Genetic analysis of X-chromosome neurodegenerative mutants of Drosophila melanogaster induced by ethyl methansulfonate and nitrosoethylurea

In a series of Drosophila mutants with changes in the brain structure, some characters (reduced life span, behavioral changes, and neuronal loss in various brain regions) resemble symptoms observed in human patients with neurodegenerative diseases. In addition, similar specific phenotypes shared by different species suggest that common mechanisms underlie degeneration of their nerve cell. This study reports the results of a genetic analysis of new X-chromosome mutants with neurodegenerative changes in brain structure, which were induced by chemical mutagenesis. According to complementation test, all mutants were divided into three complementation groups, in which the life span and dynamics of neurodegenerative changes were studied. The life span of Drosophila melanogaster flies was found to depend on the state of their nervous system.     

Chemically InducedDrosophila melanogaster mutants with Changes in Brain Structure

Neurodegenerative human diseases are caused by nerve cell death and anatomical changes in some brain regions. Molecular genetic studies of Drosophila showed that this organism can serve as a valuable test-system for conserved mechanisms underlying human nervous system disorders. Analysis of brain functions is possible when the mutants with disturbed functions are available. In this study, we have developed a unique collection ofDrosophila melanogaster mutants with morphological and neurodegenerative changes in brain structure, which were induced by chemical mutagens.     

Two mutations in pab-1 encoding poly(A)-binding protein show similar defects in germline stem cell proliferation but different longevity in C. elegans

Four new alleles, bn116, bn117, bn118, and bn119, on LG I were isolated in C. elegans with defects in germline stem cell proliferation. Using genetic mapping and snip-SNP mapping, bn116, bn117, bn118, and bn119 were located 5.0 cM, 1.3 cM, 2.3 cM, and 5.0 cM, respectively, to the right of dpy-5 on LG I. Further, bn116 and bn119 were grouped into the same complementation group by a complementation test. They are loss-of-function recessive alleles that produce homozygous sterile worms whose germ cells do not proliferate during larval development. However, the worms contained normal somatic gonadal structures including distal tip cells and gonadal sheath cells, suggesting that the defect in germline proliferation was not caused by the absence of somatic signaling. Although DAF-16 was localized to the nucleus in all four mutants, the life span was extended only in the three mutants except bn116. These results suggest that the defect in germline stem cell proliferation, the presence of normal somatic gonadal tissues, and DAF-16 nuclear translocation were sufficient for extending the lifespan of the bn117, bn118, and bn119 mutants, but not the bn116 mutant. Intriguingly, bn116 and bn119 were identified as two different mutations on the same gene, pab-1, which encodes a poly(A)-binding protein. Therefore, although the bn116 and bn119 mutations cause similar defects in germ cell proliferation, their effects on life span are different.     

Mutations induced by X-ray irradiation and certain chemical reagents that alter the life span of <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>

Survivorship curves are constructed and the life span parameters in mutant Drosophila melanogaster lines obtained as a result of induction by X-ray irradiation (3000 rad) as well as the combined action of X-ray irradiation and certain chemical agents are analyzed. It is shown that most of these mutant lines are characterized by a reduction in vitality and a shortening of life span. By means of blot hybridization in the Sausern modification it is shown that insertion-excision processes in the genes white and cut may be among the factors responsible for rapid dying off of the imago. A series of neurodegenerative mutants is obtained from the effect of ethylnitrosourea on the basis of the Oregon wild type line. In these mutants vitality is reduced and the shortened life span indicators are correlated with the time when a change appears in the brain structures.     

Mutants with altered muscle structure in Caenorhabditis elegans

In the small nematode, Caenorhabditis elegans, mutants with a disorganized myofilament lattice structure have been identified by polarized light and electron microscopy. Genetic analysis places the mutations in 12 complementation groups which are distributed over the six linkage groups of C. elegans. The phenotypes are described for the mutants from the 9 complementation groups not previously reported on in detail. Most are paralyzed, but some exhibit essentially normal movement; mutants of two loci show changes only in later larval stages and adulthood. Morphological studies show that, in general, all the members of a complementation group show similar changes in muscle structure and that these changes are distinctive for that group. In mutants of several genes, disorganization of the myofilament lattice is general with no one component of the lattice more obviously altered than others. In mutants of other genes specific structures are prominently altered. In one of the instances where thick filaments appear to be abnormal, double mutants combining mutations in this gene (unc-82 IV) with mutations in the gene for a myosin heavy chain (MacLeod et al., 1977a,b) or paramyosin (Waterston et al., 1977) were used to show that the unc-82 gene product probably affects thick filament assembly through its actions on paramyosin. Some possible implications of the morphological features of the mutants as well as the conclusions derived from the genetic studies are discussed.     

Age-associated and tissue-specific decline in autophagic activity in the nematode C. elegans

Macroautophagy/autophagy is a cellular recycling process that is required for the extended life span observed in many longevity paradigms, including in the nematode C. elegans. However, little is known regarding the spatiotemporal changes in autophagic activity in such long-lived mutants as well as in wild-type animals during normal aging. In a recent study, we report that autophagic activity decreases with age in several major tissues of wild-type C. elegans, including the intestine, body-wall muscle, pharynx, and nerve-ring neurons. Moreover, long-lived daf-2/insulin-signaling mutants and glp-1/Notch receptor mutants display increased autophagic activity, yet with different time- and tissue-specific differences. Notably, the intestine appears to be a critical tissue in which autophagy contributes to longevity in glp-1, but not in daf-2 mutants. Our findings indicate that autophagic degradation is reduced with age, possibly with distinct kinetics in different tissues, and that long-lived mutants increase autophagy in a tissue-specific manner, resulting in increased life span.     

Inositol-Requiring Mutants of SACCHAROMYCES CEREVISIAE

Fifty-two inositol-requiring mutants of Saccharomyces cerevisiae were isolated following mutagenesis with ethyl methanesulfonate. Complementation and tetrad analysis revealed ten major complementation classes, representing ten independently segregating loci (designated ino1 through ino10) which recombined freely with their respective centromeres. Members of any given complementation class segregated as alleles of a single locus. Thirteen complementation subclasses were identified among thirty-six mutants which behaved as alleles of the ino1 locus. The complementation map for these mutants was circular.—Dramatic cell viability losses indicative of unbalanced growth were observed in liquid cultures of representative mutants under conditions of inositol starvation. Investigation of the timing, kinetics, and extent of cell death revealed that losses in cell viability in the range of 2-4 log orders could be prevented by the addition of inositol to the medium or by disruption of protein synthesis with cycloheximide. Mutants defective in nine of the ten loci identified in this study displayed these unusual characteristics. The results suggest an important physiological role for inositol that may be related to its cellular localization and function in membrane phospholipids. The possibility is discussed that inositol deficiency initiates the process of unbalanced growth leading to cell death through the loss of normal assembly, function, or integrity of biomembranes.—Part of this work has been reported in preliminary form (Culbertson and Henry 1974).     

Neurodegenerative mutants in Drosophila: a means to identify genes and mechanisms involved in human diseases?

There are 50 ways to leave your lover (Simon 1987) but many more to kill your brain cells. Several neurodegenerative diseases in humans, like Alzheimer’s disease, have been intensely studied but the underlying cellular and molecular mechanisms are still unknown for most of them. For those syndromes where associated gene products have been identified their biochemistry and physiological as well as pathogenic function is often still under debate. This is in part due to the inherent limitations of genetic analyses in humans and other mammals and therefore experimentally accessible invertebrate in vivo models, such as Caenorhabditis elegans and Drosophila melanogaster, have recently been introduced to investigate neurodegenerative syndromes. Several laboratories have used transgenic approaches in Drosophila to study the human genes associated with neurodegenerative diseases. This has added substantially to our understanding of the mechanisms leading to neurodegenerative diseases in humans. The isolation and characterization of Drosophila mutants, which display a variety of neurodegenerative phenotypes, also provide valuable insights into genes, pathways, and mechanisms causing neurodegeneration. So far only about two dozen such mutants have been described but already their characterization reveals an involvement of various cellular functions in neurodegeneration, ranging from preventing oxidative stress to RNA editing. Some of the isolated genes can already be associated with human neurodegenerative diseases and hopefully the isolation and characterization of more of these mutants, together with an analysis of homologous genes in vertebrate models, will provide insights into the genetic and molecular basis of human neurodegenerative diseases.     

Role ofRAS2in Recovery from Chronic Stress: Effect on Yeast Life Span

The replicative life span ofSaccharomyces cerevisiaewas previously shown to be modulated by the homologous signal transducers Ras1p and Ras2p in a reciprocal manner. We have used thermal stress as a life span modulator in order to uncover functional differences between theRASgenes that may contribute to their divergent effects on life span. Chronic exposure of cells throughout life to recurring heat shocks at sublethal temperatures decreased their replicative life span.ras2mutants, however, suffered the largest decrease compared to wild-type andras1mutant cells. The decrease was correlated with a substantial delay in resumption of budding upon recovery from these heat shocks, indicating an impaired renewal of cell cycling. Detailed analysis of gene expression showed that, during recovery,ras2mutants were selectively impaired in down-regulation of stress-responsive genes and up-regulation of growth-promoting genes. Our results suggest that one of the functions ofRAS2in maintaining life span, for whichRAS1does not substitute, is to ensure renewal of growth and cell division after bouts of stress that cells encounter during their life. This activity ofRAS2is effected by the cyclic AMP pathway. Overexpression ofRAS2,but notRAS2^ser42which is deficient in the activation of adenylate cyclase, completely reversed the effect of chronic stress on life span. Thus,RAS2is limiting for longevity in the face of chronic stress. SinceRAS2is known to down-regulate stress responses, this demonstrates that for longevity the ability to recover from stress is at least as important as the ability to mount a stress response.     

An amber map of Salmonella phage P22

Summary Forty five amber mutants of Salmonella phage P22 were assigned to 12 complementation groups. Two amber mutants could not be classified into any one particular group.Ten of the complementation groups were mapped by two-factor crosses. The map is circular and about 65 units long.The remaining two complementation groups each consist of a single member which form very small plaques. Attempts to map these two mutants by two-factor crosses were unsuccessful.     

Allelspezifische suppressormutationen vonSchizosaccharomyces pombe

By comparing the intragenic distribution of suppressor sensitive mutants in fine structure maps, 13 allele specific suppressor mutations (isolated from revertants in adenine dependent mutants of constitutionad ₇) have been analyzed for their allele specific patterns of action in three different groups of mutants blocked in adenine biosynthesis. The 13 suppressor mutations, which have resulted from mutations at seven different suppressor loci, are characterized by four different suppression patterns. Three of these patterns, which partially overlap, are not locus specific since they include sensitive mutants at each of the three lociad ₇, ad₆ andad ₁ studied. The relative frequency of mutants sensitive to one or the other of the suppressors of this type, the absence of osmotic-remedial strains among the suppressor sensitive mutants, and the polarized complementation behaviour of one suppressiblead ₆ mutant and two suppressiblead ₁ mutants capable of interallelic complementation, suggest that the suppression mechanism involves misreading of a mutant triplet of the nonsense type.     

Mutations induced by X-rays and some chemical reagents changing Drosophila melanogaster life span

It has been shown that most of Drosophila melanogaster mutant lines obtained as a result of X-rays irradiation (XI) as well as of the combined action of XI and some chemical agents are characterized by decreased indexes of average (7-40 %) and maximal (1-35 %) life span. Insertion-excision processes at the instable genes white and cut are among the reasons of decreased vitality and shortened life span in induced mutants. Collection of neurodegenerative mutants has been obtained under the influence of ENU. Fast dying of flies and decreased vitality correlated with time point of neurodegenerations in brain structure.     

Complementation betweenPhycomyces mutants of mating type (+) with abnormal phototropism

Summary Twelve mutants ofPhycomyces blakesleeanus with defects in sporangiophore phototropism (genotypemad) were obtained from a wild type of the (+) mating type by mutagenesis with nitrosoguanidine. These mutants were tested for genetic complementation against standard (+)mad mutants derived from sexual crosses between the isogenic (+) strain and established (-)mad mutants (Ootaki et al., 1974; Eslava et al., 1976). Heterokaryons for complementation tests were obtained by grafting stage I sporangiophores. The (+) mutants were also investigated for their sensory responses such as photoinduction of sporangiophores and avoidance. The mutants were grouped into two classes, based on the phenotypic classification scheme of Bergman et al. (1973). There were eleven class 1.2 mutants and one class 2 mutant. Complementation tests revealed that all eleven class 1.2 mutants carry the genemadC and the class 2 mutant carriesmadD. There was no evidence that any were double mutants. These results are consistent with the phenotypic classification and with the complementation results of themad mutants of the (-) mating type.     

prp4 from Schizosaccharomyces pombe, a mutant deficient in pre-mRNA splicing isolated using genes containing artificial introns

Summary We have generated a bank of temperature-sensitive (ts) Schizosaccharomyces pombe mutant strains. About 150 of these mutants were transformed with a ura4 gene containing an artificial intron. We screened these is mutants for mutants deficient in splicing of the ura4 intron. With this approach three mutants were isolated which have a general defect in the splicing process. Two of these mutants fall into the prp1 complementation group and one defines a new complementation group, prp4.     

Interallelic complementation at the pyrF locus and the homodimeric nature of orotate phosphoribosyltransferase (OPRTase) in Mucor circinelloides

Using 5-fluoroorotic acid (5-FOA) as a positive selection system we isolated mutants of Mucor circinelloides altered in the pyrimidine biosynthetic pathway. These mutants were found to be deficient either in orotidine-5′-monophosphate decarboxylase (OMPdecase), or in orotate phosphoribosyltransferase (OPRTase) activity. Complementation tests among mutants lacking OPRTase activity classified them into three groups, thus suggesting the possibility of interallelic complementation. To investigate this hypothesis a cDNA clone corresponding to the OPRTase-encoding gene of M. circinelloides was isolated by direct complementation of E. coli. The genomic copy transformed to prototrophy one member of each of the three classes of OPRTase-deficient mutants. We therefore concluded that they were all altered at the same locus, the pyrF locus. The corresponding alleles were cloned and sequenced. Comparisons of the amino acid sequence of M. circinelloides OPRTase with those of E. coli and S. typhimurium revealed a high degree of similarity in secondary and tertiary structure. As the two bacterial enzymes exist as dimers, a homodimeric quaternary structure of the M. circinelloides mature protein can be assumed. This would also explain the interallelic complementation between some pyrF mutants. The mutations found could affect either the active site or the structure of the dimer interface of the OPRTase. Received: 22 May 1998 / Accepted: 13 August 1998     

MORPHOGENESIS IN TRICHODERMA: AUTONOMOUS AND NONAUTONOMOUS PIGMENTATION IN HETEROKARYONS OF COLOR MUTANTS IN TRICHODERMA VIRIDE

The final step in the process of conidiation—conidial pigmentation—was studied in the fungus Trichoderma viride. Twenty-nine auxotrophic, color mutants, isolated from the same green wildtype strain, were paired to produce stable heterokaryons in all possible combinations and grouped according to their complementation behavior. No complementation (green pigmentation) was found in any of the heterokaryons formed by pairs of white (W) mutants. However, these mutants could be separated into two groups with respect to their behavior when paired with yellow (Y) and brown (Br) mutants. When W^c mutants were paired with any of the Y or Br mutants complementation took place. However, W^d mutants displayed this reaction with only one group of yellow mutants (Y^a) and not with the other (Y^b) nor with Br mutants. In noncomplementing heterokaryons such as Y^b/W^d, only yellow and white conidia were produced, pigmentation being autonomous. On the other hand, in heterokaryons in which complementation did take place, as for instance Y^a/W^d, green as well as white and yellow conidia were produced. Differential sensitivity to UV irradiation was used to show that the green conidia were of either W^d or F^a genotype, indicating a nonautonomous type of gene action. It is suggested that the genes W^c, Y^a, Y^b and Br have a sequential structural role in the biosynthesis of the green pigment, while W^d controls the activity of three (W^c, Y^b, Br) of these genes.     

Genetic analysis of benzoate metabolism in Aspergillus niger

Summary The benzoate metabolism of Aspergillus niger was studied as part of a design to clone the benzoate-4-hydroxylase gene of this fungus on the basis of complementation. Filtration enrichment techniques yielded mutants defective for different steps of benzoate degradation: bph (benzoate-4-hydroxylase), phh (4-hydroxybenzoate-3-hydroxylase) and prc (protocatechuate ring cleavage) mutants. In this way the degradation pathway for benzoate, involving the formation of 4-hydroxybenzoate and 3,4-dihydroxybenzoate has been confirmed. In addition a mutant sensitive to benzoate has been found. Complementation tests in somatic diploids showed that the bph mutants belonged to two complementation groups. The major group is probably defective in the structural gene (bphA). All phh mutants tested belonged to one complementation group. The prc mutants could be divided into several groups on the basis of their growth on different aromatic substrates and on the basis of the complementation test. The phh and both bph mutations are shown to be located on different chromosomes.Offprint requests to: C. J. Bos     

Cloning of seven differently complementing DNA fragments with chl functions from Escherichia coli K12

Summary Seven genomic libraries of chromosomal Escherichia coli K12 wild-type DNA were constructed in plasmid vectors. These were used to transform chl insertion mutants. Selection for growth on nitrate under anaerobic conditions yielded four plasmids which complemented mutants of the chlA, B, E and G types. The chromosomal fragments were mapped with restriction enzymes and subcloned. Three complementation groups were observed among the chlA mutants and two among the chlE mutants. The established complementation groups plus mutants of the chlD type represent eight distinct functions, which are all believed to be required for the molybdenum cofactor activity in the reduction of nitrate to nitrite by E. coli.     

Arginine and proline genes ofAspergillus niger

Summary Aspergillus niger mutants defective in arginine or proline biosynthesis have been isolated and 12 genetic loci were identified. Mutation was induced by low doses UV, and mutants were isolated after filtration enrichment. The mutants were classified according to their phenotype in growth tests and were further characterized in complementation tests. The arginine auxotrophic mutants represent nine complementation groups. Three additional complementation groups were found for mutants that could grow on proline (two of them on arginine too). Linkage group analysis was done in somatic diploids obtained from a mutant and a master strain with genetic markers on six chromosomes. Thearg genes belong to six different linkage groups and thepro genes to two. Onearg-mutant could be complemented by transformation with theA. nidulans arg B ⁺ gene, and thisA. niger gene thus appeared to be homologous to theA. nidulans arg B. We isolated anA. niger strain with theargB gene tightly linked with thenicA1 marker. This strain is very suitable as acceptor for transformation with anargB-plasmid, because transformants with inserts on the homologous site can be recognized and analyzed genetically using thenicA1 marker gene.     

Chemically induced Drosophila melanogaster mutants with changes in brain structure

Neurodegenerative human diseases are caused by nerve cell death and anatomical changes in some brain regions. Molecular genetic studies of Drosophila showed that this organism can serve as a valuable test-system for conserved mechanisms underlying human nervous system disorders. Analysis of brain functions is possible when the mutants with disturbed functions are available. In this study, we have developed a unique collection of Drosophila melanogaster mutants with morphological and neurodegenerative changes in brain structure, which were induced by chemical mutagens.