Continuous interscalene block using a stimulating catheter: a review of the technique

The management of postoperative pain after major shoulder surgery can be achieved successfully with a continuous interscalene block. This article reviews the essentials of the stimulating catheter technique for the continuous interscalene block that was described by Boezaart in 1999. The authors also describe their experience and results with the first two hundred catheters they placed.

Towards integrating vectors for gene therapy: expression of functional bacteriophage MuA and MuB proteins in mammalian cells

Bacteriophage Mu has one of the best studied, most efficient and largest transposition machineries of the prokaryotic world. To harness this attractive integration machinery for use in mammalian cells, we cloned the coding sequences of the phage factors MuA and MuB in a eukaryotic expression cassette and fused them to a FLAG epitope and a SV40-derived nuclear localization signal. We demonstrate that these N-terminal extensions were sufficient to target the Mu proteins to the nucleus, while their function in Escherichia coli was not impeded. In vivo transposition in mammalian cells was analysed by co-transfection of the MuA and MuB expression vectors with a donor construct, which contained a miniMu transposon carrying a Hygromycin-resistance marker (Hyg(R)). In all co-transfections, a significant but moderate (up to 2.7-fold) increase in Hyg(R) colonies was obtained if compared with control experiments in which the MuA vector was omitted. To study whether the increased efficiency was the result of bona fide Mu transposition, integrated vector copies were cloned from 43 monoclonal and one polyclonal cell lines. However, in none of these clones, the junction between the vector and the chromosomal DNA was localized precisely at the border of the Att sites. From our data we conclude that expression of MuA and MuB increases the integration of miniMu vectors in mammalian cells, but that this increase is not the result of bona fide Mu-induced transposition.

Opposite effects of Ras or PKC activation on the expression of the SPRR2A keratinocyte terminal differentiation marker

Epidermal growth factor (EGF) enhances the expression of the keratinocyte terminal differentiation marker SPRR2A, when added to monolayers of basal keratinocytes, induced to stratify by increasing the extracellular calcium concentration. A similar stimulation is found during suspension-induced differentiation in methylcellulose. This effect, which is observed after several hours of EGF addition, is restricted to terminally differentiating keratinocytes and is dependent on PKC signaling. EGF also transiently activates the Ras signaling pathway, with a maximum induction after 10 min (Medema et al., 1994, Mol. Cell. Biol. 14, 7078-7085). The cellular effects of activated Ras were determined by transient transfection of Ha-ras(Leu-61) into normal human keratinocytes. Activated Ras completely inhibited PKC-mediated expression of SPRR2A. This inhibition is mediated via c-Jun as it is reversed by a dominant-negative c-Jun mutant (cJunDelta6/194) and c-Jun can substitute for activated Ras. The inhibitory effect is targeted to a 150-bp minimal promoter region, which is essential and sufficient for SPRR2A expression during keratinocyte terminal differentiation. This indicates that the Ras and PKC pathways, which both can be triggered by EGF, although at different time points, have opposite effects on SPRR2A gene expression.

Structure and evolution of the human SPRR3 gene: implications for function and regulation

SPRR3, a member of the SPRR family of cornified envelope precursor proteins, is expressed in oral and esophageal epithelia, where it is strictly linked to keratinocyte terminal differentiation. This gene is characterized by intragenic duplications that have created the characteristic proline-rich repeats in the coding sequence, an alternative noncoding exon, and a 200-bp polypyrimidine tract in the promoter region. Mutational analysis of the promoter region and transient transfection in normal human keratinocytes showed that in addition to the polypyrimidine tract, multiple regulatory elements are involved in differentiation-specific expression. These elements include a high-affinity Ets binding site bound by ESE-1, an AP-1 site (TRE) recognized by the Jun/Fos family of transcription factors, and an ATF/CRE bound by Jun/Fos and ATF factors. The repositioning of the SPRR3 Ets binding site during evolution has a major effect on the relative contribution of this site to promoter activity.

Involvement of a nuclear matrix association region in the regulation of the SPRR2A keratinocyte terminal differentiation marker

The small proline-rich protein genes ( SPRRs ) code for precursors of the cornified cell envelope, and are specifically expressed during keratinocyte terminal differentiation. The single intron of SPRR2A enhanced the activity of the SPRR2A promoter in transient transfection assays. This enhancement was position dependent, and did not function in combination with a heterologous promoter, indicating that the intron does not contain a classical enhancer, and that the enhancement was not due to the splicing reaction per se. Mild DNAse-I digestion of nuclei showed the SPRR2 genes to be tightly associated with the nuclear matrix, in contrast to the other cornified envelope precursor genes mapping to the same chromosomal location (epidermal differentiation complex). In vitro binding studies indicated that both the proximal promoter and the intron of SPRR2A are required for optimal association of this gene with nuclear matrices. Neither nuclear matrix association nor the relative transcriptional enhancement by the intron changed during keratinocyte differentiation. Apparently, the association of the SPRR2A gene with the nuclear matrix results in a general, differentiation-independent enhancement of gene expression.

AP-1 and ets transcription factors regulate the expression of the human SPRR1A keratinocyte terminal differentiation marker

The 173-base pair proximal promoter of SPRR1A is necessary and sufficient for regulated expression in primary keratinocytes induced to differentiate either by increasing extracellular calcium or by 12-O-tetradecanoylphorbol-13-acetate (TPA) treatment. Whereas calcium-induced expression depends both on an AP-1 and an Ets binding site in this region, responsiveness to TPA resides mainly (but not exclusively) on the Ets element, indicating that Ets factors are important targets for protein kinase C signaling during keratinocyte terminal differentiation. This conclusion is further substantiated by the finding that expression of ESE-1, an Ets transcription factor involved in SPRR regulation, is also induced by TPA, with kinetics similar to SPRR1A. The strict AP-1 requirement in SPRR1A for calcium-induced differentiation is not found for SPRR2A, despite the presence of an identical AP-1 consensus binding site in this gene. Binding site swapping indicates that both the nucleotides flanking the TGAGTCA core sequence and the global promoter context are essential in determining the contribution of AP-1 factors in gene expression during keratinocyte terminal differentiation. In the distal SPRR1A promoter region, a complex arrangement of positive and negative regulatory elements, which are only conditionally needed for promoter activity, are likely involved in gene-specific fine-tuning of the expression of this member of the SPRR gene family.

Regulation of single-strand RNA synthesis of alfalfa mosaic virus in non-transgenic cowpea protoplasts by the viral coat protein

We have compared the RNA synthesis of alfalfa mosaic virus in complete (by RNAs 1, 2 and 3) and incomplete infections (by RNAs 1 and 2) of cowpea protoplasts. Both viral RNA polymerase activity and accumulation of viral RNA were measured. By annealing RNA in solution with 32P-labelled probes of plus and minus polarity followed by treatment with ribonucleases, we determined viral RNAs quantitatively in both single- and double-stranded RNA fractions. The accumulation of single-stranded RNA of positive polarity differed considerably between the two types of infection (250 ng vs. less than 1 ng per 10(5) protoplasts), although viral RNA polymerase activities as measured in vitro and the concentrations of minus RNA were similar. Since the method also measured fragmented RNA, this difference is probably not due to lack of protection of viral RNA by coat protein during incomplete infection. Synthesis of single-stranded plus RNA requires either RNA 3 itself or one of its gene products. We postulate that coat protein is the stringent regulator of alfalfa mosaic virus genomic expression.

Function of the homologous regions of the Escherichia coli DNA excision repair proteins UvrB and UvrC in stabilization of the UvrBC-DNA complex and in 3'-incision

The nicking of damaged DNA during the nucleotide excision repair reaction in E. coli, is the result of a multi-step process involving three enzymes, UvrA, UvrB and UvrC. The UvrB protein is loaded on the site of the damage by UvrA, forming a stable UvrB-DNA complex. This complex is recognized by UvrC and in the resulting UvrBC-DNA complex dual incision takes place, first on the 3'-side and next on the 5'-side of the damaged nucleotide. A domain in the C-terminal part of UvrB has been identified to be essential for formation of the specific UvrBC-DNA complex that induces the 3'-incision [1]. The N-terminal half of UvrC contains a region that is homologous to this C-terminal domain of UvrB. Using site-directed mutagenesis of a conserved phenylalanine in the homologous regions of UvrB and UvrC two mutants were constructed, UvrB(F652L) and UvrC(F223L). Both proteins were tested in vitro using a DNA substrate with a defined cisplatin lesion. The protein-DNA and protein-protein interactions were studied using bandshift assays and DNAse I footprinting. We show that both domains are important for the binding of UvrC to the UvrB-DNA complex.

Transitions in the coupling of transcription and nucleotide excision repair within RNA polymerase II-transcribed genes of Saccharomyces cerevisiae

The molecular mechanism of transcription-coupled nucleotide excision repair in eukaryotes is poorly understood. The identification of the dual role of basal transcription factor TFIIH in DNA repair and transcription provided a plausible link between both processes. However, TFIIH is not part of the elongating transcription complex, suggesting that additional components are required to recruit TFIIH when RNA polymerase II (RNAPII) stalls at the site of DNA damage. Previously, we have shown that the yeast Rad26 protein is involved in transcription-coupled DNA repair. This paper describes the differential contribution of the Rad26 protein to efficient removal of UV-induced cyclobutane pyrimidine dimers (CPDs) from transcribed DNA. Two distinct regions within the transcribed strand of RNAPII-transcribed genes are identified that differ in their requirement for the RAD26 gene product. Using high-resolution repair analysis, we determined the in vivo repair kinetics of cyclobutane pyrimidine dimers positioned around the transcription initiation site of RNAPII-transcribed genes RPB2 and URA3. Although transcription-coupled repair is severely reduced in rad26 mutants, lesions positioned in a small region immediately downstream of transcription initiation are efficiently removed in the absence of Rad26. The observed transition in repair characteristics is abrupt and in excellent agreement with the region where TFIIH dissociates from RNAPII in vitro, strongly suggesting an inverse correlation between TFIIH association and Rad26 requirement. These data suggest that a transcription repair coupling factor (Rad26/CSB) is required for efficient repair only during the elongating stages of RNAPII transcription.

The integration host factor-DNA complex upstream of the early promoter of bacteriophage Mu is functionally symmetric

Inversion of the ihf site in the promoter region of the early promoter of bacteriophage Mu did not influence the integration host factor (IHF)-mediated functions. IHF bound to this inverted site could counteract H-NS-mediated repression, directly activate transcription, and support lytic growth of bacteriophage Mu. This implies that the IHF heterodimer and its asymmetrical binding site form a functionally symmetrical complex.

Transcription elongation factor S-II is not required for transcription-coupled repair in yeast

Two different subpathways play a role in removal of UV-induced cyclobutane pyrimidine dimers (CPDs) by nucleotide excision repair (NER). The relatively slow global genome repair subpathway operates on all CPDs irrespective of their position in the DNA, whereas the transcription-coupled repair subpathway is responsible for the rapid removal of CPDs from transcribed strands. In Saccharomyces cerevisiae, the RAD26 gene is implicated in transcription-coupled repair. However, transcription-coupled repair is not completely absent in rad26 mutants, and therefore other gene products are possibly involved in this subpathway. Based on in vitro experiments with purified components, the transcription elongation factor S-II appeared to be a candidate for a function in transcription-coupled repair. To investigate a possible role of S-II in transcription-coupled repair in vivo in yeast, S-II null mutations were introduced into various genetic backgrounds differing in NER capacity. UV sensitivity was not altered by disruption of the S-II gene in a RAD+ (NER proficient) strain, or in rad26 (impaired in efficient transcription-coupled repair), rad7 (lacking global genome repair), or rad7 rad26 (lacking global genome repair, but having residual transcription-coupled repair capacity) mutants. Moreover, S-II did not influence the repair rate on the transcribed strand of the RPB2 gene, either in repair-proficient or in rad7 rad26 backgrounds. Hence, transcription-coupled repair is fully functional in yeast cells lacking the gene encoding S-II. Furthermore, S-II is not required for the Rad26-independent residual transcription-coupled repair in vivo.

Involvement of c-JUN in the regulation of terminal differentiation genes in normal and malignant keratinocytes

In stratifying cultures of human keratinocytes, expression of the proto-oncoprotein c-JUN and the small proline rich 2 (SPRR2) protein, a precursor of the cornified cell envelope, are inversely related. Whereas c-JUN is typically found in basal proliferating cells, SPRR2 is restricted to suprabasal differentiating layers. Malignant keratinocytes (derived from squamous cell carcinoma, SCC) have reduced sprr2 expression, consistent with their low potential to differentiate, and express c-jun at higher levels than normal keratinocytes. A direct relation between c-jun and sprr2 expression was shown in several ways: transient ectopic expression of c-jun inhibits sprr2a promoter activity in normal differentiating cells, whereas in malignant keratinocytes a dominant negative c-jun mutant restored at least partially both the low promoter activity and the expression of endogenous sprr2. These effects are mediated via a 134 bp promoter fragment which does not include the sprr2a AP-1 binding site. Interestingly, in an SCC cell line, constitutively expressing the dominant c-jun mutant, expression of the terminal differentiation marker involucrin is also strongly increased, suggesting that c-JUN is a general modulator of keratinocyte terminal differentiation rather than only affecting the expression of sprr2.

Expression of the SPRR cornification genes is differentially affected by carcinogenic transformation

The small proline rich protein (SPRR) genes constitute a family of conserved genes which are part of the human epidermal differentiation complex (EDC) on chromosome 1q21 and code for precursor proteins of the cornified cell envelope. The expression of these genes is strictly linked to keratinocyte terminal differentiation both in vivo and in vitro. Here we show that cultured cell lines derived from squamous cell carcinoma (SCC) show significantly lower levels of SPRR expression than normal human keratinocytes. However, the residual SPRR expression in SCC lines appears to be both gene and cell line specific. Expression of SPRR2 appears to correlate well with the residual ability of these cells to differentiate. However, the kinetics of SPRR2 expression, following treatment with calcium, an inducer of keratinocyte differentiation, are typical for each cell line and differ substantially from the ones found in normal cells. In most cell lines a rapid transient expression of SPRR2 contrasts with a slow induction leading to a high sustained level of expression in normal cells. This pattern of expression is typical for SPRR2 and not observed for the other SPRR genes or involucrin. Our analysis indicates that the expression of various keratinocyte terminal differentiation markers, even when involved in the same biological process (cornification), can be differentially affected by carcinogenic transformation.

Function of the C-terminal domain of the alpha subunit of Escherichia coli RNA polymerase in basal expression and integration host factor-mediated activation of the early promoter of bacteriophage Mu

Integration host factor (IHF) can activate transcription from the early promoter (Pe) of bacteriophage Mu both directly and indirectly. Indirect activation occurs through alleviation of H-NS-mediated repression of the Pe promoter (P. Van Ulsen, M. Hillebrand, L. Zulianello, P. Van de Putte, and N. Goosen, Mol. Microbiol. 21:567-578, 1996). The direct activation involves the C-terminal domain of the alpha subunit (alphaCTD) of RNA polymerase. We investigated which residues in the alphaCTD are important for IHF-mediated activation of the Pe promoter. Initial in vivo screening, using a set of substitution mutants derived from an alanine scan (T. Gaal, W. Ross, E. E. Blatter, T. Tang, X. Jia, V. V. Krishnan, N. Assa-Munt, R. Ebright, and R. L. Gourse, Genes Dev. 10:16-26, 1996; H. Tang, K. Severinov, A. Goldfarb, D. Fenyo, B. Chait, and R. H. Ebright, Genes Dev. 8:3058-3067, 1994), indicated that the residues, which are required for transcription activation by the UP element of the rrnB P1 promoter (T. Gaal, W. Ross, E. E. Blatter, T. Tang, X. Jia, V. V. Krishnan, N. Assa-Munt, R. Ebright, and R. L. Gourse, Genes Dev. 10:16-26, 1996), are also important for Pe expression in the presence of IHF. Two of the RNA polymerase mutants, alphaR265A and alphaG296A, that affected Pe expression most in vivo were subsequently tested in in vitro transcription experiments. Mutant RNA polymerase with alphaR265A showed no IHF-mediated activation and a severely reduced basal level of transcription from the Pe promoter. Mutant RNA polymerase with alphaG296A resulted in a slightly reduced transcription from the Pe promoter in the absence of IHF but could still be activated by IHF. These results indicate that interaction of the alphaCTD with DNA is involved not only in the IHF-mediated activation of Pe transcription but also in maintaining the basal level of transcription from this promoter. Mutational analysis of the upstream region of the Pe promoter identified a sequence, positioned from -39 to -51 with respect to the transcription start site, that is important for basal Pe expression, presumably through binding of the alphaCTD. The role of the alphaCTD in IHF-mediated stimulation of transcription from the Pe promoter is discussed.

Cloning of Schizosaccharomyces pombe rph16+, a gene homologous to the Saccharomyces cerevisiae RAD16 gene

The RAD16 gene is involved in the nucleotide excision repair of UV damage in the transcriptional silenced mating type loci (Terleth et al., 1990 and Bang et al., 1992) and in non-transcribed stands of active genes in Saccharomyces cerevisiae (Verhage et al., 1994). Using touchdown-PCR with primers derived from various domains of the S. cerevisiae Rad 16 protein, a specific Schizosaccharomyces pombe probe was isolated. This probe was used to obtain the complete RAD16 homologous gene from a S. pombe chromosomal bank. DNA sequence analysis of the rph16+ gene revealed an open reading frame of 854 amino acids. Comparison of the amino acid sequences of the Rhp16 and Rad16 proteins showed a high level of conservation: 68% similarity. The Rhp16 protein sequence contains the two Zn-finger motifs and the putative helicase domains as found in the Rad16 protein. Like the RAD16, the rph16+ gene is UV-inducible (Bang et al., 1995). In analogy with the rad16 mutant, the rhp16 disruption mutant is viable and grows normally, indicating that the gene does not have an essential function. The rhp16 disruption mutant is not sensitive for UV but is sensitive for cisplatin. The rhp16+ gene cloned behind the GAI 1 promoter partially complements the UV sensitivity and the defect in the non-transcribed strand DNA repair of a S. cerevisiae rad16 mutant, indicating functional homology between the rhp16+ and RAD16 genes. The structural and functional homology between the two genes suggests that the RAD16 dependent subpathway of NER for the repair of non-transcribed DNA is evolutionary conserved.

Transcription-coupled and global genome repair in the Saccharomyces cerevisiae RPB2 gene at nucleotide resolution

Repair of UV-induced cyclobutane pyrimidine dimers (CPDs) was examined at single nucleotide resolution in the yeast Saccharomyces cerevisiae, using an improved protocol for genomic end-labelling. To obtain the sensitivity required for adduct detection in yeast, an oligonucleotide-directed enrichment step was introduced into the current methodology developed for adduct detection in Escherichia coli. With this method, heterogeneous repair of CPDs within the RPB2 locus is observed. Individual CPDs positioned in the transcribed strand are removed very efficiently with identical kinetics. This fast repair starts within 23 bases downstream of the transcription initiation site. The non-transcribed strand of the active gene exhibits slow repair without detectable repair variations between individual lesions. In contrast, CPDs positioned in the promoter region show profound repair heterogeneity. Here, CPDs at specific sites are removed very quickly, with comparable rates to CPDs positioned in the transcribed strand, while at other positions lesions are not repaired at all during the period studied. Interestingly, the fast repair in the promoter region is dependent on the RAD7 and RAD16 genes, as are the slowly repaired CPDs in this region and in the non-transcribed strand. This indicates that the global genome repair pathway is not intrinsically slow and at specific positions can be as efficient as the transcription-coupled repair pathway.

Integration host factor alleviates the H-NS-mediated repression of the early promoter of bacteriophage Mu

Integration host factor (IHF), which is a histone-like protein, has been shown to positively regulate transcription in two different ways. It can either help the formation of a complex between a transcription factor and RNA polymerase or it can itself activate RNA polymerase without the involvement of other transcription factors. In this study, we present a third mechanism for IHF-stimulated gene expression, by counteracting the repression by another histone-like protein, H-NS. The early (Pe) promoter of bacteriophage Mu is specifically inhibited by H-NS, both in vivo and in vitro. For this inhibition, H-NS binds to a large DNA region overlapping the Pe promoter. Binding of IHF to a binding site just upstream of Pe alleviates the H-NS-mediated repression of transcription. This same ihf site is also involved in the direct activation of Pe by IHF. In contrast to the direct activation by IHF, however, the alleviating effect of IHF appears not to be dependent on the relevant position of the ihf site on the DNA helix, and it also does not require the presence of the C-terminal domain of the alpha subunit of RNA polymerase. Footprint analysis shows that binding of IHF to the ihf site destabilizes the interaction of H-NS with the DNA, not only in the IHF-binding region but also in the DNA regions flanking the ihf site. These results suggest that IHF disrupts a higher-order nucleoprotein complex that is formed by H-NS and the DNA.

Comparison of spontaneous hprt mutation spectra at the nucleotide sequence level in the endogenous hprt gene and five other genomic positions

Mutation spectra at the nucleotide sequence level of five hprt cDNA genes integrated in different genomic positions of a HPRT(-) derivative of the human lymphoblastoid TK6 cell line were compared with each other and with the spectrum of mutations confined to the 657 bp coding region of the endogenous hprt gene in the parental TK6 cells. The mutation rates in these genomic positions vary significantly and also the mutation spectra are different. In each genomic position the majority of mutations are basepair substitutions and deletions. the ratios of which vary among the genomic positions. Although it is likely that the different rates of deletion are to a large extent the net result of different rates of misalignment and repair of these errors in the various genomic positions, for the basepair substitutions it is not possible to deduce which mechanisms have caused these mutations and what causes the differences among the genomic positions. Taken together, the differences in mutation rates and spectra cannot be explained by a single mutagenic process.

Analysis of gene- and strand-specific repair in the moderately UV-sensitive Saccharomyces cerevisiae rad23 mutant

The RAD23 gene of Saccharomyces cerevisiae is involved in nucleotide excision repair (NER) and mutations in this gene confer a moderate sensitivity to UV irradiation. However, no repair of either cyclobutane pyrimidine dimers (CPDs) and 6-4 photoproducts, the major types of lesions formed upon UV irradiation, was detectable during the first 4 h post UV irradiation in a rad23 mutant. rad23, like the rad7 and rad16 mutants, is not as UV sensitive as completely NER-deficient mutants. The rad7 and rad16 mutants are only partly defective in NER: non-transcribed strands are completely refractory to repair while transcription-coupled repair is not affected. To investigate whether the rad23 mutant has similar strand-specific repair characteristics we analyzed gene-specific CPD removal from several loci using strand-specific probes but did not detect any repair. The moderate UV sensitivity of rad23 mutants as compared to completely NER-deficient mutants is therefore not due to gene- or strand-specific removal of lesions, indicating that rad23 mutants do not have a similar repair defect as rad7 or rad16 mutants, but are presumably defective in general NER. The rad23 mutation does not suppress the high UV sensitivity of completely NER-deficient rad1 or rad14 strains. This demonstrates that the relatively high survival of rad23 mutants in not due to an increased tolerance for the lesions that seem to persist in the genome but rather requires some NER function.

Double mutants of Saccharomyces cerevisiae with alterations in global genome and transcription-coupled repair

The nucleotide excision repair (NER) pathway is thought to consist of two subpathways: transcription-coupled repair, limited to the transcribed strand of active genes, and global genome repair for nontranscribed DNA strands. Recently we cloned the RAD26 gene, the Saccharomyces cerevisiae homolog of human CSB/ERCC6, a gene involved in transcription-coupled repair and the disorder Cockayne syndrome. This paper describes the analysis of yeast double mutants selectively affected in each NER subpathway. Although rad26 disruption mutants are defective in transcription-coupled repair, they are not UV sensitive. However, double mutants of RAD26 with the global genome repair determinants RAD7 and RAD16 appeared more UV sensitive than the single rad7 or rad16 mutants but not as sensitive as completely NER-deficient mutants. These findings unmask a role of RAD26 and transcription-coupled repair in UV survival, indicate that transcription-coupled repair and global genome repair are partially overlapping, and provide evidence for a residual NER modality in the double mutants. Analysis of dimer removal from the active RPB2 gene in the rad7/16 rad26 double mutants revealed (i) a contribution of the global genome repair factors Rad7p and Rad16p to repair of the transcribed strand, confirming the partial overlap between both NER subpathways, and (ii) residual repair specifically of the transcribed strand. To investigate the transcription dependence of this repair activity, strand-specific repair of the inducible GAL7 gene was investigated. The template strand of this gene was repaired only under induced conditions, pointing to a role for transcription in the residual repair in the double mutants and suggesting that transcription-coupled repair can to some extent operate independently from Rad26p. Our findings also indicate locus heterogeneity for the dependence of transcription-coupled repair on RAD26.

The in vitro more efficiently repaired cisplatin adduct cis-Pt.GG is in vivo a more mutagenic lesion than the relative slowly repaired cis-Pt.GCG adduct

The toxic effect and the mutagenicity of two differentially repaired site-specific cis-diamminedichloroplatinum(II) (cis-DDP) lesions were investigated. Detailed analysis of the UvrABC-dependent repair of the two lesions in vitro showed a more efficient repair of the cis-Pt.GG adduct compared to that of the cis-Pt.GCG adduct (Visse et al., 1994). Furthermore, previously, a dependency of cis-DDP mutagenesis on UvrA and UvrB, but not on UvrC was found (Brouwer et al., 1988). To possibly relate survival and mutagenesis to repair, plasmids containing the same site-specific cis-DDP lesions as those that were used in the detailed repair studies were transformed into Escherichia coli. The results indicate that both lesions are very efficiently bypassed in vivo. Mutation analysis was performed using a denaturing gradient gel electrophoresis technique, which allows identification of mutations without previous selection. Although the cis-Pt.GG adduct is in vitro more efficiently repaired than the cis-Pt.GCG adduct, it appeared to be more mutagenic. We present a model in which this result is related to the previously observed dependency of the mutagenicity of cis-DDP lesions on the Uvr A and B proteins.

The C-terminal region of the UvrB protein of Escherichia coli contains an important determinant for UvrC binding to the preincision complex but not the catalytic site for 3'-incision

The UvrABC endonuclease from Escherichia coli repairs damage in the DNA by dual incision of the damaged strand on both sides of the lesion. The incisions are in an ordered fashion, first on the 3'-side and next on the 5'-side of the damage, and they are the result of binding of UvrC to the UvrB-DNA preincision complex. In this paper, we show that at least the C-terminal 24 amino acids of UvrB are involved in interaction with UvrC and that this binding is important for the 3'-incision. The C-terminal region of UvrB, which shows homology with a domain of the UvrC protein, is part of a region that is predicted to be able to form a coiled-coil. We therefore propose that UvrB and UvrC interact through the formation of such a structure. The C-terminal region of UvrB only interacts with UvrC when present in the preincision complex, indicating that the conformational change in UvrB accompanying the formation of this complex exposes the UvrC binding domain. Binding of UvrC to the C-terminal region of UvrB is not important for the 5'-incision, suggesting that for this incision a different interaction of UvrC with the UvrB-DNA complex is required. Truncated UvrB mutants that lack up to 99 amino acids from the C terminus still give rise to significant incision (1-2%), indicating that this C-terminal region of UvrB does not participate in the formation of the active site for 3'-incision. This region, however, contains the residue (Glu-640) that was proposed to be involved in 3'-catalysis, since a mutation of the residue (E640A) fails to promote 3'-incision (Lin, J.J., Phillips, A.M., Hearst, J.E., and Sancar, A. (1992) J. Biol. Chem. 267, 17693-17700). We have isolated a mutant UvrB with the same E640A substitution, but this protein shows normal UvrC binding and incision in vitro and also results in normal survival after UV irradiation in vivo. As a consequence of these results, it is still an open question as to whether the catalytic site for 3'-incision is located in UvrB, in UvrC, or is formed by both proteins.

Atraumatic cardiac arrest in apparently healthy young women

Sudden non-traumatic death in young people (< 30 years old) has been discussed both in systematic studies and anecdotal reports. After presenting three remarkable cases, a global survey of the incidence with special reference to the Belgian CPCR database, ethiopathogenesis and prognosis of sudden non-traumatic death in this specific age group is given. The atherosclerotic coronary artery disease (CAD) related and especially the non-CAD related causes are extensively discussed as well as the role of intoxication and increasing drug and substance abuse. After conventional cardiopulmonary resuscitation with restoration of spontaneous circulation and a favourable neurological outcome, a thorough search for the underlying disease is mandatory. The involvement of drugs or other toxins has to be excluded in the first place. Apart from transoesophageal echocardiography and coronary angiography, electrophysiological testing, serological exams, myocardial biopsy and magnetic resonance imaging should be considered.

Participation of the flank regions of the integration host factor protein in the specificity and stability of DNA binding

The heterodimeric integration host factor (IHF) protein is a site-specific DNA-binding protein from Escherichia coli that strongly bends the DNA. It has been proposed (Yang, C., and Nash, H.A. (1989) Cell 57, 869-880; Granston, A. E., and Nash, H. A. (1993) J. Mol. Biol 234, 45-59; Lee, E. C., Hales, L. M., Gumport, R. I., and Gardner, J. F. (1992) EMBO J. 11, 305-313) that the wrapping of the DNA around the protein is stabilized through interactions between the flanks of the protein and the DNA. In order to elucidate which domains of the IHF protein are involved in these interactions, we have constructed mutant proteins in which the C-terminal part of one of the subunits has been deleted. We observed that the C-terminal alpha 3 helix of HimD is involved in the stability of DNA binding, but not in the specificity. In contrast the corresponding alpha 3 helix of HimA is essential for the sequence specificity, since an IHF mutant lacking this domain only binds to the DNA in a non-specific way. The possible role of the two C-terminal alpha-helical structures in complex formation will be discussed. We also examined the properties of an IHF mutant that has an amino acid substitution between beta sheets beta 1 and beta 2 of the HimD subunit (R46H). The occupancy of the ihf site by the mutant and wild type proteins differ in the 3' part of the ihf site and as a result the bend introduced in the DNA by the mutant protein is less pronounced. We propose that the arginine 46 in the HimD subunit is in vicinity of the TTR region of the consensus and that through contacts within the minor groove the DNA bend introduced by IHF is stabilized.

Regulation of the Saccharomyces cerevisiae DNA repair gene RAD16

The RAD16 gene product has been shown to be essential for the repair of the silenced mating type loci [Bang et al. (1992) Nucleic Acids Res. 20, 3925-3931]. More recently we demonstrated that the RAD16 and RAD7 proteins are also required for repair of non-transcribed strands of active genes in Saccharomyces cerevisiae [Waters et al. (1993) Mol. Gen. Genet. 239, 28-32]. We have studied the regulation of the RAD16 gene and found that the RAD16 transcript levels increased up to 7-fold upon UV irradiation. Heat shock at 42 degrees C also results in elevated levels of RAD16 mRNA. In sporulating MAT alpha/MATa diploid cells RAD16 mRNA is also induced. The basal level of the RAD16 transcript is constant during the mitotic cell cycle. G1-arrested cells show normal induction of RAD16 mRNA upon UV irradiation demonstrating that the induction is not a secondary consequence of G2 cell cycle arrest following UV irradiation. However, in cells arrested in G1 the induction of RAD16 mRNA after UV irradiation is not followed by a rapid decline as occurs in normal growing cells suggesting that the down regulation of RAD16 transcription is dependent on progression into the cell cycle.

The regulation of transcription initiation by integration host factor

Integration host factor (IHF) of Escherichia coli is an asymmetric histone-like protein that binds and bends the DNA at specific sequences. IHF functions as an accessory factor in a wide variety of processes including replication, site-specific recombination and transcription. In many of these processes IHF was shown to act as an architectural element which helps the formation of nucleo-protein complexes by bending of the DNA at specific sites. This MicroReview shows how such a structural role of IHF can influence the initiation of transcription. In addition, it summarizes the evidence indicating that IHF can stimulate transcription via a direct interaction with RNA polymerase and explores the possibility that the asymmetry of the IHF protein might reflect such an interaction.

Spontaneous mutation spectrum in the hprt gene in human lymphoblastoid TK6 cells

A spectrum of 100 mutations in the endogenous hprt gene of the human lymphoblastoid TK6 cell line is presented. The majority of the mutations originates in sequences outside the coding region of the gene. Large deletions are a major cause of inactivation of the hprt gene (57% of the mutants). Mutations in the splice sites that result in several forms of aberrantly spliced mRNA are relatively frequently recovered (16%) compared with mutants containing alterations in the coding region of the hprt gene (27%). The majority, but not all, of the splice mutants contain an alteration in the consensus sequences of the splice sites. A spectrum of mutations in the coding region of the hprt gene enlarged to a total of 42 mutants shows that basepair substitutions predominate (71%) and that small deletions and insertions are less frequently recovered. Basepair substitutions arise slightly more frequently at GC basepairs than at AT basepairs.

Gin invertase of bacteriophage Mu is a dimer in solution, with the domain for dimerization in the N-terminal part of the protein

The Gin protein of bacteriophage Mu mediates recombination between two inverted repeat sequences. Gin binds as a dimer to each of these recombination sites. We show that Gin is a dimer in solution also, and that the dimerization is probably stabilized by hydrophobic interactions between the subunits. The subunits of the dimer could efficiently be cross-linked with the 4-A cross-linker diepoxybutane. Spontaneous oxidation of Cys(24) and/or Cys(27) also resulted in intersubunit cross-linking. One or both cysteine residues are located at the interface of the Gin dimer, which maps the dimerization domain in the N-terminal part of the protein. Binding of the disulfide-bonded dimers of Gin to a recombination site was strongly reduced, suggesting that the subunits need to reorient in order to form a stable protein-DNA complex. In the protein-DNA complex, however, oxidation of cysteine residues still seems to be possible, indicating that the N-terminal parts of two Gin subunits are also in close proximity when bound to DNA.

Effects of N-terminal deletions of the Escherichia coli protein Fis on growth rate, tRNA(2Ser) expression and cell morphology

The Escherichia coli Fis protein is known to be involved in a variety of processes, including the activation of stable RNA operons. In this paper we study the ability of a set of N-terminal Fis deletion mutants to stimulate transcription of the tRNA(2Ser) gene. The results indicate that the domain of the Fis protein containing residues 1-26 is not required for transcription activation. The Fis mutants that are still active in transcription stimulation can also complement the reduced growth rates of Fis- cells, suggesting that the same activating domain is involved in this phenomenon. In addition, we show that in fast growing cultures in the absence of an active Fis protein, minicells are formed. These minicells seem to arise from septum formation near the cell poles. Suppression of minicell formation by Fis also does not require the presence of the N-terminal domain of the protein.

UV-induced mutagenesis in the endogenous hprt gene and in hprt cDNA genes integrated at different positions of the human genome

The influence of the genomic position of a gene on UV-induced mutations was studied in the endogenous hprt gene in human lymphoblastoid TK6 cells and in cell lines derived from TK6 each containing a single copy of a hamster hprt cDNA gene integrated on a retroviral vector in different positions of the human genome. Previous studies showed that the genomic sequences surrounding the integration site influence spontaneous mutagenesis, resulting in a 10-fold difference in mutation rates among the hprt cDNA genes. Here we demonstrate that the genomic positions of three integrated hprt cDNA genes do not influence UV-induced mutagenesis. The mutability by UV irradiation in these cell lines is approximately the same (16.0 x 10(-6) per J/m2). The nature of the UV-induced mutations determined in two of the cell lines containing the integrated hprt cDNA gene (approximately 30 mutants each) was also found not to be different. The endogenous hprt gene in the parental TK6 cells exhibits a significantly lower mutability (2.1 x 10(-6) per J/m2) than the cDNA genes, but the spectrum is very similar. The spectrum in TK6 shows no influence of strand-specific repair and resembles most closely the spectrum obtained by McGregor et al. after irradiation of human cells synchronized in S-phase. This suggests that mutations arising in cells that are in S-phase at the time of irradiation constitute the majority of the mutants in an asynchronous TK6 cell population. We hypothesize that repair in the endogenous hprt gene in TK6 cells is very efficient, removing virtually all lesions before replication takes place except in cells that were in S-phase at the time of irradiation when there is not enough time for repair. Furthermore we suggest that the higher mutability of the integrated hprt cDNA genes compared with the endogenous gene is caused by a less efficient repair in the cDNA genes.

Gin mutants that can be suppressed by a Fis-independent mutation

The Gin invertase of bacteriophage Mu mediates recombination between two inverted gix sites. Recombination requires the presence of a second protein, Fis, which binds to an enhancer sequence. We have isolated 24 different mutants of Gin that are impaired in DNA inversion but proficient in DNA binding. Six of these mutants could be suppressed for inversion by introduction of a second mutation, which when present in the wild-type gin gene causes a Fis-independent phenotype. Only one of the six resulting double mutants shows an inversion efficiency which is comparable to that of the wild-type Gin and which is independent of Fis. The corresponding mutation, M to I at position 108 (M108I), is located in a putative alpha-helical structure, which in the homologous gamma delta resolvase has been implicated in dimerization. The properties of the M108I mutant suggest that in Gin this dimerization helix might also be the target for Fis interaction. The five other mutants that show a restored inversion after introduction of a Fis-independent mutation appear to be completely dependent on Fis for this inversion. The corresponding mutations are located in different domains of the protein. The properties of these mutants in connection with the role of Fis in inversion will be discussed.

RAD26, the functional S. cerevisiae homolog of the Cockayne syndrome B gene ERCC6

Transcription-coupled repair (TCR) is a universal sub-pathway of the nucleotide excision repair (NER) system that is limited to the transcribed strand of active structural genes. It accomplishes the preferential elimination of transcription-blocking DNA lesions and permits rapid resumption of the vital process of transcription. A defect in TCR is responsible for the rare hereditary disorder Cockayne syndrome (CS). Recently we found that mutations in the ERCC6 repair gene, encoding a putative helicase, underly the repair defect of CS complementation group B. Here we report the cloning and characterization of the Saccharomyces cerevisiae homolog of CSB/ERCC6, which we designate RAD26. A rad26 disruption mutant appears viable and grows normally, indicating that the gene does not have an essential function. In analogy with CS, preferential repair of UV-induced cyclobutane pyrimidine dimers in the transcribed strand of the active RBP2 gene is severely impaired. Surprisingly, in contrast to the human CS mutant, yeast RAD26 disruption does not induce any UV-, cisPt- or X-ray sensitivity, explaining why it was not isolated as a mutant before. Recovery of growth after UV exposure was somewhat delayed in rad26. These findings suggest that TCR in lower eukaryotes is not very important for cell survival and that the global genome repair pathway of NER is the major determinant of cellular resistance to genotoxicity.

The RAD7 and RAD16 genes, which are essential for pyrimidine dimer removal from the silent mating type loci, are also required for repair of the nontranscribed strand of an active gene in Saccharomyces cerevisiae

The rad16 mutant of Saccharomyces cerevisiae was previously shown to be impaired in removal of UV-induced pyrimidine dimers from the silent mating-type loci (D. D. Bang, R. A. Verhage, N. Goosen, J. Brouwer, and P. van de Putte, Nucleic Acids Res. 20:3925-3931, 1992). Here we show that rad7 as well as rad7 rad16 double mutants have the same repair phenotype, indicating that the RAD7 and RAD16 gene products might operate in the same nucleotide excision repair subpathway. Dimer removal from the genome overall is essentially incomplete in these mutants, leaving about 20 to 30% of the DNA unrepaired. Repair analysis of the transcribed RPB2 gene shows that the nontranscribed strand is not repaired at all in rad7 and rad16 mutants, whereas the transcribed strand is repaired in these mutants at a fast rate similar to that in RAD+ cells. When the results obtained with the RPB2 gene can be generalized, the RAD7 and RAD16 proteins not only are essential for repair of silenced regions but also function in repair of nontranscribed strands of active genes in S. cerevisiae. The phenotype of rad7 and rad16 mutants closely resembles that of human xeroderma pigmentosum complementation group C (XP-C) cells, suggesting that RAD7 and RAD16 in S. cerevisiae function in the same pathway as the XPC gene in human cells. RAD4, which on the basis of sequence homology has been proposed to be the yeast XPC counterpart, seems to be involved in repair of both inactive and active yeast DNA, challenging the hypothesis that RAD4 and XPC are functional homologs.

Protein-DNA interactions and alterations in the DNA structure upon UvrB-DNA preincision complex formation during nucleotide excision repair in Escherichia coli

The UvrB-DNA preincision complex is a key intermediate in the repair of damaged DNA by the UvrABC endonuclease from Escherichia coli. DNaseI footprinting of this complex on DNA with a cis-[Pt(NH3)2[d(GpG)-N7(1),N7(2)]] adduct provided global information on the protein binding site on this substrate [Visse, R., et al. (1991) J. Biol. Chem. 266, 7609-7617]. By applying a method developed by Fairall and Rhodes [Fairall, L., & Rhodes, D. (1992) Nucleic Acids Res. 20, 4727-4731], who have used the size and shape of DNasI for the interpretation of a footprint, we were able to define in more detail the region where UvrB-DNA interactions in the preincision complex occur. The potential interactions with phosphate groups could be reduced to less then 14 in the damaged and to 12 in the nondamaged strand. The main UvrB-DNA interactions seem restricted to the major groove on both sides of the lesion. As a consequence UvrB crosses the minor groove just downstream of the damage. Such a binding of UvrB orients the protein away from the damage. The more detailed interpretation of UvrB-DNA interactions was supported by methylation protection experiments. The structure of the DNA in the preincision complex formed on cis-[Pt(NH3)2[GpG-N7(1),N7(2)]] is altered as could be shown diethylpyrocarbonate sensitivity of adenines just downstream of the lesion. However the adenines just downstream of another cisplatin adduct, cis-[Pt(NH3)2[d(GpCpG)-N7(1),N7(3)]], did not become diethylpyrocarbonate sensitive in the preincision complex although this complex is incision proficient.(ABSTRACT TRUNCATED AT 250 WORDS)

Helicase motifs V and VI of the Escherichia coli UvrB protein of the UvrABC endonuclease are essential for the formation of the preincision complex

The UvrB protein is a subunit of the UvrABC endonuclease which is involved in the repair of a large variety of DNA lesions. We have 91 isolated random uvrB mutants which are impaired in the repair of UV-damage in vivo. These mutants were classified on the basis of the ability to form normal levels of protein and the position of the mutations in the gene. The amino acid substitutions in the N-terminal part or in the C-terminal part of the UvrB protein are exclusively found in the conserved boxes of the so-called "helicase motifs" present in these parts of the protein, indicating that these motifs are essential for UvrB function. The proteins of four C-terminal mutants were purified: two mutants in motif V (E514K and G509S), one mutant in motif VI (R544H) and a double mutant in both motifs (E514K + R541H). In vitro experiments with these mutant proteins show that the helicase motifs V and VI are involved in the induction of ATP hydrolysis in the presence of (damaged) DNA and in the strand-displacement activity of the UvrA2B complex as is observed in a helicase assay. Furthermore, our results suggest that this strand-displacement activity is correlated to a local unwinding, which seems to be used to form the UvrB-DNA preincision complex.

The HimA and HimD subunits of integration host factor can specifically bind to DNA as homodimers

Integration host factor (IHF) is a heterodimeric protein from Escherichia coli which specifically binds to an asymmetric consensus sequence. We have isolated the individual subunits of IHF, HimA and HimD, and show that an active IHF protein can be reconstituted from these subunits. The HimA and HimD polypeptides alone are capable of specifically recognizing the same ihf sequence. The mobilities of the protein-DNA complexes in a gel-retardation assay suggest that the proteins bind as homodimers. The stability of the HimD-DNA complex is approximately 100-fold lower than that of the IHF-DNA complex. The HimA-DNA complex is even less stable and is only observed when a large excess of HimA is used. This instability is possibly due to the inability of HimA to form stable homodimers. By domain swapping between HimA and HimD, we have constructed an IHF fusion protein which has the putative DNA-binding domains of only HimA. This fusion protein forms stable dimers and makes specific protein-DNA complexes with a high efficiency. A comparable fusion protein with only the DNA-binding domains of HimD forms less stable complexes, suggesting that sequence-specific contacts between IHF and the ihf consensus are mainly provided by the HimA subunit.

Transposase A binding sites in the attachment sites of bacteriophage Mu that are essential for the activity of the enhancer and A binding sites that promote transposition towards Fpro-lac

In this paper we determine which of the A binding sites in the attachment sites of phage Mu are required for the stimulatory activity of the transpositional enhancer (IAS). For this purpose the transposition frequencies of mini-Mu's with different truncated attachment sites to an Ftet target were measured both in the presence and the absence of the IAS. The results show that in our in vivo assay the L3 and R3 sites are dispensable for functioning of the IAS. An additional deletion of L2 or R2 however abolishes the stimulating activity of the enhancer suggesting an interaction between A molecules bound to these sites and the IAS. The residual transposition activity of a IAS-containing mini Mu in which R2 (and R3) are deleted is much lower than the activity of the comparable construct without the IAS. This means that in the absence of R2 the IAS is inhibiting transposition. Such an inhibition is not observed when L2 (and L3) are deleted. This suggests that the IAS interacts with the attachment sites in an ordered fashion, first with attL and then with attR. Furthermore we show that mini-Mu transposition is enhanced when Fpro-lac is used as a target instead of Ftet. We show that this elevated transposition is dependent on the Mu A binding sites L2,L3 and R2. These sequences could possibly mediate an interaction between the mini-Mu plasmid and sequences present on Fpro-lac.

The actual incision determines the efficiency of repair of cisplatin-damaged DNA by the Escherichia coli UvrABC endonuclease

The UvrABC endonuclease from Escherichia coli repairs a broad spectrum of DNA lesions with variable efficiencies. The effectiveness of repair is influenced by the nature of the lesion, the local DNA sequence, and/or the topology of the DNA. To get a better understanding of the aspects of this multistep repair reaction that determine the effectiveness of repair, we compared the incision efficiencies of linear DNA fragments containing either a site-specific cis-[Pt(NH3)2(d(GpG)-N7(1),-N7(2)]] or a cis- Pt(NH3)2[d(GpCpG)-N7(1),-N7(3)]] adduct. Overall the DNA with the cis-PtGG adduct was incised about 3.5 times more efficiently than the cis-Pt.GCG-containing DNA. The rate of UvrB-DNA preincision complex formation for both lesions was similar and high in relation to the incision. DNase I footprints, however, showed that the local structure of the two preincision complexes is different. An assay was developed to measure the binding of UvrC to the preincision complexes and it was found that the binding rate of UvrC to the more slowly incised cis-Pt.GCG preincision complex was higher than to the cis-Pt.GG preincision complex. This most likely reflects a qualitative difference in preincision complex structures. For both lesions the binding of UvrC to the preincision complex was fast compared to the kinetics of actual incision. Apparently, direct incision of cisplatin damage requires an additional conformational change after the binding of UvrC.

Inhibition of bacteriophage Mu transposition by Mu repressor and Fis

In this paper we show that the Escherichia coli protein Fis has a regulatory function in Mu transposition in the presence of Mu repressor. Fis can lower the transposition frequency of a mini-Mu 3-80-fold, but only if the Mu repressor is expressed simultaneously. In this novel type of regulation of transposition by the concerted action of Fis and repressor, the IAS, the internal activating sequence, is also involved as deletion of this site lead to the loss of the Fis effect. As the IAS contains strong repressor binding sites these are probably the target for the repressor in the observed negative regulation by Fis and repressor. However, the role of Fis and repressor is not only to inactivate the IAS, since a 4 bp insertion in the IAS, which changes the spacing of the repressor-binding site, abolishes the enhancing function of the IAS but leaves the repressor-Fis effect intact. A likely target for Fis in this regulation is a strong Fis-binding site, which is located adjacent to the L2 transposase-binding site. However, when this Fis-binding sequence was substituted by a random sequence and Fis no longer showed specific binding to this site, the Fis effect was still observed. Although it is still possible that Fis can function by binding to this non-specific site in a particular complex, it seems more likely that Fis is directly or indirectly involved in determining the level of the repressor.

The first zinc-binding domain of UvrA is not essential for UvrABC-mediated DNA excision repair

Specific mutations in uvrA were introduced to analyze the role of the zinc-binding domains of the protein in DNA excision repair. Zinc-coordinating cysteines were substituted into non-coordinating serine or glycine residues. Mutations leading to changes in the second zinc-binding domain had a profound effect on UV survival in vivo; however these mutant proteins could not be isolated for in vitro analyses. Amino acid substitutions in the first zinc-binding domain had very little effect on UV survival in vivo. In vitro analyses showed that although this domain no longer coordinates zinc, ATPase activity, helicase activity, DNA binding, incision of damaged DNA and DNA repair synthesis appeared to be normal. Therefore it seems that the first zinc-binding domain of UvrA is not essential for DNA excision repair.

Mutation induction by UV light in retroviral hprt cDNA integrated at various chromosomal positions in repair-deficient hamster cells

Mutation induction by UV irradiation was studied in a retroviral vector integrated in one copy per cell at various chromosomal positions. As a mutational target, hamster hprt cDNA was present on the retroviral vector. To minimize the influence of repair we used repair-deficient hamster cells, V-H1 and UV5, as a recipient for the vector. There is no major influence of chromosomal position on UV-induced mutation frequency and spectrum because no statistically significant difference between mutation induction in retroviral cDNA copies integrated at different chromosomal sites was observed. However, a major difference was found in mutation induction between the endogenous hamster hprt gene and the retroviral cDNA copies. Most noticeable was the absence in the cDNA of the strong strand bias for mutation induction, which was reported for the endogenous hprt gene. Our results with the hprt cDNA exclude as a general phenomenon a difference in mutation induction for leading and lagging strand DNA replication, which was proposed as an explanation for this strand bias in the endogenous gene. The similarity of mutation induction in the different retroviral cDNA copies, all directly surrounded by the same DNA sequence elements, together with the marked difference between the mutation induction in the endogenous gene and the cDNA copies may point to an important role of chromatin structure in mutation induction.

Genome wide spontaneous mutation in human cells determined by the spectrum of mutations in hprt cDNA genes

We have studied spontaneous mutagenesis in five hprt cDNA genes integrated at five different genomic positions in a human lymphoblastoid cell line (TK6). The spectra of 40 mutants from each position were combined to obtain a mutation spectrum of the overall genome. This collection of mutants was used to assess the contribution of several mutagenic processes to spontaneous mutagenesis. Deletions and single base pair changes account for the majority of the mutants and arise in approximately equal amounts (43 and 41%, respectively). The majority of the deletions and insertions are < 5 bp and are likely to be caused by template-directed misalignment (slippage) during replication. To account for frameshifts at non-iterated sites we propose a slightly different template-directed replication error model. A considerable amount of the observed base pair changes can also be explained by this last model, but several other processes leading to base pair changes such as depurination, deamination or spontaneously arising DNA damage are likely to contribute as well. We have compared this spectrum with mutation spectra in the endogenous hprt genes using published mutation data. It is shown that in the endogenous genes the contribution of base pair substitutions is much larger (71%) than in the hprt cDNA integrates and that deletions are less frequently observed (20%). The mutation rates of the integrated hprt cDNA genes show a mean increase of 30-fold as compared with the endogenous hprt gene. This results in a 60-fold increase of the absolute rate of deletion in the hprt cDNA genes and in a 15-fold increase of the base pair substitution rate. Replication errors such as slippage or the mechanism proposed in this study probably account to a large extent for this increase.

Genomic position influences spontaneous mutagenesis of an integrated retroviral vector containing the hprt cDNA as target for mutagenesis

We have used five isogenic human lymphoblastoid cell lines each containing a retroviral vector at a different position in the genome to assess the influence of these positions on spontaneous mutagenesis. The vector contains the hamster hprt cDNA and the neo gene, both genes are transcribed from the retroviral LTR promoter. The rates of mutation leading to a HPRT- phenotype during growth in non-selective medium differed up to 60-fold in the five retroviral integrates, ranging from 5.9 x 10(-6) to 3.5 x 10(-4) mutations per cell generation. From each of the cell lines approximately 20 independent mutants were analyzed by Southern blot analysis. In two cell lines all mutations were caused by inactivation of the LTR promoter (presumably by DNA methylation), whereas in another cell line the estimated rate of this mutation is 1000-fold lower. Another important class of mutation is homologous recombination between the LTRs. This accounts for at least half of the mutants in the other three cell lines. Mutants carrying deletions or point mutations form a minor fraction of the mutant distribution. Mutations confined to the hprt cDNA sequences only were studied by selecting HPRT- mutants in the presence of G418. Even for this subset of mutations the rates can vary at least 10-fold between the different genomic positions, ranging from 4.2 x 10(-7) to 5.1 x 10(-6). We conclude therefore that mutations leading to a HPRT- phenotype are quantitatively as well as qualitatively different in the studied cell lines. This suggests that spontaneous mutagenesis in a gene is dependent on its position in the genome.

DNA inversions in phages and bacteria

In certain phages and bacteria, there is a recombination system that specifically promotes the inversion of a DNA fragment. These inversion events appear to act as genetic switches allowing the alternate expression of different sets of genes which in general code for surface proteins. The mechanism of inversion in one class of inversion systems (Gin/Hin) has been studied in detail. It involves the formation of a highly specific nucleoprotein complex in which not only the two recombination sites and the DNA invertase participate but also a recombinational enhancer to which the DNA-bending protein Fis is bound.

Molecular cloning of RAD16, a gene involved in differential repair in Saccharomyces cerevisiae

We have cloned the RAD16 gene of Saccharomyces cerevisiae and determined its nucleotide sequence. The gene complements the UV sensitivity of a rad16 mutant and restores the ability to repair the transcriptionally inactive HML alpha locus that is absent in this mutant. Disruption mutants that were constructed using the cloned gene are viable and UV sensitive and show no detectable growth defect. Moreover, such a mutant is deficient for repair of the HML alpha locus. The nucleotide sequence shows that the gene codes for a protein of 790 amino acids that has two potential zinc binding domains and shares homology with two other yeast proteins: the RAD54 gene product involved in recombinational repair and SNF2, a transcription factor that possibly functions in transcription activation through an interaction with chromatin components that allows access of other factors involved in transcription. The role of RAD16 in the repair of HML alpha might be to change the chromatin structure of silenced genes to provide access for excision repair enzymes.

Preferential repair and strand-specific repair of benzo[a]pyrene diol epoxide adducts in the HPRT gene of diploid human fibroblasts

If excision repair-proficient human cells are allowed time for repair before onset of S phase, the premutagenic lesions formed by (+/-)-7 beta,8 alpha-dihydroxy-9 alpha,10 alpha-epoxy- 7,8,9,10-tetrahydrobenzo[a]pyrene (benzo[a]pyrene diol epoxide, BPDE) are lost from the transcribed strand of the hypoxanthine (guanine) phosphoribosyltransferase (HPRT) gene faster than from the nontranscribed strand. No change in strand distribution is seen with repair-deficient cells. These results suggest strand-specific repair of BPDE-induced DNA damage in human cells. To test this, we measured the initial number of BPDE adducts formed in each strand of the actively transcribed HPRT gene and the rate of repair, using UvrABC excinuclease in conjunction with Southern hybridization and strand-specific probes. We also measured the rate of loss of BPDE adducts from the inactive 754 locus. The frequencies of adducts formed by exposure to BPDE (1.0 or 1.2 microM) in either strand of a 20-kilobase fragment that lies entirely within the transcription unit of the HPRT gene were similar; the frequency in the 14-kilobase 754 fragment was approximately 20% lower. The rates of repair in the two strands of the HPRT fragment differed significantly. Within 7 hr after treatment with 1.2 microM BPDE, 53% of the adducts had been removed from the transcribed strand, but only 26% from the nontranscribed strand; after 20 hr, these values were 87% and 58%, respectively. In contrast, only approximately 14% of the BPDE adducts were lost from the 754 locus in 20 hr, a value even lower than the rate of loss from the overall genome (i.e., 38%). These results demonstrate strand-specific and preferential repair of BPDE adducts in human cells. They suggest that the heterogeneous repair of BPDE adducts in the human genome cannot be accounted for merely by the greatly increased rate of the repair specific to the transcribed strand of the active genes, and they point to a role for the chromatin structure.