Neither enhanced removal of cyclobutane pyrimidine dimers nor strand-specific repair is found after transcription induction of the beta 3-tubulin gene in a Drosophila embryonic cell line Kc

CSB-independent, XPC-dependent transcription-coupled repair in Drosophila

Drosophila melanogaster has been extensively used as a model system to study ionizing radiation and chemical-induced mutagenesis, double-strand break repair, and recombination. However, there are only limited studies on nucleotide excision repair in this important model organism. An early study reported that Drosophila lacks the transcription-coupled repair (TCR) form of nucleotide excision repair. This conclusion was seemingly supported by the Drosophila genome sequencing project, which revealed that Drosophila lacks a homolog to CSB, which is known to be required for TCR in mammals and yeasts. However, by using excision repair sequencing (XR-seq) genome-wide repair mapping technology, we recently found that the Drosophila S2 cell line performs TCR comparable to human cells. Here, we have extended this work to Drosophila at all its developmental stages. We find TCR takes place throughout the life cycle of the organism. Moreover, we find that in contrast to humans and other multicellular organisms previously studied, the XPC repair factor is required for both global and transcription-coupled repair in Drosophila.

DNA Repair Repertoire of the Enigmatic Hydra

Since its discovery by Abraham Trembley in 1744, hydra has been a popular research organism. Features like spectacular regeneration capacity, peculiar tissue dynamics, continuous pattern formation, unique evolutionary position, and an apparent lack of organismal senescence make hydra an intriguing animal to study. While a large body of work has taken place, particularly in the domain of evolutionary developmental biology of hydra, in recent years, the focus has shifted to molecular mechanisms underlying various phenomena. DNA repair is a fundamental cellular process that helps to maintain integrity of the genome through multiple repair pathways found across taxa, from archaea to higher animals. DNA repair capacity and senescence are known to be closely associated, with mutations in several repair pathways leading to premature ageing phenotypes. Analysis of DNA repair in an animal like hydra could offer clues into several aspects including hydra’s purported lack of organismal ageing, evolution of DNA repair systems in metazoa, and alternative functions of repair proteins. We review here the different DNA repair mechanisms known so far in hydra. Hydra genes from various DNA repair pathways show very high similarity with their vertebrate orthologues, indicating conservation at the level of sequence, structure, and function. Notably, most hydra repair genes are more similar to deuterostome counterparts than to common model invertebrates, hinting at ancient evolutionary origins of repair pathways and further highlighting the relevance of organisms like hydra as model systems. It appears that hydra has the full repertoire of DNA repair pathways, which are employed in stress as well as normal physiological conditions and may have a link with its observed lack of senescence. The close correspondence of hydra repair genes with higher vertebrates further demonstrates the need for deeper studies of various repair components, their interconnections, and functions in this early metazoan.

Drosophila, which lacks canonical transcription-coupled repair proteins, performs transcription-coupled repair

Previous work with the classic T4 endonuclease V digestion of DNA from irradiated Drosophila cells followed by Southern hybridization led to the conclusion that Drosophila lacks transcription-coupled repair (TCR). This conclusion was reinforced by the Drosophila Genome Project, which revealed that Drosophila lacks Cockayne syndrome WD repeat protein (CSA), CSB, or UV-stimulated scaffold protein A (UVSSA) homologs, whose orthologs are present in eukaryotes ranging from Arabidopsis to humans that carry out TCR. A recently developed in vivo excision assay and the excision repair-sequencing (XR-Seq) method have enabled genome-wide analysis of nucleotide excision repair in various organisms at single-nucleotide resolution and in a strand-specific manner. Using these methods, we have discovered that Drosophila S2 cells carry out robust TCR comparable with that observed in mammalian cells. Our findings provide critical new insights into the mechanisms of TCR among various different species.

Diseases Associated with Mutation of Replication and Repair Proteins

Alterations in proteins that function in DNA replication and repair have been implicated in the development of human diseases including cancer, premature ageing, skeletal disorders, mental retardation, microcephaly, and neurodegeneration. Drosophila has orthologues of most human replication and repair proteins and high conservation of the relevant cellular pathways, thus providing a versatile system in which to study how these pathways are corrupted leading to the diseased state. In this chapter I will briefly review the diseases associated with defects in replication and repair proteins and discuss how past and future studies on the Drosophila orthologues of such proteins can contribute to the dissection of the mechanisms involved in disease development.

Transcription-coupled nucleotide excision repair in mammalian cells: molecular mechanisms and biological effects

The encounter of elongating RNA polymerase II (RNAPIIo) with DNA lesions has severe consequences for the cell as this event provides a strong signal for P53-dependent apoptosis and cell cycle arrest. To counteract prolonged blockage of transcription, the cell removes the RNAPIIo-blocking DNA lesions by transcription-coupled repair (TC-NER), a specialized subpathway of nucleotide excision repair (NER). Exposure of mice to UVB light or chemicals has elucidated that TC-NER is a critical survival pathway protecting against acute toxic and long-term effects (cancer) of genotoxic exposure. Deficiency in TC-NER is associated with mutations in the CSA and CSB genes giving rise to the rare human disorder Cockayne syndrome (CS). Recent data suggest that CSA and CSB play differential roles in mammalian TC-NER: CSB as a repair coupling factor to attract NER proteins, chromatin remodellers and the CSA- E3-ubiquitin ligase complex to the stalled RNAPIIo. CSA is dispensable for attraction of NER proteins, yet in cooperation with CSB is required to recruit XAB2, the nucleosomal binding protein HMGN1 and TFIIS. The emerging picture of TC-NER is complex: repair of transcription-blocking lesions occurs without displacement of the DNA damage-stalled RNAPIIo, and requires at least two essential assembly factors (CSA and CSB), the core NER factors (except for XPC-RAD23B), and TC-NER specific factors. These and yet unidentified proteins will accomplish not only efficient repair of transcription-blocking lesions, but are also likely to contribute to DNA damage signalling events.

Codon Signature Extremes In Eukaryote genomes

Twenty-one complete eukaryotic genomes are compared for codon signature biases. The codon signature refers to the dinucleotide relative abundance values at codon sites {1, 2}, {2, 3}, and {3, 4} (4 = 1 of the next codon site). The genomes under study include human, mouse, chicken, three invertebrates, one plant species, eight fungi, and six protists. The dinucleotide CpG is significantly underrepresented at all contiguous codon sites and drastically suppressed in noncoding regions in mammalian species, in yeast-like genomes, in the dicotArabidopsis thaliana, but not in the filamentous fungiNeurospora crassaandAsperigillus fumigatus, and in the protistEntamoeba histolytica.The dinucleotide TpA, probably due to DNA structural weaknesses, is underrepresented genome-wide and significantly underrepresented in the codon signature for all contiguous codon sites in mammals, inverterbrates, plants, and fungi, but somewhat restricted to codon sites {1, 2} among protists helping in avoidance of stop codons. The amino acid Ser, not of abundance in bacterial genomes, generally ranks among the two most used amino acids among eukaryotes ostensibly resulting from greater activity in the nucleus. The observed differences are linked to specifics of methylation, context-dependent mutation, DNA repair, and replication. For example, the amino acid Leu is broadly abundant in all life domains generally resulting from extra occurrences of the codon TTR, R purine. The malarial protistPlasmodium falciparumshows many codon signature extremes.

Genomic heterogeneity of background substitutional patterns in Drosophila melanogaster

Mutation is the underlying force that provides the variation upon which evolutionary forces can act. It is important to understand how mutation rates vary within genomes and how the probabilities of fixation of new mutations vary as well. If substitutional processes across the genome are heterogeneous, then examining patterns of coding sequence evolution without taking these underlying variations into account may be misleading. Here we present the first rigorous test of substitution rate heterogeneity in the Drosophila melanogaster genome using almost 1500 nonfunctional fragments of the transposable element DNAREP1_DM. Not only do our analyses suggest that substitutional patterns in heterochromatic and euchromatic sequences are different, but also they provide support in favor of a recombination-associated substitutional bias toward G and C in this species. The magnitude of this bias is entirely sufficient to explain recombination-associated patterns of codon usage on the autosomes of the D. melanogaster genome. We also document a bias toward lower GC content in the pattern of small insertions and deletions (indels). In addition, the GC content of noncoding DNA in Drosophila is higher than would be predicted on the basis of the pattern of nucleotide substitutions and small indels. However, we argue that the fast turnover of noncoding sequences in Drosophila makes it difficult to assess the importance of the GC biases in nucleotide substitutions and small indels in shaping the base composition of noncoding sequences.

Patterns of Polymorphism and Divergence from Noncoding Sequences of Drosophila melanogaster and D. simulans: Evidence for Nonequilibrium Processes

Despite the fact that D. melanogaster and D. simulans have been the central model system for molecular population genetics, few data are available for noncoding regions. Here, we present an analysis of population genetic data from intergenic regions and comparisons of these data to previously collected data from introns and exons. Polymorphisms and fixations were categorized as A/T to G/C or G/C to A/T changes and were polarized by inferring the ancestral state using both parsimony and maximum likelihood. Noncoding fixations in both D. melanogaster and D. simulans were consistent with equilibrium base-composition evolution. However, polarized noncoding polymorphisms, revealed a different pattern. Although A/T to G/C and G/C to A/T polymorphisms in D. simulans were consistent with equilibrium, we observed a highly significant dearth of A/T to G/C polymorphisms in D. melanogaster introns but not in intergenic sequences. Such data could be explained by recent evolution of mutational biases associated with transcription or by lineage-specific selection on base composition. These data reveal the complexity of evolutionary processes acting even on noncoding DNA in Drosophila.

Effect of nucleotide excision repair on ENU-induced mutation in female germ cells of Drosophila melanogaster

The role of nucleotide excision repair (NER) in the repair of alkylation damage in the germ cells of higher eukaryotes has been studied mainly by treating postmeiotic male germ cells. Little is known about repair in actively repairing female germ cells. In this study, we treated NER-deficient (ner(-)) mus201(D1) Drosophila females with N-ethyl-N-nitrosourea (ENU) and determined both the mutant frequencies in the multiple locus recessive lethal (RL) test and in the single locus vermilion gene and determined the ENU mutation spectrum in the vermilion gene. The results show that ENU is mutagenic in all cell stages and that the induced frequencies increase with cell maturation, from oogonia to mature oocytes. In addition, the induced spectrum consists mainly of A:T-->T:A transversions (43.8%), A:T-->G:C transitions (21.9%), and A:T-->C:G transversions (15.6%). G:C-->A:T (3.1%) transitions, other transversions (9.4%), frameshifts (3.1%), and deletions (3.1%) were also found. Comparison of these results with those previously obtained for repair-proficient (ner(+)) female germ cells reveal: 1) Differences in the RL and vermilion mutation frequencies for ner(+) and ner(-) germ cells, indicating that NER is involved in the repair of ENU-induced damage to these cells. 2) At least 15.6% of mutations in ner(-) cells may be the consequence of N-ethylation damage and mutations of this type were not detected in ner(+) cells. 3) Although differences were found in transition frequencies between ENU-treated ner(+) and ner(-) germ cells (52.2% vs. 25%), suggesting that a functional NER is involved in processing O-ethylated damage, the role of NER in repairing O-ethylated adducts is uncertain.

How intron splicing affects the deletion and insertion profile in Drosophila melanogaster

Studies of "dead-on-arrival" transposable elements in Drosophila melanogaster found that deletions outnumber insertions approximately 8:1 with a median size for deletions of approximately 10 bp. These results are consistent with the deletion and insertion profiles found in most other Drosophila pseudogenes. In contrast, a recent study of D. melanogaster introns found a deletion/insertion ratio of 1.35:1, with 84% of deletions being shorter than 10 bp. This discrepancy could be explained if deletions, especially long deletions, are more frequently strongly deleterious than insertions and are eliminated disproportionately from intron sequences. To test this possibility, we use analysis and simulations to examine how deletions and insertions of different lengths affect different components of splicing and determine the distribution of deletions and insertions that preserve the original exons. We find that, consistent with our predictions, longer deletions affect splicing at a much higher rate compared to insertions and short deletions. We also explore other potential constraints in introns and show that most of these also disproportionately affect large deletions. Altogether we demonstrate that constraints in introns may explain much of the difference in the pattern of deletions and insertions observed in Drosophila introns and pseudogenes.

Amino acid runs in eukaryotic proteomes and disease associations

We present a comparative proteome analysis of the five complete eukaryotic genomes (human, Drosophila melanogaster, Caenorhabditis elegans, Saccharomyces cerevisiae, Arabidopsis thaliana), focusing on individual and multiple amino acid runs, charge and hydrophobic runs. We found that human proteins with multiple long runs are often associated with diseases; these include long glutamine runs that induce neurological disorders, various cancers, categories of leukemias (mostly involving chromosomal translocations), and an abundance of Ca(2 +) and K(+) channel proteins. Many human proteins with multiple runs function in development and/or transcription regulation and are Drosophila homeotic homologs. A large number of these proteins are expressed in the nervous system. More than 80% of Drosophila proteins with multiple runs seem to function in transcription regulation. The most frequent amino acid runs in Drosophila sequences occur for glutamine, alanine, and serine, whereas human sequences highlight glutamate, proline, and leucine. The most frequent runs in yeast are of serine, glutamine, and acidic residues. Compared with the other eukaryotic proteomes, amino acid runs are significantly more abundant in the fly. This finding might be interpreted in terms of innate differences in DNA-replication processes, repair mechanisms, DNA-modification systems, and mutational biases. There are striking differences in amino acid runs for glutamine, asparagine, and leucine among the five proteomes.

O-ethylthymidine adducts are the most relevant damages for mutation induced by N-ethyl-N-nitrosourea in female germ cells of Drosophila melanogaster

Responses to genotoxic agents vary not only among organisms, test systems, and cellular stages, but also between sexes; little, however, is known about the mutagenic consequences of chemical exposures to female germ cells. In this study, the mutagenicity of N-ethyl-N-nitrosourea (ENU) was analyzed in female germ cells of Drosophila melanogaster using the recessive-lethal test and the vermilion system, which simultaneously generates information on induced mutation frequency and mutation spectrum. ENU was mutagenic in all stages of oogenesis, although there were differences among the stages. In mature and immature oocytes, ENU-induced mutations in the vermilion locus were 43.5% A:T-->G:C transitions, 39.1% A:T-->T:A transversions, 8.7% G:C-->A:T transitions, and 8.7% A:T-->C:G transversions, indicating that the most important premutagenic lesions induced by this chemical are O(4)-ethylthymine and O(2)-ethylthymine. The low frequency of mutation involving O(6)-ethylguanine (i.e., G:C-->A:T transitions) could be a consequence of the repair of these lesions by O(6)-methylguanine DNA methyltransferase. Comparison of these results with those previously obtained in male germ cells stresses the importance of the repair activity of the analyzed cells, because the mutation spectrum in female germ cells was similar to the spectrum obtained with repair-proficient spermatogonial cells and different from repair-deficient postmeiotic cells. The results also indicate that studies with female germ cells could be an alternative to the use of premeiotic male germ cells, especially when the analysis of these cells is difficult or almost impossible and when studies of in vivo DNA repair in premeiotic germ cells are performed.

A chimeric prokaryotic ancestry of mitochondria and primitive eukaryotes

We provide data and analysis to support the hypothesis that the ancestor of animal mitochondria (Mt) and many primitive amitochondrial (a-Mt) eukaryotes was a fusion microbe composed of a Clostridium-like eubacterium and a Sulfolobus-like archaebacterium. The analysis is based on several observations: (i) The genome signatures (dinucleotide relative abundance values) of Clostridium and Sulfolobus are compatible (sufficiently similar) and each has significantly more similarity in genome signatures with animal Mt sequences than do all other available prokaryotes. That stable fusions may require compatibility in genome signatures is suggested by the compatibility of plasmids and hosts. (ii) The expanded energy metabolism of the fusion organism was strongly selective for cementing such a fusion. (iii) The molecular apparatus of endospore formation in Clostridium serves as raw material for the development of the nucleus and cytoplasm of the eukaryotic cell.

Drosophila ribosomal protein PO contains apurinic/apyrimidinic endonuclease activity

Drosophila ribosomal protein PO was overexpressed in Escherichia coli to allow for its purification, biochemical characterization and to generate polyclonal antibodies for Western analysis. Biochemical tests were originally performed to see if overexpressed PO contained DNase activity similar to that recently reported for the apurinic/apyrimidinic (AP) lyase activity associated with Drosophila ribosomal protein S3. The overexpressed ribosomal protein was subsequently found to act on AP DNA, producing scissions that were in this case 5' of a baseless site instead of 3', as has been observed for S3. As a means of confirming that the source of AP endonuclease activity was in fact due to PO, glutathione S-transferase (GST) fusions containing a Factor Xa cleavage site between GST and PO were constructed, overexpressed in an E.coli strain defective for the major 5'-acting AP endonucleases and the fusions purified using glutathione-agarose affinity column chromatography. Isolated fractions containing purified GST-PO fusion proteins were subsequently found to have authentic AP endonuclease activity. Moreover, glutathione-agarose was able to deplete AP endonuclease activity from GST-PO fusion protein preparations, whereas the resin was ineffective in lowering DNA repair activity for PO that had been liberated from the fusion construct by Factor Xa cleavage. These results suggested that PO was a multifunctional protein with possible roles in DNA repair beyond its known participation in protein translation. In support of this notion, tests were performed that show that GST-PO, but not GST, was able to rescue an E.coli mutant lacking the major 5'-acting AP endonucleases from sensitivity to an alkylating agent. We furthermore show that GST-PO can be located in both the nucleus and ribosomes. Its nuclear location can be further traced to the nuclear matrix, thus placing PO in a subcellular location where it could act as a DNA repair protein. Other roles beyond DNA repair seem possible, however, since GST-PO also exhibited significant nuclease activity for both single- and double-stranded DNA.

Rad23 is required for transcription-coupled repair and efficient overrall repair in Saccharomyces cerevisiae

The repair of UV-induced photoproducts (cyclobutane pyrimidine dimers) in a well-characterized minichromosome, genomic DNA, and a transcribed genomic gene (RPB2) of a rad23delta mutant of Saccharomyces care was examined. Isogenic wild-type cells show a strong bias for the repair of the transcribed strands in both the plasmid and genomic genes and efficient overall repair of both DNAs (>80% of the dimers were removed in 6 h). However, the rad23delta mutant shows (i) no strand bias for repair in these genes and decreased repair of both strands, (ii) partial repair of genomic DNA (approximately 45% in 6 h), and (iii) very poor repair of the plasmid overall approximately 15% in 6 h). These features, coupled with the decreased UV survival of rad23delta cells, indicate that Rad23 is required for both transcription-coupled repair and efficient overall repair in S. cerevisiae.

Hormones and the cytoskeleton of animals and plants

It is often overlooked that a cell can exert its specific functions only after it has acquired a specific morphology: function follows form. The cytoskeleton plays an important role in establishing this form, and a variety of hormones can influence it. The cytoskeletal framework has also been shown to function in a variety of cellular processes, such as cell motility (important for behavior), migration (important for the interrelationship between the endocrine and immune systems, e.g., chemotaxis), intracellular transport of particles, mitosis and meiosis, maintenance of cellular morphology, spatial distribution of cell organelles (e.g., nucleus and Golgi system), cellular responses to membrane events (e.g., endocytosis and exocytosis), intracellular communication including conductance of electrical signals, localization of mRNA, protein synthesis, and--more specifically in plants--ordered cell wall deposition, cytoplasmic streaming, and spindle function followed by phragmoplast function. All classes of hormones seem to make use of the cytoskeleton, either during their synthesis, transport, secretion, degradation, or when influencing their target cells. In this review special attention is paid to cytoskeleton-mediated effects of selected hormones related to growth, transepithelial transport, steroidogenesis, thyroid and parathyroid functioning, motility, oocyte maturation, and cell elongation in plants.

Variations in transcription-repair coupling in mouse cells

Formation and repair of UV-induced cyclobutane pyrimidine dimers (CPDs) was examined in three different genes in mouse L cells: 1) a stably integrated insert (called LTL), consisting of a herpes simplex virus thymidine kinase gene (tk) fused to a hormone inducible promotor (LTR); 2) the constitutively expressed proto-oncogene c-abl; and 3) the inactive immunoglobulin J chain gene. Transcription of the tk gene is induced > 50-fold by dexamethasone. There is a nonuniform distribution of CPDs in LTL DNA irradiated in vitro, being 4-fold higher in the LTR than in the tk gene, indicating the LTR may be damaged preferentially in irradiated cells. Repair of CPDs occurs efficiently in both strands of LTL and is unaffected by hormone induction of tk gene transcription. Transcription of tk mRNA is very sensitive to UV damage and follows single hit kinetics with UV dose. Furthermore, tk mRNA expression rapidly recovers during repair incubation. Transcription-coupled repair occurs in these cells, however, since only the transcribed strand of c-abl is efficiently repaired of CPDs; the non-transcribed strand as well as both strands of the J chain gene are inefficiently repaired. Thus, repair in the LTL construct may reflect a lack of transcription-coupled repair in either the LTR promotor or the LTL insertion region of chromatin.

Mechanisms of transcription-repair coupling and mutation frequency decline

Mutation frequency decline is the rapid and irreversible decline in the suppressor mutation frequency of Escherichia coli cells if the cells are kept in nongrowth media immediately following the mutagenic treatment. The gene mfd, which is necessary for mutation frequency decline, encodes a protein of 130 kDa which couples transcription to excision repair by binding to RNA polymerase and to UvrA, which is the damage recognition subunit of the excision repair enzyme. Although current evidence suggests that transcription-repair coupling is the cause of the preferential repair of the transcribed strand of mRNA encoding genes as well as of suppressor tRNA genes, the decline occurs under stringent response conditions in which the tRNA genes are not efficiently transcribed. Thus, the mechanism of strand-specific repair is well understood, but some questions remain regarding the precise mechanism of mutation frequency decline.

Fine tuning of DNA repair in transcribed genes: mechanisms, prevalence and consequences

Cells fine-tune their DNA repair, selecting some regions of the genome in preference to others. In the paradigm case, excision of UV-induced pyrimidine dimers in mammalian cells, repair is concentrated in transcribed genes, especially in the transcribed strand. This is due both to chromatin structure being looser in transcribing domains, allowing more rapid repair, and to repair enzymes being coupled to RNA polymerases stalled at damage sites; possibly other factors are also involved. Some repair-defective diseases may involve repair-transcription coupling: three candidate genes have been suggested. However, preferential excision of pyrimidine dimers is not uniformly linked to transcription. In mammals it varies with species, and with cell differentiation. In Drosophila embryo cells it is absent, and in yeast, the determining factor is nucleosome stability rather than transcription. Repair of other damage departs further from the paradigm, even in some UV-mimetic lesions. No selectivity is known for repair of the very frequent minor forms of base damage. And the most interesting consequence of selective repair, selective mutagenesis, normally occurs for UV-induced, but not for spontaneous mutations. The temptation to extrapolate from mammalian UV repair should be resisted.