Expression and functional analyses of the Dxpa gene, the Drosophila homolog of the human excision repair gene XPA

Cross-species investigation into the requirement of XPA for nucleotide excision repair

After reconstitution of nucleotide excision repair (excision repair) with XPA, RPA, XPC, TFIIH, XPF-ERCC1 and XPG, it was concluded that these six factors are the minimal essential components of the excision repair machinery. All six factors are highly conserved across diverse organisms spanning yeast to humans, yet no identifiable homolog of the XPA gene exists in many eukaryotes including green plants. Nevertheless, excision repair is reported to be robust in the XPA-lacking organism, Arabidopsis thaliana, which raises a fundamental question of whether excision repair could occur without XPA in other organisms. Here, we performed a phylogenetic analysis of XPA across all species with annotated genomes and then quantitatively measured excision repair in the absence of XPA using the sensitive whole-genome qXR-Seq method in human cell lines and two model organisms, Caenorhabditis elegans and Drosophila melanogaster. We find that although the absence of XPA results in inefficient excision repair and UV-sensitivity in humans, flies, and worms, excision repair of UV-induced DNA damage is detectable over background. These studies have yielded a significant discovery regarding the evolution of XPA protein and its mechanistic role in nucleotide excision repair.

Nucleotide excision repair genes shaping embryonic development

Nucleotide excision repair (NER) is a highly conserved mechanism to remove helix-distorting DNA lesions. A major substrate for NER is DNA damage caused by environmental genotoxins, most notably ultraviolet radiation. Xeroderma pigmentosum, Cockayne syndrome and trichothiodystrophy are three human disorders caused by inherited defects in NER. The symptoms and severity of these diseases vary dramatically, ranging from profound developmental delay to cancer predisposition and accelerated ageing. All three syndromes include developmental abnormalities, indicating an important role for optimal transcription and for NER in protecting against spontaneous DNA damage during embryonic development. Here, we review the current knowledge on genes that function in NER that also affect embryonic development, in particular the development of a fully functional nervous system.

Characterizing the Binding Interactions between DNA-Binding Proteins, XPA and XPE: A Molecular Dynamics Approach

The scaffold nature of Xeroderma pigmentosum complementation group A (XPA) protein makes it an important member of nucleotide excision repair (NER) that removes bulky DNA lesions with the help of various protein-protein interactions (PPI) and DNA-protein interactions. However, many structural insights of XPA's interaction and the binding patterns with other NER proteins are yet to be understood. Here, we have studied one such crucial PPI of XPA with another NER protein, Xeroderma pigmentosum complementation group A (XPE), by using the previously identified binding site of XPA (residues 185-226) in the Assisted Model Building With Energy Refinement force-field-mediated dynamic system. We studied the relationship between XPA_185-226-XPE complex using three different docked models. The major residues observed in all of the models that were responsible for the PPI of this complex were Arg20, Arg47, Asp51, and Leu57 from XPE and the residues Leu191, Gln192, Val193, Trp194, Glu198, Glu202, Glu205, Arg207, Glu209, Gln216, and Phe219 from XPE_185-226. During the simulation study, the orientation of XPA was also noted to be changed by almost 180° in models 1 and 3, which remain unchanged in model 2, indicating that XPA interacts with XPE with its N-terminal end facing downward and C-terminal end facing upward. The same was concurrent with the binding of DNA-binding domain region of XPA (aa98-239) with XPE. The N-terminal of XPE was stretched for accommodating XPA. Using the per-residue energy decomposition analysis for the interface residues of all models, the binding affinity between these proteins were found to be dependent on R20, R47, and L57 of XPE and the residues L191, V193, W194, E198, E202, E205, R207, and F219 of XPA. The net binding free energy of the XPA_185-226-XPE protein complex was found to be -48.3718 kcal mol^-1 for model 1, -49.09 kcal mol^-1 for model 2, and -56.51 kcal mol^-1 for model 3.

Structural and sequence similarities of hydra xeroderma pigmentosum A protein to human homolog suggest early evolution and conservation

Xeroderma pigmentosum group A (XPA) is a protein that binds to damaged DNA, verifies presence of a lesion, and recruits other proteins of the nucleotide excision repair (NER) pathway to the site. Though its homologs from yeast, Drosophila, humans, and so forth are well studied, XPA has not so far been reported from protozoa and lower animal phyla. Hydra is a fresh-water cnidarian with a remarkable capacity for regeneration and apparent lack of organismal ageing. Cnidarians are among the first metazoa with a defined body axis, tissue grade organisation, and nervous system. We report here for the first time presence of XPA gene in hydra. Putative protein sequence of hydra XPA contains nuclear localization signal and bears the zinc-finger motif. It contains two conserved Pfam domains and various characterized features of XPA proteins like regions for binding to excision repair cross-complementing protein-1 (ERCC1) and replication protein A 70 kDa subunit (RPA70) proteins. Hydra XPA shows a high degree of similarity with vertebrate homologs and clusters with deuterostomes in phylogenetic analysis. Homology modelling corroborates the very close similarity between hydra and human XPA. The protein thus most likely functions in hydra in the same manner as in other animals, indicating that it arose early in evolution and has been conserved across animal phyla.

Fusarium mycotoxin-contaminated wheat containing deoxynivalenol alters the gene expression in the liver and the jejunum of broilers

The effects of mycotoxins in the production of animal feed were investigated using broiler chickens. For the feeding trial, naturally Fusarium mycotoxin-contaminated wheat was used, which mainly contained deoxynivalenol (DON). The main effects of DON are reduction of the feed intake and reduced weight gain of broilers. At the molecular level, DON binds to the 60 S ribosomal subunit and subsequently inhibits protein synthesis at the translational level. However, little is known about other effects of DON, for example, at the transcriptional level. Therefore, a microarray analysis was performed, which allows the investigation of thousands of transcripts in one experiment. In the experiment, 20 broilers were separated into four groups of five broilers each at day 1 after hatching. The diets consisted of a control diet and three diets with calculated, moderate concentrations of 1.0, 2.5 and 5.0 mg DON/kg feed, which was attained by exchanging uncontaminated wheat with naturally mycotoxin-contaminated wheat up to the intended DON concentration. The broilers were held at standard conditions for 23 days. Three microarrays were used per group to determine the significant alterations of the gene expression in the liver (P < 0.05), and qPCR was performed on the liver and the jejunum to verify the results. No significant difference in BW, feed intake or feed conversion rate was observed. The nutrient uptake into the hepatic and jejunal cells seemed to be influenced by genes: SLC2A5 (fc: -1.54, DON2.5), which facilitates glucose and fructose transport and SLC7A10 (fc: +1.49, DON5), a transporter of d-serine and other neutral amino acids. In the jejunum, the palmitate transport might be altered by SLC27A4 (fc: -1.87, DON5) and monocarboxylates uptake by SLC16A1 (fc: -1.47, DON5). The alterations of the SLC gene expression may explain the reduced weight gain of broilers chronically exposed to DON-contaminated wheat. The decreased expressions of EIF2AK3 (fc: -1.29, DON2.5/5) and DNAJC3 (fc: -1.44, DON2.5) seem to be related to the translation inhibition. The binding of DON to the 60 S ribosomal subunit and the subsequent translation inhibition might be counterbalanced by the downregulation of EIF2AK3 and DNAJC3. The genes PARP1, MPG, EME1, XPAC, RIF1 and CHAF1B are mainly related to single-strand DNA modifications and showed an increased expression in the group with 5 mg DON/kg feed. The results indicate that significantly altered gene expression was already occurring at 2.5 mg DON/kg feed.

Nucleotide excision repair and the degradation of RNA pol II by the Caenorhabditis elegans XPA and Rsp5 orthologues, RAD-3 and WWP-1

The Caenorhabditis elegans rad-3 gene was identified in a genetic screen for radiation sensitive (rad) mutants. Here, we report that the UV sensitivity of rad-3 mutants is caused by a nonsense mutation in the C. elegans orthologue of the human nucleotide excision repair gene XPA. We have used the xpa-1/rad-3 mutant to examine how a defect in nucleotide excision repair (NER) perturbs development. We find that C. elegans carrying a mutation in xpa-1/rad-3 are hypersensitive and hypermutable in response to UV irradiation, but do not display hypersensitivity to oxidative stress or show obvious developmental abnormalities in the absence of UV exposure. Consistent with these observations, non-irradiated xpa-1 mutants have a similar lifespan as wild type. We further show that UV irradiated xpa-1 mutants undergo a stage-dependent decline in growth and survival, which is associated with a loss in transcriptional competence. Surprisingly, transcriptionally quiescent dauer stage larvae are able to survive a dose of UV irradiation, which is otherwise lethal to early stage larvae. We show that the loss of transcriptional competence in UV irradiated xpa-1 mutants is associated with the degradation of the large RNA polymerase II (RNA pol II) subunit, AMA-1, and have identified WWP-1 as the putative E3 ubiquitin ligase mediating this process. The absence of wwp-1 by itself does not cause sensitivity to UV irradiation, but it acts synergistically with a mutation in xpa-1 to enhance UV hypersensitivity.

DNA helicases, genomic instability, and human genetic disease

DNA helicases are a highly conserved group of enzymes that unwind DNA. They function in all processes in which access to single-stranded DNA is required, including DNA replication, DNA repair and recombination, and transcription of RNA. Defects in helicases functioning in one or more of these processes can result in characteristic human genetic disorders in which genomic instability and predisposition to cancer are common features. So far, different helicase genes have been found mutated in six such disorders. Mutations in XPB and XPD can result in xeroderma pigmentosum, Cockayne syndrome, or trichothiodystrophy. Mutations in the RecQ-like genes BLM, WRN, and RECQL4 can result in Bloom syndrome, Werner syndrome, and Rothmund-Thomson syndrome, respectively. Because XPB and XPD function in both nucleotide excision repair and transcription initiation, the cellular phenotypes associated with a deficiency of each one of them include failure to repair mutagenic DNA lesions and defects in the recovery of RNA transcription after UV irradiation. The functions of the RecQ-like genes are unknown; however, a growing body of evidence points to a function in restarting DNA replication after the replication fork has become stalled. The genomic instability associated with mutations in the RecQ-like genes includes spontaneous chromosome instability and elevated mutation rates. Mouse models for nearly all of these entities have been developed, and these should help explain the widely different clinical features that are associated with helicase mutations.

Human XPA and XRCC1 DNA repair proteins expressed in yeast, Saccharomyces cerevisiae

Human XPA and XRCC1 DNA repair proteins have been expressed in a series of novel yeast episomal vectors. Expression of XPA cDNA resulted in synthesis of anti-XPA crossreacting polypeptides of 40 and 42 kDa, the status of the native protein found in human cells. Likewise, the majority of the recombinant XRCC1 found in the yeast intracellular fraction corresponded to the molecular mass of the full-length human protein. Recombinant XPA protein expressed as an NH(2)-terminal polyhistidine fusion could be affinity purified using Ni(2+) agarose.

Partial functional correction of xeroderma pigmentosum group A cells by suppressor tRNA

Genetic diseases are often caused by nonsense mutations. The resulting defect in protein translation can be restored by expressing suppressor tRNA in the mutant cells. Our goal was to demonstrate both protein restoration and phenotypic correction using these small transgenes. Functional activity of an arginine opal suppressor tRNA in cells expressing a nonsense mutated GFP gene was demonstrated by restored fluorescence. This suppressor tRNA was expressed in xeroderma pigmentosum group A cells, containing a homozygous nonsense mutation at Arg-207 in the XPA complementing gene. The transfected XPA cell population showed a twofold increase in cell survival after UV irradiation as determined by colony-forming assays compared with cell populations without the suppressor tRNA gene. The UV doses required for 37% survival of XP cells and XP cells expressing the suppressor tRNA were 0.6 and 1.2 J/m2. A similar twofold increase in the reactivation of UV-irradiated plasmid DNA was observed in XP cells expressing the suppressor tRNA. However, there was no detectable increase in XPA protein levels. Several potential limitations of this approach exist, including the availability of mutant RNA transcripts, the efficiency of suppression by the suppressor tRNA, and the abundance and availability and continued expression of the suppressor tRNA. The unique feature of this study is the relatively small size (88 bp) of the suppressor tRNA. Small-sized suppressor tRNAs can be synthetically constructed and subcloned into different viral vectors for delivery into the target cells. This approach may be useful for other genetic diseases caused by nonsense mutations.

DNA repair defects and other (mus)takes in Drosophila melanogaster

Preservation of the structural integrity of DNA in any organism is crucial to its health and survival. Such preservation is achieved by an extraordinary cellular arsenal of damage surveillance and repair functions, many of which are now being defined at the gene and protein levels. Mutants hypersensitive to the killing effects of DNA-damaging agents have been instrumental in helping to identify DNA repair-related genes and to elucidate repair mechanisms. In Drosophila melanogaster, such strains are generally referred to as mutagen-sensitive (mus) mutants and currently define more than 30 genetic loci. Whereas most mus mutants have been recovered on the basis of hypersensitivity to the monofunctional alkylating agent methyl methanesulfonate, they nevertheless constitute a phenotypically diverse group, with many mutants having effects beyond mutagen sensitivity. These phenotypes include meiotic dysfunctions, somatic chromosome instabilities, chromatin abnormalities, and cell proliferation defects. Within the last few years numerous mus and other DNA repair-related genes of Drosophila have been molecularly cloned, providing new insights into the functions of these genes. This article outlines strategies for isolating mus mutations and reviews recent advances in the Drosophila DNA repair field, emphasizing mutant analysis and gene cloning.

The Drosophila melanogaster homologue of the Xeroderma pigmentosum D gene product is located in euchromatic regions and has a dynamic response to UV light-induced lesions in polytene chromosomes

The XPD/ERCC2/Rad3 gene is required for excision repair of UV-damaged DNA and is an important component of nucleotide excision repair. Mutations in the XPD gene generate the cancer-prone syndrome, xeroderma pigmentosum, Cockayne's syndrome, and trichothiodystrophy. XPD has a 5'- to 3'-helicase activity and is a component of the TFIIH transcription factor, which is essential for RNA polymerase II elongation. We present here the characterization of the Drosophila melanogaster XPD gene (DmXPD). DmXPD encodes a product that is highly related to its human homologue. The DmXPD protein is ubiquitous during development. In embryos at the syncytial blastoderm stage, DmXPD is cytoplasmic. At the onset of transcription in somatic cells and during gastrulation in germ cells, DmXPD moves to the nuclei. Distribution analysis in polytene chromosomes shows that DmXPD is highly concentrated in the interbands, especially in the highly transcribed regions known as puffs. UV-light irradiation of third-instar larvae induces an increase in the signal intensity and in the number of sites where the DmXPD protein is located in polytene chromosomes, indicating that the DmXPD protein is recruited intensively in the chromosomes as a response to DNA damage. This is the first time that the response to DNA damage by UV-light irradiation can be visualized directly on the chromosomes using one of the TFIIH components.

Initiation and bidirectional propagation of chromatin assembly from a target site for nucleotide excision repair

To restore full genomic integrity in a eukaryotic cell, DNA repair processes have to be coordinated with the resetting of nucleosomal organization. We have established a cell-free system using Drosophila embryo extracts to investigate the mechanism linking de novo nucleosome formation to nucleotide excision repair (NER). Closed-circular DNA containing a uniquely placed cisplatin-DNA adduct was used to follow chromatin assembly specifically from a site of NER. Nucleosome formation was initiated from a target site for NER. The assembly of nucleosomes propagated bidirectionally, creating a regular nucleosomal array extending beyond the initiation site. Furthermore, this chromatin assembly was still effective when the repair synthesis step in the NER process was inhibited.

The molecular basis of xeroderma pigmentosum

BACKGROUND

Xeroderma pigmentosum is an extremely rare, autosomal recessive disease characterized by a more than 1000-fold increase in nonmelanoma skin cancer. Individuals with this disease can be divided into eight complementation groups: A-G and V for variant. Each one represents a different genetic defect in DNA repair.

OBJECTIVE

To review the molecular basis of xeroderma pigmentosum.

RESULTS

Deficiencies in various gene products in the nucleotide excision repair pathway cause xeroderma pigmentosum in complementation groups A-G. The molecular basis of the variant group remains to be elucidated.

CONCLUSIONS

Research into the genetic defects underlying xeroderma pigmentosum have led to an increased understanding of nucleotide excision repair.