A Genetic Pathway Conferring Life Extension and Resistance to Uv Stress in Caenorhabditis Elegans

A variety of mechanisms have been proposed to explain the extension of adult life span (Age) seen in several mutants in Caenorhabditis elegans (age-1: an altered aging rate; daf-2 and daf-23: activation of a dauer-specific longevity program; spe-26: reduced fertility; clk-1: an altered biological clock). Using an assay for ultraviolet (UV) resistance in young adult hermaphrodites (survival after UV irradiation), we observed that all these Age mutants show increased resistance to UV. Moreover, mutations in daf-16 suppressed the UV resistance as well as the increased longevity of all the Age mutants. In contrast to the multiple mechanisms initially proposed, these results suggest that a single, daf-16-dependent pathway, specifies both extended life span and increased UV resistance. The mutations in daf-16 did not alter the reduced fertility of spe-26 and interestingly a daf-16 mutant is more fertile than wild type. We propose that life span and some aspects of stress resistance are jointly negatively regulated by a set of gerontogenes (genes whose alteration causes life extension) in C. elegans.     

Macrorestriction Analysis of Caenorhabditis Elegans Genomic DNA

The usefulness of genomic physical maps is greatly enhanced by linkage of the physical map with the genetic map. We describe a ``macrorestriction mapping' procedure for Caenorhabditis elegans that we have applied to this endeavor. High molecular weight, genomic DNA is digested with infrequently cutting restriction enzymes and size-fractionated by pulsed field gel electrophoresis. Southern blots of the gels are probed with clones from the C. elegans physical map. This procedure allows the construction of restriction maps covering several hundred kilobases and the detection of polymorphic restriction fragments using probes that map several hundred kilobases away. We describe several applications of this technique. (1) We determined that the amount of DNA in a previously uncloned region is <220 kb. (2) We mapped the mes-1 gene to a cosmid, by detecting polymorphic restriction fragments associated with a deletion allele of the gene. The 25-kb deletion was initially detected using as a probe sequences located ~400 kb away from the gene. (3) We mapped the molecular endpoint of the deficiency hDf6, and determined that three spontaneously derived duplications in the unc-38-dpy-5 region have very complex molecular structures, containing internal rearrangements and deletions.     

Low-Dose Formaldehyde Delays DNA Damage Recognition and DNA Excision Repair in Human Cells

Objective

Formaldehyde is still widely employed as a universal crosslinking agent, preservative and disinfectant, despite its proven carcinogenicity in occupationally exposed workers. Therefore, it is of paramount importance to understand the possible impact of low-dose formaldehyde exposures in the general population. Due to the concomitant occurrence of multiple indoor and outdoor toxicants, we tested how formaldehyde, at micromolar concentrations, interferes with general DNA damage recognition and excision processes that remove some of the most frequently inflicted DNA lesions.

Methodology/Principal Findings

The overall mobility of the DNA damage sensors UV-DDB (ultraviolet-damaged DNA-binding) and XPC (xeroderma pigmentosum group C) was analyzed by assessing real-time protein dynamics in the nucleus of cultured human cells exposed to non-cytotoxic (<100 μM) formaldehyde concentrations. The DNA lesion-specific recruitment of these damage sensors was tested by monitoring their accumulation at local irradiation spots. DNA repair activity was determined in host-cell reactivation assays and, more directly, by measuring the excision of DNA lesions from chromosomes. Taken together, these assays demonstrated that formaldehyde obstructs the rapid nuclear trafficking of DNA damage sensors and, consequently, slows down their relocation to DNA damage sites thus delaying the excision repair of target lesions. A concentration-dependent effect relationship established a threshold concentration of as low as 25 micromolar for the inhibition of DNA excision repair.

Conclusions/Significance

A main implication of the retarded repair activity is that low-dose formaldehyde may exert an adjuvant role in carcinogenesis by impeding the excision of multiple mutagenic base lesions. In view of this generally disruptive effect on DNA repair, we propose that formaldehyde exposures in the general population should be further decreased to help reducing cancer risks.     

Bacteriophage T4 Gene 32 Participates in Excision Repair as Well as Recombinational Repair of Uv Damages

Gene 32 of phage T4 has been shown previously to be involved in recombinational repair of UV damages but, based on a mutant study, was thought not to be required for excision repair. However, a comparison of UV-inactivation curves of several gene 32 mutants grown under conditions permissive for progeny production in wild-type or polA- hosts demonstrates that gene 32 participates in both kinds of repair. Different gene 32 mutations differentially inactivate these repair functions. Under conditions permissive for DNA replication and progeny production, all gene 32 mutants investigated here are partially defective in recombinational repair, whereas only two of them, P7 and P401, are also defective in excision repair. P401 is the only mutant whose final slope of the inactivation curve is significantly steeper than that of wild-type T4. These results are discussed in terms of interactions of gp32, a single-stranded DNA-binding protein, with DNA and with other proteins.     

Evidence for Base Excision Repair of Oxidative DNA Damage in Chloroplasts of Arabidopsis thaliana

Chloroplasts are the sites of photosynthesis in plants, and they contain their own multicopy, requisite genome. Chloroplasts are also major sites for production of reactive oxygen species, which can damage essential components of the chloroplast, including the chloroplast genome. Compared with mitochondria in animals, relatively little is known about the potential to repair oxidative DNA damage in chloroplasts. Here we provide evidence of DNA glycosylase-lyase/endonuclease activity involved in base excision repair of oxidized pyrimidines in chloroplast protein extracts of Arabidopsis thaliana. Three base excision repair components (two endonuclease III homologs and an apurinic/apyrimidinic endonuclease) that might account for this activity were identified by bioinformatics. Transient expression of protein-green fluorescent protein fusions showed that all three are targeted to the chloroplast and co-localized with chloroplast DNA in nucleoids. The glycosylase-lyase/endonuclease activity of one of the endonuclease III homologs, AtNTH2, which had not previously been characterized, was confirmed in vitro. T-DNA insertions in each of these genes were identified, and the physiological and biochemical phenotypes of the single, double, and triple mutants were analyzed. This mutant analysis revealed the presence of a third glycosylase activity and potentially another pathway for repair of oxidative DNA damage in chloroplasts.Reactive oxygen species (ROS)² are inevitable by-products of metabolism in all aerobic organisms (1). Plants and algae are especially prone to photo-oxidative stress because of ROS generated during oxygenic photosynthesis. Several types of ROS are generated at various sites in the photosynthetic electron transport chain in chloroplasts, and their production is enhanced by such factors as excess or varying light intensities and extremes of temperature, drought, nutrient deficiencies, and herbicides (2). These ROS can damage many chloroplast constituents, including lipids, proteins, pigments, and the multicopy genome.Plants have evolved numerous mechanisms to deal with photo-oxidative stress, including dissipation of excess light energy, synthesis of antioxidant molecules and scavenging enzymes, and targeted repair (2). DNA repair of oxidized bases, such as thymine glycol (TG) or 8-oxoguanine, can be hypothesized as an important element of chloroplast photoprotection. Although there is considerable overlap in both the types of DNA lesions caused by different insults and the targeting of different DNA repair mechanisms, base excision repair (BER) is considered to be the main repair pathway for oxidative DNA damage, at least in the nucleus and mitochondrion (3, 4).BER repairs single damaged bases (because of oxidation, deamination, alkylation, etc.) in DNA by removing them, breaking the phosphodiester backbone, excising the sugar residue at the abasic site, and filling the gap (reviewed in Refs. 5, 6). BER begins with a DNA glycosylase or glycosylase-lyase. There are many types of glycosylases in any given organism and across taxa, and they are distinguishable by their substrate specificity, whether they are monofunctional (glycosylase activity only) or bifunctional (glycosylase plus apurinic/apyrimidinic (AP) lyase activities; see below), by the phylogenetic family in which they reside, and/or by conserved structural characteristics (reviewed in Refs. 6–8). The glycosylases involved in BER of oxidative DNA damage can be roughly divided into those that target either oxidized purines or oxidized pyrimidines (4, 9). For example, TG is a common type of oxidized pyrimidine, which is removed primarily by endonuclease III (Nth), endonuclease VIII (Nei), or their homologs (10). TG is only poorly mutagenic, but it strongly blocks polymerases, inducing cell cycle arrest and potentially cell death if it is not removed.After an appropriate glycosylase cleaves the N-glycosyl bond attaching a damaged base to deoxyribose, leaving an abasic site, the sugar-phosphate backbone is nicked. Bifunctional glycosylases also have an AP lyase activity that cleaves on the 3′ side of the AP site. However, the site still requires the function of a separate AP endonuclease that cuts on the 5′ side of the AP site to remove the 3′-deoxyribose residue at the nick site (11) before repair can continue. In the case of a monofunctional glycosylase, an AP endonuclease nicks the strand on the 5′ side of the AP site. Escherichia coli has two unrelated AP endonucleases, exonuclease III (Xth) and endonuclease IV (Nfo). In humans Ape1/Ref-1 is an Xth homolog, and in yeast Apn1p is an Nfo homolog (5, 12). Following generation of the AP site and nicking of the backbone, the gap is filled by a polymerase in either a short or long patch and then sealed by a ligase.BER of oxidative DNA lesions such TG has been studied intensively in E. coli, yeast, and mammals, whereas comparatively little is known about BER in plants. For example, only two genes involved in BER of oxidized pyrimidines have been characterized previously in the model plant Arabidopsis thaliana (13, 14), and their localization within the plant cell is unknown. An Nth homolog in Arabidopsis, AtNTH1 (At2g31450), has the expected bifunctional glycosylase-lyase activity in vitro (14). The ARP gene (At2g41460) in Arabidopsis encodes an enzyme with AP endonuclease activity (13).Here we present the results of experiments conducted to address whether there is BER of oxidized pyrimidines in the Arabidopsis chloroplast. Chloroplast protein extracts were assayed for glycosylase-lyase/endonuclease activity. The chloroplast localization of ARP, AtNTH1, and AtNTH2, a second Arabidopsis homolog of Nth, was tested experimentally, and the predicted activity of AtNTH2 was confirmed in vitro. In addition, an analysis of T-DNA insertion mutants affecting each of these three BER genes was performed.     

Coupling of Human DNA Excision Repair and the DNA Damage Checkpoint in a Defined in Vitro System

DNA repair and DNA damage checkpoints work in concert to help maintain genomic integrity. In vivo data suggest that these two global responses to DNA damage are coupled. It has been proposed that the canonical 30 nucleotide single-stranded DNA gap generated by nucleotide excision repair is the signal that activates the ATR-mediated DNA damage checkpoint response and that the signal is enhanced by gap enlargement by EXO1 (exonuclease 1) 5′ to 3′ exonuclease activity. Here we have used purified core nucleotide excision repair factors (RPA, XPA, XPC, TFIIH, XPG, and XPF-ERCC1), core DNA damage checkpoint proteins (ATR-ATRIP, TopBP1, RPA), and DNA damaged by a UV-mimetic agent to analyze the basic steps of DNA damage checkpoint response in a biochemically defined system. We find that checkpoint signaling as measured by phosphorylation of target proteins by the ATR kinase requires enlargement of the excision gap generated by the excision repair system by the 5′ to 3′ exonuclease activity of EXO1. We conclude that, in addition to damaged DNA, RPA, XPA, XPC, TFIIH, XPG, XPF-ERCC1, ATR-ATRIP, TopBP1, and EXO1 constitute the minimum essential set of factors for ATR-mediated DNA damage checkpoint response.     

Nimotuzumab Enhances the Radiosensitivity of Cancer Cells In Vitro by Inhibiting Radiation-Induced DNA Damage Repair

Background

Nimotuzumab is a humanized IgG1 monoclonal antibody specifically targeting EGFR. In this study, we aimed to investigate the molecular mechanisms of nimotuzumab in its effects of enhancing cancer cell radiosensitivity.

Principal Finding

Lung cancer A549 cells and breast cancer MCF-7 cells were pretreated with or without nimotuzumab for 24 h before radiation to perform the clonogenic survival assay and to analyze the cell apoptosis by flow ctyometry. γ-H2AX foci were detected by confocal microscopy to assess the effect of nimotuzumab on radiation induced DNA repair. EGFR activation was examined and the levels of DNA damage repair related proteins in A549 cells at different time point and at varying doses exposure after nimotuzumab and radiation treatment were examined by Western blot. Pretreatment with nimotuzumab reduced clonogenic survival after radiation, inhibited radiation-induced EGFR activation and increased the radiation-induced apoptosis in both A549 cells and MCF-7 cells. The foci of γ-H2AX 24 h after radiation significantly increased in nimotuzumab pretreated cells with different doses. The phosphorylation of AKT and DNA-PKcs were remarkably inhibited in the combination group at each dose point as well as time point.

Conclusions

Our results revealed that the possible mechanism of nimotuzumab enhancing the cancer radiosensitivity is that nimotuzumab inhibited the radiation-induced activation of DNA-PKcs through blocking the PI3K/AKT pathway, which ultimately affected the DNA DSBs repair.     

Impact of Single Nucleotide Polymorphisms of Base Excision Repair Genes on DNA Damage and Efficiency of DNA Repair in Recurrent Depression Disorder

Elevated level of DNA damage was observed in patients with depression. Furthermore, single nucleotide polymorphisms (SNPs) of base excision repair (BER) genes may modulate the risk of this disease. Therefore, the aim of this study was to delineate the association between DNA damage, DNA repair, the presence of polymorphic variants of BER genes, and occurrence of depression. The study was conducted on peripheral blood mononuclear cells of 43 patients diagnosed with depression and 59 controls without mental disorders. Comet assay was used to assess endogenous (oxidative) DNA damage and efficiency of DNA damage repair (DRE). TaqMan probes were employed to genotype 12 SNPs of BER genes. Endogenous DNA damage was higher in the patients than in the controls, but none of the SNPs affected its levels. DRE was significantly higher in the controls and was modulated by BER SNPs, particularly by c.977C>G–hOGG1, c.972G>C–MUTYH, c.2285T>C–PARP1, c.580C>T–XRCC1, c.1196A>G–XRCC1, c.444T>G–APEX1, c.-468T>G–APEX1, or c.*50C>T–LIG3. Our study suggests that both oxidative stress and disorders in DNA damage repair mechanisms contribute to elevated levels of DNA lesions observed in depression. Lower DRE can be partly attributed to the presence of specific SNP variants.     

Meiotic Recombination, Noncoding DNA and Genomic Organization in Caenorhabditis Elegans

The genetic map of each Caenorhabditis elegans chromosome has a central gene cluster (less pronounced on the X chromosome) that contains most of the mutationally defined genes. Many linkage group termini also have clusters, though involving fewer loci. We examine the factors shaping the genetic map by analyzing the rate of recombination and gene density across the genome using the positions of cloned genes and random cDNA clones from the physical map. Each chromosome has a central gene-dense region (more diffuse on the X) with discrete boundaries, flanked by gene-poor regions. Only autosomes have reduced rates of recombination in these gene-dense regions. Cluster boundaries appear discrete also by recombination rate, and the boundaries defined by recombination rate and gene density mostly, but not always, coincide. Terminal clusters have greater gene densities than the adjoining arm but similar recombination rates. Thus, unlike in other species, most exchange in C. elegans occurs in gene-poor regions. The recombination rate across each cluster is constant and similar; and cluster size and gene number per chromosome are independent of the physical size of chromosomes. We propose a model of how this genome organization arose.     

秀丽线虫的蛋白质组学研究

作为模式生物,秀丽线虫(Caenorhabditis elegans)已经成功地用于许多生命过程的研究,尤其被广泛应用于现代发育生物学、行为与神经生物学、基因组学、正向和反向的遗传学研究中,近年来,秀丽线虫更成为了一个进行蛋白质组学研究的优良体系,诠释了基于基因组学和RNA干涉研究中的基因功能。许多比较蛋白质组学表达谱的建立可以更好地理解线虫在不同发育阶段、不同温度下基因的表达,在与人类神经疾病相关的疾病研究中,线虫对帕金森疾病、阿尔茨海默症、衰老与寿命、胰岛素通路都有所揭示。另外,线虫的亚蛋白质组学和翻译后修饰如糖基化和磷酸化也已经鉴定,其数据库也在不断地完善。本文介绍了秀丽线虫的蛋白质表达谱建立的历史,尤其是神经科学研究中的应用及翻译后修饰表达谱的建立等方面的研究现状,因此,结合其它分子生物学和基因工程技术,线虫蛋白质组学研究已成为提供一个新的全面的系统分析基因功能的重要工具,提示线虫是"蠕虫蛋白质组学"的一个丰富宝藏。     

DNA切除修复与转录偶联

细胞DNA受到某些环境理化因子损伤后,其中活性转录基因和DNA转录链上的损伤被优先切除修复,这种DNA选择性修复直接与基因转录过程偶联．在大肠杆菌中已分离到实现此功能的转录修复偶联因子（TRCF）,是由mdf基因编码的一种具有ATPase活性的DNA结合蛋白．在真核细胞中,发现某些DNA修复蛋白也在DNA转录中起作用,如人DNA切除修复基因ERCG－3编码产物,是转录因子TFⅡH中最大亚基p89,酵母切除修复基因RAD3就是编码因子b的最大亚基p85．     

Nucleotide Excision Repair Is a Predominant Mechanism for Processing Nitrofurazone-Induced DNA Damage in Escherichia coli

Nitrofurazone is reduced by cellular nitroreductases to form N²-deoxyguanine (N²-dG) adducts that are associated with mutagenesis and lethality. Much attention recently has been given to the role that the highly conserved polymerase IV (Pol IV) family of polymerases plays in tolerating adducts induced by nitrofurazone and other N²-dG-generating agents, yet little is known about how nitrofurazone-induced DNA damage is processed by the cell. In this study, we characterized the genetic repair pathways that contribute to survival and mutagenesis in Escherichia coli cultures grown in the presence of nitrofurazone. We find that nucleotide excision repair is a primary mechanism for processing damage induced by nitrofurazone. The contribution of translesion synthesis to survival was minor compared to that of nucleotide excision repair and depended upon Pol IV. In addition, survival also depended on both the RecF and RecBCD pathways. We also found that nitrofurazone acts as a direct inhibitor of DNA replication at higher concentrations. We show that the direct inhibition of replication by nitrofurazone occurs independently of DNA damage and is reversible once the nitrofurazone is removed. Previous studies that reported nucleotide excision repair mutants that were fully resistant to nitrofurazone used high concentrations of the drug (200 μM) and short exposure times. We demonstrate here that these conditions inhibit replication but are insufficient in duration to induce significant levels of DNA damage.Replication in the presence of DNA damage is thought to produce most of the mutagenesis, genomic rearrangements, and lethality that occur in all cells. UV-induced photoproducts, X-ray-induced strand breaks, psoralen- or cis-platin-interstrand cross-links, oxidized bases from reactive oxygen species, and base depurination are just a few of the structurally distinct challenges that the replication machinery must overcome. It seems likely that the mechanisms that process these lesions will vary depending on the nature of the impediment.While a number of the lesions described above are known to block replication, the events associated with UV-induced damage have been the most extensively characterized. UV irradiation causes the formation of cyclobutane pyrimidine dimers and 6-4 photoproducts in DNA that block the progression of the replication fork (16, 29, 30, 37). Following the arrest of replication at UV-induced damage, RecA and several RecF pathway proteins are required to process the replication fork such that the blocking lesion is removed or bypassed (2, 5, 6, 8-10). Cells lacking either RecA or any of several RecF pathway proteins are hypersensitive to UV-induced damage and fail to recover replication following disruption by the lesions (2, 6, 10). RecBCD is an exonuclease/helicase complex that is involved in repairing double-strand breaks (38). It also is required for resistance to UV-induced damage, although it is not required to process or restore disrupted replication forks, and the substrates it acts upon after UV irradiation currently remain unclear (3, 10, 19).Survival and the ability to resume DNA synthesis following UV-induced damage depend predominantly on the removal of the lesions by nucleotide excision repair (5, 7, 36). Cells deficient in nucleotide excision repair are unable to remove UV-induced DNA lesions and exhibit elevated levels of mutagenesis, strand exchanges, rearrangements, and cell lethality (16, 33, 34). In cases where replication fork processing or lesion repair is prevented, the recovery of replication and survival become entirely dependent on translesion synthesis by DNA polymerase V (Pol V) (6). However, in repair-proficient cells, the contribution of translesion synthesis to recovery and survival is minor and is detected only following UV doses that exceed the repair capacity of the cell (5, 6).Less is known about how replication recovers from other forms of DNA damage. We chose to characterize nitrofurazone, because a number of studies suggested that N²-deoxyguanine (N²-dG) adducts induced by this and other agents would be processed differently than UV-induced lesions. Nitrofurazone is a topical antibacterial agent that historically has been used for treating burns and skin grafts in patients and animals (14, 15, 32). Nitrofurazone toxicity is known to require activation by cellular nitroreductases (25, 42). However, the mechanism and targets of its antimicrobial properties have yet to be fully elucidated. In addition to its antimicrobial properties, the reduced nitrofurazone metabolites also target DNA and have been shown to induce free radical damage, strand breaks, and N²-dG adducts (26, 40, 42, 45), and they are mutagenic and carcinogenic in rodent models (1, 15, 24, 39).Whereas nucleotide excision repair is the predominant mechanism required for survival after UV-induced damage, a number of studies suggest that translesion synthesis plays a larger role in survival after nitrofurazone-induced DNA damage. dinB mutants lacking Pol IV were shown to be hypersensitive to nitrofurazone compared to cells that constitutively express the polymerase (17). Biochemically, Pol IV and a number of Pol IV homologs from other organisms have been shown to efficiently replicate over a range of N²-dG adducts in vitro (17, 35, 44). In addition, several studies have reported that uvrA mutants, which are defective in nucleotide excision repair, do not exhibit any hypersensitivity to nitrofurazone or other agents that induce similar adducts in vivo (12, 21, 27). Early studies also observed a direct correlation between nitrofurazone-induced mutations and lethality, suggesting that mutagenic lesions persist in the DNA to cause toxicity (21, 23, 27, 43). Consistent with these observations, nitrofuran-induced lesions were found to be poor substrates for nucleotide excision repair in vitro (46).Taken together, these observations suggest to us that the cellular response to nitrofurazone will be distinct from its response to UV irradiation. However, no study has examined the relative contributions that nucleotide excision repair, translesion synthesis, or recombination has in recovering from nitrofurazone-induced damage. In this study, we characterized the mechanism by which nitrofurazone inhibits DNA replication and identified the genes that contribute to the recovery, survival, and mutagenesis of Escherichia coli treated with nitrofurazone. In contrast to previous studies, we found that survival following nitrofurazone-induced damage depends predominantly on nucleotide excision repair. Similarly to UV-induced DNA damage, both the RecF and RecBC pathways contribute to survival following nitrofurazone-induced DNA damage. The contribution of translesion polymerases to survival was minor and was mediated by Pol IV. In addition, we found that nitrofurazone can act to inhibit DNA replication directly when used at higher concentrations. The direct inhibition of replication is reversible and occurs independently of DNA damage, suggesting that DNA is not the primary target of its antimicrobial properties.     

Chromosome I Duplications in Caenorhabditis Elegans

We have isolated and characterized 76 duplications of chromosome I in the genome of Caenorhabditis elegans. The region studied is the 20 map unit left half of the chromosome. Sixty-two duplications were induced with gamma radiation and 14 arose spontaneously. The latter class was apparently the result of spontaneous breaks within the parental duplication. The majority of duplications behave as if they are free. Three duplications are attached to identifiable sequences from other chromosomes. The duplication breakpoints have been mapped by complementation analysis relative to genes on chromosome I. Nineteen duplication breakpoints and seven deficiency breakpoints divide the left half of the chromosome into 24 regions. We have studied the relationship between duplication size and segregational stability. While size is an important determinant of mitotic stability, it is not the only one. We observed clear exceptions to a size-stability correlation. In addition to size, duplication stability may be influenced by specific sequences or chromosome structure. The majority of the duplications were stable enough to be powerful tools for gene mapping. Therefore the duplications described here will be useful in the genetic characterization of chromosome I and the techniques we have developed can be adapted to other regions of the genome.     

Base Excision Repair of DNA: Glycosylases

The review considers the role of base excision repair in maintaining the constancy of genetic information in the cell. The genetic control and biochemical mechanism are described for the first stage of base excision repair, which is catalyzed by specific enzymes, DNA glycosylases.__________Translated from Genetika, Vol. 41, No. 6, 2005, pp. 725–735.Original Russian Text Copyright © 2005 by Korolev.     

Nicotinamide Enhances Repair of Arsenic and Ultraviolet Radiation-Induced DNA Damage in HaCaT Keratinocytes and Ex Vivo Human Skin

Arsenic-induced skin cancer is a significant global health burden. In areas with arsenic contamination of water sources, such as China, Pakistan, Myanmar, Cambodia and especially Bangladesh and West Bengal, large populations are at risk of arsenic-induced skin cancer. Arsenic acts as a co-carcinogen with ultraviolet (UV) radiation and affects DNA damage and repair. Nicotinamide (vitamin B3) reduces premalignant keratoses in sun-damaged skin, likely by prevention of UV-induced cellular energy depletion and enhancement of DNA repair. We investigated whether nicotinamide modifies DNA repair following exposure to UV radiation and sodium arsenite. HaCaT keratinocytes and ex vivo human skin were exposed to 2μM sodium arsenite and low dose (2J/cm²) solar-simulated UV, with and without nicotinamide supplementation. DNA photolesions in the form of 8-oxo-7,8-dihydro-2′-deoxyguanosine and cyclobutane pyrimidine dimers were detected by immunofluorescence. Arsenic exposure significantly increased levels of 8-oxo-7,8-dihydro-2′-deoxyguanosine in irradiated cells. Nicotinamide reduced both types of photolesions in HaCaT keratinocytes and in ex vivo human skin, likely by enhancing DNA repair. These results demonstrate a reduction of two different photolesions over time in two different models in UV and arsenic exposed cells. Nicotinamide is a nontoxic, inexpensive agent with potential for chemoprevention of arsenic induced skin cancer.     

Genetic Analysis of Defecation in Caenorhabditis Elegans

Defecation in the nematode Caenorhabditis elegans is achieved by a cyclical stereotyped motor program. The first step in each cycle is contraction of a set of posterior body muscles (pBoc), followed by contraction of a set of anterior body muscles (aBoc), and finally contraction of specialized anal muscles that open the anus and expel intestinal contents (Exp). By testing existing behavioral mutants and screening for new mutants that become constipated due to defects in defecation, I have identified 18 genes that are involved in defecation. Mutations in 16 of these genes affect specific parts of the motor program: mutations in two genes specifically affect the pBoc step; mutations in four genes affect the aBoc step; mutations in four genes affect the Exp step; and mutations in six genes affect both aBoc and Exp. Mutations in two other genes affect the defecation cycle period but have a normal motor program. Sensory inputs that regulate the cycle timing in the wild type are also described. On the basis of the phenotypes of the defecation mutants and of double mutants, I suggest a formal genetic pathway for the control of the defecation motor program.     

Sex Determination in Polyploids of Caenorhabditis Elegans

In Caenorhabditis elegans triploid animals with two X chromosomes (symbolized 3A;2X) are males. However, these triploid males can be feminized by making them mutant for recessive dosage compensation mutations, by adding X chromosome duplications or by microinjecting particular DNA sequences termed feminizing elements. None of these treatments affects diploid males. This study explores several aspects of these treatments in polyploids. The dosage compensation mutants exhibit a strong maternal effect, such that reduction of any of the dosage compensation gene functions in the mother leads to sex reversal of 3A;2X animals. Likewise, all X chromosome duplications tested cause both sex reversal and intersexual development of many 3A;2X animals. Microinjected feminizing element DNA does not cause extensive sex reversal, but does result in intersexual development in 3A;2X animals. Neither X chromosome duplications nor microinjected feminizing elements show the extreme maternal effect of the dosage compensation mutants, although there is indirect evidence for a maternal effect of the feminizing elements. In particular, very little feminizing element DNA needs to be microinjected in order to feminize triploid males, far less than what is needed for stable inheritance, implying that feminizing elements can work within the mother's gonad. However, even very high concentrations of microinjected feminizing elements do not affect sex determination in diploid males, suggesting that they are not part of the numerator of the X/A ratio. In addition, no pair of X chromosome duplications feminizes diploid males, suggesting that none of these duplications contains a numerator of the X/A ratio. Instead, I infer that an X-linked locus, as yet undefined, must be present in two copies for hermaphrodite development to ensue or that the two X chromosomes might interact.