNA gene-containing mtDNA fragments reflects their tendency to form temporary or stable alternative secondary structures under semi-denaturing conditions. The high sensitivity of the method, which can detect as low as 10% of mutant mtDNA visually, makes it valuable for the analysis of heteroplasmic mutations.

Molecular characterization of a genomic region in a Lactococcus bacteriophage that is involved in its sensitivity to the phage defense mechanism AbiA.

A spontaneous mutant of the lactococcal phage phi31 that is insensitive to the phage defense mechanism AbiA was characterized in an effort to identify the phage factor(s) involved in sensitivity of phi31 to AbiA. A point mutation was localized in the genome of the AbiA-insensitive phage (phi31A) by heteroduplex analysis of a 9-kb region. The mutation (G to T) was within a 738-bp open reading frame (ORF245) and resulted in an arginine-to-leucine change in the predicted amino acid sequence of the protein. The mutant phi31A-ORF245 reduced the sensitivity of phi31 to AbiA when present in trans, indicating that the mutation in ORF245 is responsible for the AbiA insensitivity of phi31A. Transcription of ORF245 occurs early in the phage infection cycles of phi31 and phi31A and is unaffected by AbiA. Expansion of the phi31 sequence revealed ORF169 (immediately upstream of ORF245) and ORF71 (which ends 84 bp upstream of ORF169). Two inverted repeats lie within the 84-bp region between ORF71 and ORF169. Sequence analysis of an independently isolated AbiA-insensitive phage, phi31B, identified a mutation (G to A) in one of the inverted repeats. A 118-bp fragment from phi31, encompassing the 84-bp region between ORF71 and ORF169, eliminates AbiA activity against phi31 when present in trans, establishing a relationship between AbiA and this fragment. The study of this region of phage phi31 has identified an open reading frame (ORF245) and a 118-bp DNA fragment that interact with AbiA and are likely to be involved in the sensitivity of this phage to AbiA.

Mismatch repair in Xenopus egg extracts: DNA strand breaks act as signals rather than excision points.

In Xenopus egg extracts, DNA strand breaks (nicks) located 3' or 5' to a mismatch cause an overall 3-fold stimulation of the repair of the mismatch in circular heteroduplex DNA molecules. The increase in mismatch repair is almost entirely due to an increase in repair of the nicked strand, which is stimulated 5-fold. Repair synthesis is centered to the mismatch site, decreases symmetrically on both sides, and its position is not significantly altered by the presence of the nick. Therefore, it appears that in the Xenopus germ cells, the mismatch repair system utilizes nicks as signals for the induction and direction of mismatch repair, but not as the start or end point for excision and resynthesis.

Mutation spectra of M13 vectors containing site-specific Cis-Syn, Trans-Syn-I, (6-4), and Dewar pyrimidone photoproducts of thymidylyl-(3'-->5')-thymidine in Escherichia coli under SOS conditions.

The mutations spectra of cis-syn, trans-syn-I, (6-4), and Dewar pyrimidone photoproducts of the TT site of AATTAA and TATTAT in the (-) strand of a heteroduplex M13 vector were obtained in an excision and photoreversal repair deficient Escherichia coli host under SOS conditions. Oligonucleotides containing site-specific photoproducts were annealed to a complementary uracil-containing (+) strand that contained one or more unique pairs of nucleotide mismatches and used to prime (-) strand synthesis with a DNA polymerase and dNTPs. Following DNA synthesis, the reaction mixtures were incubated with T4 DNA ligase and ATP and then used to transfect SOS-induced competent CSRO6F' cells (uvrA6 and phr-1). The transfectants were plated, gridded, and probed by oligonucleotides specific for progeny of the (-) and (+) strands. Individual progeny of the photoproduct-containing (-) strands were plaque purified and sequenced by the dideoxy method. The cis-syn and trans-syn-I dimers were found not to be very mutagenic (<9%), the Dewar product more so (<33%), and the (6-4) product the most mutagenic (<73%). The mutation spectra were similar to those previously reported for the same photoproducts of the TT site of AGTTGG in the (+) strand of an M13 vector [Lawrence, C. W., et al. (1990) Mol. Gen Genet. 222, 166-168; LeClerc, J. E., et al. (1991) Proc. Natl. Acad. Sci. U.S.A. 88, 9685-9689] except that -1 deletion mutations were not observed for the trans-syn-I photoproducts, and a lower frequency of 3'-T-->C mutations was observed for the (6-4) photoproduct. Evidence that a small percentage of (+) strand repair of a double mismatch to the 3'-side of the photoproduct. Evidence that a small percentage of (+) strand repair of a double mismatch to the 3'-side was obtained from transfection experiments in which a second double mismatch was introduced opposite or flanking the photoproduct. Analysis of the minor tandem mutations induced by the (6-4) and Dewar products suggests that the SOS polymerase complex is able to elongate what amounts to double mismatches opposite these photoproducts and is consistent with the action of a highly processive polymerase that lacks proofreading ability.

Dominant negative mutator mutations in the mutS gene of Escherichia coli.

The MutS protein of Escherichia coli is part of the dam-directed MutHLS mismatch repair pathway which rectifies replication errors and which prevents recombination between related sequences. In order to more fully understand the role of MutS in these processes, dominant negative mutS mutations on a multicopy plasmid were isolated by screening transformed wild-type cells for a mutator phenotype, using a Lac+ papillation assay. Thirty-eight hydroxylamine- and 22 N-methyl-N'-nitro-N-nitrosoguanidine-induced dominant mutations were isolated. Nine of these mutations altered the P-loop motif of the ATP-binding site, resulting in four amino acid substitutions. With one exception, the remaining sequenced mutations all caused substitution of amino acids conserved during evolution. The dominant mutations in the P-loop consensus caused severely reduced repair of heteroduplex DNA in vivo in a mutS mutant host strain. In a wild-type strain, the level of repair was decreased by the dominant mutations to between 12 to 90% of the control value, which is consistent with interference of wild-type MutS function by the mutant proteins. Increasing the wild-type mutS gene dosage resulted in a reversal of the mutator phenotype in about 60% of the mutant strains, indicating that the mutant and wild-type proteins compete. In addition, 20 mutant isolates showed phenotypic reversal by increasing the gene copies of either mutL or mutH. There was a direct correlation between the levels of recombination and mutagenesis in the mutant strains, suggesting that these phenotypes are due to the same function of MutS.

Unstable triplets and their mutational mechanism: size reduction of the CGG repeat vs. germline mosaicism in the fragile X syndrome.

The mechanism responsible for the characteristic expansion of the trinucleotide repeat involved in the pathogenesis of the fragile X syndrome is still largely unclear. Slipped strand mispairing (SSM) and similar DNA replication errors could determine both increases and decreases of the unit number in simple repetitive sequences. Actually, there have been a few reports of size reduction of the (CGG)n in parent-to-child transmission of the fragile X syndrome, which may help in understanding the mutational mechanism and may have practical implications for genetic counseling. We describe here 5 such cases from our series of fragile X patients and emphasize the possible role of SSM-like events in causing (CGG)n expansions and reductions. The possibility that some of these reductions are only apparent, resulting from parental germinal mosaicism is also considered.

Geographical variation in prevalence of hepatitis B virus DNA in HBsAg negative patients.

AIMS--To study the geographical variation of the prevalence of hepatitis B virus (HBV) DNA in hepatitis B surface antigen (HBsAg) negative subjects. METHODS--A nested polymerase chain reaction (PCR) assay was used to amplify the core region of HBV. The assay was able to detect 10 molecules of a full length HBV plasmid. RESULTS--When applied to HBsAg negative paraffin wax embedded liver samples from Italy, Hong Kong, and the United Kingdom, a geographical variation in the prevalence of HBV-DNA positivity was noted. Two of 18 (11%) of Italian samples and 2/29 (6.9%) of Hong Kong samples were positive for HBV-DNA while none of the 70 cases from the United Kingdom was positive by nested PCR. Contamination by plasmid DNA was excluded using a novel method based on heteroduplex formation. One HBV-DNA positive case had idiopathic chronic active hepatitis, but the diagnoses in the other three HBV-DNA positive cases did not suggest any aetiological connection between HBV-DNA positivity and liver pathology. CONCLUSIONS--HBV-DNA could be detected in the liver tissues of a proportion of HBsAg negative subjects. The prevalence of such cases is related to the endemic rate of a geographical region. The use of HBV PCR on paraffin wax embedded tissues will be valuable for future studies on the molecular epidemiology of HBV.

Formation of heteroduplex DNA during mammalian intrachromosomal gene conversion.

We have studied intrachromosomal gene conversion in mouse Ltk- cells with a substrate designed to provide genetic evidence for heteroduplex DNA. Our recombination substrate consists of two defective chicken thymidine kinase genes arranged so as to favor the selection of gene conversion products. The gene intended to serve as the recipient in gene conversion differs from the donor sequence by virtue of a palindromic insertion that creates silent restriction site polymorphisms between the two genes. While selection for gene conversion at a XhoI linker insertion within the recipient gene results in coconversion of the nearby palindromic site in more than half of the convertants, 4% of convertant colonies show both parental and nonparental genotypes at the polymorphic site. We consider these mixed colonies to be the result of genotypic sectoring and interpret this sectoring to be a consequence of unrepaired heteroduplex DNA at the polymorphic palindromic site. DNA replication through the heteroduplex recombination intermediate generates genetically distinct daughter cells that comprise a single colony. We believe that the data provide the first compelling genetic evidence for the presence of heteroduplex DNA during chromosomal gene conversion in mammalian cells.