Cloning of the regulatory gene areA mediating nitrogen metabolite repression in Aspergillus nidulans.

The areA gene, which mediates nitrogen metabolite repression in the fungus Aspergillus nidulans, lies sufficiently close to a telomere that no indispensable gene can be distal to it. We were able therefore to exploit the existence of a near terminal pericentric inversion to devise a method for cloning areA plus the region beyond it towards the telomere. In crosses heterozygous for this inversion a class of duplication-deficient progeny lacking areA and the region centromere-distal to it is obtained. We, therefore, sought clones from an A. nidulans gene library in lambda Charon 4 able to hybridize to total genomic DNA from a wild-type strain but not to that from a duplication-deficiency strain. A clone, containing an 11.6-kb insert, which hybridised weakly to duplication-deficiency DNA, overlapped chromosome breakpoints of three different aberration-associated areA alleles and was able to transform an areA mutant to areA+. Southern blotting and genetic analysis established that the transforming sequence had integrated in the region centromere distal to areA. The cloning method yielded other clones from the region centromere-distal to areA which were used to show that the translocation associated with a mutant areA allele is reciprocal rather than non-reciprocal, a fact which could not be established by classical genetics. Finally, analysis of the cloned portion of the dispensable region centromere-distal to areA indicates that this region contains at least 0.5% of the A. nidulans genome.     

A paracentric inversion suppresses genetic recombination at the <Emphasis Type="Italic">FON3</Emphasis> locus with breakpoints corresponding to sequence gaps on rice chromosome 11L

Paracentric inversion is known to inhibit genetic recombination between normal and inverted chromosomal segments in heterozygous arrangements. Insect inversion polymorphisms have been studied to reveal adaptive processes for maintaining genetic variation. We report the first paracentric inversion in rice (Oryza sativa), which was discovered in our effort to clone the floral organ number gene FON3. Recombination at the FON3 locus on the long arm of chromosome 11 was severely suppressed over a distance of more than 36 cM. An extensive screening among 8,242 F₂ progeny failed to detect any recombinants. Cytological analysis revealed a loop-like structure on pachytene chromosomes, whereas FISH analysis showed the migration of a BAC clone from a distal location to a position closer to the centromere. Interestingly, the locations where the genetic recombination suppression began were coincided with the positions of two physical gaps on the chromosome 11, suggesting a correlation between the physical gaps, the inversion breakpoints. Transposons and retrotransposons, and tandemly arranged members of gene families were among the sequences immediately flanking the gaps. Taken together, we propose that the genetic suppression at the FON3 locus was caused by a paracentric inversion. The possible genetic mechanism causing such a spontaneous inversion was proposed.     

A locus for eosinophilia in the MES rat is on Chromosome 19

Matsumoto Eosinophilia Shinshu (MES) is a rat strain that spontaneously develops eosinophilia and eosinophil-related inflammatory lesions in many organs. We performed chromosomal mapping of the gene for eosinophilia by breeding backcross progeny. The onset of eosinophilia appeared to be delayed in the progeny compared with that in MES, with the prevalence of eosinophilia in the backcross progeny at 12 weeks of age being 22.5%. Genetic linkage analysis with marker loci indicated the major locus for eosinophilia was located at the end of the q arm region of Chromosome 19 (between D19Rat8 and telomere). The locus was denoted eosinophilia 1 (eos1). These data will form the basis for identification of the eos1 gene using a reverse genetic approach, which will hopefully lead to elucidation of the mechanisms involved in eosinophilia and eosinophilopoiesis.     

Localisation of several chromosome I genes of Aspergillus nidulans: implications for mitotic recombination

Summary Another laboratory previously reported that the vast majority of mitotic recombinants in chromosome I disomics of Aspergillus nidulans arise from double exchange events involving the centromeric region and a far distal, possibly telomeric, region. This conclusion was based on the assumption that the camC gene is located in a position far distal to the centromere on the left arm of chromosome. I. As a left arm location for camC distal to the centromere was possibly in conflict with mapping data obtained in the context of an unrelated project, camC was partially mapped along with three other previously unlocated chromosome I genes, davA, ornD and uapA. The data presented here indicate that camC is located in a position far distal to the centromere but on the right arm of chromosome I, a conclusion also supported by the previous data. The positioning of uapA and camC in far distal locations on the right arm of chromosome I indicates the existence of a vast, otherwise nearly unmapped region on this chromosome arm.     

Stabilization of a terminal inversion duplication of 8p by telomere capture from 18q

Terminal inversion duplications of the short arm of chromosome 8 are one of the more common chromosome rearrangements in humans. We report an infant with multiple congenital anomalies, in whom karyotype analysis showed a terminal inversion duplication of 8p including additional material at the distal end of the derivative chromosome, shown to be of chromosome 18q origin. Terminal inversion duplications of 8p are the result of meiotic recombination between inverted olfactory gene receptor repeats in 8p. This recombination generates a dicentric intermediate that breaks during anaphase, and the broken chromosome end is stabilized by telomere healing or telomere capture. The origin of the telomeric region in the majority of constitutional chromosome deletions studied to date was shown to be from telomere healing; the de novo addition of telomeric repeats. In the proband a cytogenetically detectable piece of chromosome 18q was present on the distal end of the derivative 8, suggesting that this chromosome was stabilized by telomere capture of 18q. FISH analyses of additional cases may yield information as to whether telomere capture or telomere-healing events are the predominant mechanism of chromosome stabilization in terminal inversion duplications of 8p.     

Cytological studies of African cultivated rice,Oryza glaberrima

African cultivated rice, Oryza glaberrima Steud., was cytologically characterized by using both karyotype analysis and molecular cytology. The somatic chromosomes resemble those of Asian cultivated rice, Oryza sauva L., in general morphology, although some minor differences were noted. Multicolor fluorescence in situ hybridization (McFISH) with chromosomes detected one 45s (17s-5.8s-25s) ribosomal RNA gene locus (45s rDNA) and one 5s ribosomal RNA gene locus (5s rDNA) in the chromosome complement. The 45s rDNA and 5s rDNA loci were physically mapped to the distal end of the short arm of chromosome 9 and to the proximal region of the short arm of chromosome 11 respectively, as in O. sativa. Based on the cytological observations and the physical map of the rDNA loci, the chromosomal organization of O.glaberrima and O. sativa seems to be very similar.     

Fine-mapping and candidate gene analysis of bovine spinal muscular atrophy

Bovine spinal muscular atrophy (SMA), an autosomal recessive neurodegenerative disease, has been mapped at moderate resolution to the distal part of Chromosome 24. In this article we confirm this location and fine-map the SMA locus to an interval of approximately 0.8 cM at the very distal end of BTA24. Despite remarkable similarity to human SMA, the causative gene SMN can be excluded in bovine SMA. However, the interval where the disease now has been mapped contains BCL2, like SMN an antiapoptotic factor, and shown to bind to SMN. Moreover, knockout mice lacking the BCL2 gene show rapid motor neuron degeneration with early postnatal onset, as observed in bovine SMA. A comparative cattle/human map of the distal end of BTA24, based on the emerging bovine genome sequencing data, shows conserved synteny to HSA18 with hints of a segmental duplication and pericentic inversion just after the last available bovine marker DIK4971. This synteny lets us conclude that SMA is in immediate vicinity of the telomere. Candidate gene analysis of BCL2, however, excludes most of this gene, except its promoter region, and draws attention to the neighboring gene VPS4B, part of the endosomal protein-sorting machinery ESCRT-III which is involved in several neurodegenerative diseases. Stefan Krebs and Ivica Medugorac contributed equally to this work and agreed to be considered as first authors.     

Distal into proximal (Dipr): A homoeotic mutation of Drosophila melanogaster

Summary The morphology and genetical characteristics of a new dominant homoeotic mutation, called Distal into proximal (Dipr), are described. Dipr causes two main abnormalities, both of which are specific to distal regions of the adult appendages (i.e. the wing, haltere, legs, antenna, and proboscis); first that distal parts are reduced in size and second that the patterns found distally resemble those normally localised in more proximal parts. The mutation maps to the right arm of chromosome 3 and is associated with an inversion with breakpoints in 84D and 84F. Analysis of revertants of Dipr show that the right breakpoint of In(3R)Dipr is the one responsible for the mutant phenotype. Complementation analyses of Dipr revertants and dosage studies of Dipr with different doses of Dipr ⁺ indicate that the mutant is a hypermorph affecting the normal expression of a gene localised in 84F. The developmental significance of the mutation is discussed.     

Genetic mapping of an ancient translocation in the genus Lens

Summary Segregation of 18 marker genes was monitored in selfed progeny of a Lens culinaris × L. ervoides hybrid; five linkage groups were mapped, one of which contained a reciprocal translocation break-point that differentiates between the parents. Four markers were found to be linked to the translocation break-point: Aco-1 and Pgm-2 on one side and Gs and Got-2 on the other. The gene pairs on both sides of the translocation are not linked in L. culinaris or in L. orientalis. The L. ervoides gene order was also found in L. odemensis but with significantly reduced map distances. Analysis of monogenic segregations in a number of Lens inter-specific crosses revealed some consistent patterns of deviations from the expected Mendelian ratios. The factors responsible for these unequal segregations, genotypic effects on recombination frequencies, negative interference, and the possible ancient origin of the translocation are discussed.     

Nitrogen metabolite repression in Aspergillus nidulans

Summary In Aspergillus nidulans, mutations, designated areA^r, can result in the inability to utilise a wide variety of nitrogen sources including amino acids, purines, amides, nitrate, and nitrite, whilst not affecting growth on ammonium. Other allelic areA mutations, designated areA^d, lead to derepression of one or more activities which are ammonium repressible in wild type (areA⁺) strains, whilst not affecting their inducibility. Various areA mutations exhibit a wide variety of phenotypes: areA^r alleles can be temperature sensitive on some nitrogen sources while not on others, and different alleles can be temperature sensitive for utilisation of different nitrogen sources. areA^d alleles can be derepressed for one ammonium-repressible activity, be normally repressible for another, and lead to abnormally low levels for a third. Once again each areA^d allele has its own highly specific phenotype. The inability of areA^r strains to utilise most nitrogen sources is paralleled by low activities of certain ammonium-repressible enzymes. areA^r mutations appear to be epistatic to some but not all regulatory mutations leading to constitutive synthesis of inducible enzymes and also epistatic to gdhA mutations which lead both to loss of NADP-linked glutamate dehydrogenase and to derepression of ammonium-repressible activities. areA^r mutations do not interfere with repair of a large number of auxotrophies in double mutants. Furthermore, although areA^r mutations prevent utilisation of L-arginine, L-ornithine, and L--amino-n-butyrate as nitrogen sources, they do not prevent the metabolism of these compounds necessary for repairing auxotrophies for proline and isoleucine in the appropriate double mutants. Utilisation of acetamide and most amino acids as carbon or carbon and nitrogen sources is unaffected by areA^r mutations, and areA^r strains are able to utilise acetamide and L-proline (but not other amino acids) as nitrogen sources in the presence of non-catabolite-repressing carbon sources such as L-arabinose, glycerol, melibiose, and lactose. Suppressor mutations, designated creA^d, probably leading to loss of carbon catabolite repression, allow utilisation of acetamide and proline as nitrogen sources in areA^r double mutants in the presence of carbon catabolite-repressing carbon sources. creA^d mutations allow ethanol to serve as a source of acetate for pyruvate dehydrogenaseless (pdhA) strains in the presence of carbon catabolite-repressing carbon sources, whereas pdhA single mutants respond to ethanol as sole carbon source only in the presence of non-carbon catabolite-repressing carbon sources. Specific suppressor mutations, designated amd ^d and prn ^d, allow utilisation of acetamide or proline, respectively, in areA^r double mutants.The areA locus can be interpreted as specifying a protein which is capable of (and in most cases essential for) allowing the synthesis of a number of enzymes of nitrogen metabolism but which cannot function in the presence of ammonium (i.e., as specifying a positive regulatory element which mediates ammonium repression) although the possibility that the areA product also plays a negative regulatory role cannot at present be ruled out.     

Induction of recombination between rye chromosome 1RL and wheat chromosomes

Summary The ph1b mutant in bread wheat has been used to induce homoeologous pairing and recombination between chromosome arm 1RL of cereal rye and wheat chromosome/s. A figure of 2.87% was estimated for the maximal frequency of recombination between a rye glutelin locus tightly linked to the centromere and the heterochromatic telomere on the long arm of rye chromosome 1R in the progeny of ph1b homozygotes. This equates to a gametic recombination frequency of 1.44%. This is the first substantiated genetic evidence for homoeologous recombination between wheat and rye chromosomes. No recombinants were confirmed in control populations heterozygous for ph1b. The ph1b mutant was also observed to generate recombination between wheat homoeologues.     

Homozygous-viable pericentric inversions for genetic control of Lucilia Cuprina

Summary The isolation of homozygous-viable pericentric inversions for inclusion in field-female killing (FK) systems in Lucilia cuprina is described. From 7,236 irradiated chromosomes screened, 16 pericentric inversions were isolated. Four of these were viable as homozygotes. One of these, In (3LR) 14, possesses the properties required for inclusion in FK systems (tight linkage of one inversion break-point to the white-eye gene and substantial genetic exchange within the inversion in heterozygous females).     

Molecular characterization of a specific p-nitrophenylphosphatase gene, PHO13, and its mapping by chromosome fragmentation in Saccharomyces cerevisiae

Summary The structural gene, PHO13, for the specific p-nitrophenyl phosphatase of Saccharomyces cerevisiae was cloned and its nucleotide sequence determined. The deduced PHO13 protein consists of 312 amino acids and its molecular weight is 34635. The disruption of the PHO13 gene produced no effect on cell growth, sporulation, or viability of ascospores. The PHO13 locus was mapped at 1.9 centimorgans from the HO locus on the left arm of chromosome IV. By chromosome fragmentation, the PHO13 locus was found to be located about 72 kb from the left-hand telomere of chromosome IV and distal to the HO locus.     

Mapping of the Sod-2 locus into the t complex on mouse chromosome 17

A human DNA probe specific for the superoxide dismutase gene was used to identify the corresponding mouse gene. Under the chosen hybridizing conditions, the probe detected DNA fragments most likely carrying the mouse Sod-2 gene. Mapping studies revealed that the Sod-2 gene resides in the proximal inversion of the t complex on mouse chromosome 17. All complete t haplotypes tested showed restriction fragment length polymorphism which is distinct from that found in all wild-type chromosomes tested. The Sod-2 locus maps in the same region as some of the loci that influence segregation of t chromosomes in male gametes. The possibility that the Sod-2 locus is related to some of the t-complex distorter or responder loci is discussed. The data indicate that the human homolog of the mouse t complex has split into two regions, the distal region remaining on the p arm of human chromosome 6, while the proximal region has been transposed to the telomeric region of this chromosome's q arm.     

Assignment of the complement serine protease genes C1r and C1s to chromosome 12 region 12p13

Summary C1r and C1s are distinct, but structurally and functionally similar, serine protease zymogens responsible for the enzymatic activity of the first component of complement (C1). Recent comparisons indicate a significant degree of sequence similarity between C1r and C1s and support the hypothesis that they are related by gene duplication. Complementary DNA probes for human C1r and C1s do not cross-hybridize even at mild stringency conditions and are therefore genespecific. Using a panel of 25 human-rodent cell hybrids, we have independently assigned the C1r and the C1s genes to chromosome 12. In situ hybridization analyses were consistent with these assignments, showing in addition that both C1r and C1s are located on the short arm of the chromosome in the region p13. These data suggest that the homologous C1r and C1s genes have remained closely linked after duplication of a common ancestor. The C1r and C1s loci also provide useful polymorphic DNA markers for the short arm of chromosome 12.     

Mapping of the <Emphasis Type="Italic">S. demissum</Emphasis> late blight resistance gene <Emphasis Type="Italic">R8</Emphasis> to a new locus on chromosome IX

The use of resistant varieties is an important tool in the management of late blight, which threatens potato production worldwide. Clone MaR8 from the Mastenbroek differential set has strong resistance to Phytophthora infestans, the causal agent of late blight. The F1 progeny of a cross between the susceptible cultivar Concurrent and MaR8 were assessed for late blight resistance in field trials inoculated with an incompatible P. infestans isolate. A 1:1 segregation of resistance and susceptibility was observed, indicating that the resistance gene referred to as R8, is present in simplex in the tetraploid MaR8 clone. NBS profiling and successive marker sequence comparison to the potato and tomato genome draft sequences, suggested that the R8 gene is located on the long arm of chromosome IX and not on the short arm of chromosome XI as was suggested previously. Analysis of SSR, CAPS and SCAR markers confirmed that R8 was on the distal end of the long arm of chromosome IX. R gene cluster directed profiling markers CDP^Sw54 and CDP^Sw55 flanked the R8 gene at the distal end (1 cM). CDP^Tm21-1, CDP^Tm21-2 and CDP^Tm22 flanked the R8 gene on the proximal side (2 cM). An additional co-segregating marker (CDP^Hero3) was found, which will be useful for marker assisted breeding and map based cloning of R8.     

Multiple Mißbildungen bei einem Mädchen mit dem Karyotypus 46, XY, 17q+

Summary In a girl with multiple malformations (Pierre Robin syndrome, abortive form of dysostosis cleidocranialis, and other deformities) a spontaneous duplication-deficiency as well as the XY sex chromosomes were found. Detailed cytogenetic analysis revealed a deficiency of the distal half of the long arm of a chromosome 17. The duplication involves a region of the size of the long arm of chromosome 18. The combination of malformations as well as the autoradiographic pattern does not exclude the possibility that indeed a region of the long arm of chromosome 18 is involved.

---

---

Wesentliche Teile der vorliegenden Arbeit werden von Herrn Dieter Bombel als Dissertation der Medizinischen Fakultät der Universität Freiburg i. Br. vorgelegt.

---

Mit Unterstützung durch die Deutsche Forschungsgemeinschaft.     

THE ASSOCIATION BETWEEN THE POLYMORPHISMS AT THE Adh AND αGpdh LOCI AND THE In(2L)t INVERSION IN DROSOPHILA MELANOGASTER IN RELATION TO TEMPERATURE

Substantial allele-frequency changes were observed at the Adh and αGpdh loci in a seminatural population of Drosophila melanogaster kept in a tropical greenhouse during 1972–1985. Further analysis of the changes at the Adh and αGpdh loci showed that linkage disequilibrium between these loci occurred for a prolonged period due to the presence of In(2L)t, a long inversion on the left arm of the second chromosome. We observed increases in the frequencies of In(2L)t and of short inversions on the left arm of the second chromosome in subpopulations kept at 29.5°C or 33°C. These inversion-frequency increases were accompanied by an increase in Adh^s and a decrease in αGpdh^s frequency. In populations kept at 20°C and 25°C, inversion frequencies decreased, while αGpdh^s allele frequencies decreased at 25°C and increased at 20°C. At 33°C, egg-to-adult survival of individuals possessing In(2L)t, either in the homokaryotypic or the heterokaryotypic state, was higher than that of the other karyotypes of identical allozyme constitution (i.e., Adh^s αGpdh^F). Thus it seems that In(2L)t has a selective advantage at high temperature. We argue that the observed changes in allele frequencies at the Adh and αGpdh loci are, in part, due to genic selection and are not merely the result of selection acting on the chromosome rearrangements and hitchhiking of the allozymes. The results are discussed with respect to the latitudinal clines found for In(2L)t, Adh, and αGpdh.