An unusual complementation in non-excitable mutants in Paramecium

A non-excitable behavioural mutant, d4-662, was previously characterized as the fourth pawn locus mutant pwD in Paramecium tetraurelia. We now provide data demonstrating that d4-662 is in fact controlled by a pwB allele that has the unusual feature of complementing other pwB alleles in heterozygous F1 progeny. Neither the cytoplasm nor the nucleoplasm of d4-662 cured the mutational defects of pwB and in the reverse combination of d4-662 and pwB, the result was the same. On the other hand, pwA, another non-excitable mutant, was cured upon cross-injection with d4-662 and mutants carrying trichocyst non-discharge marker genes were also cured. This evidence suggests that d4-662 is a new mutant belonging to pwB, and would be better designated as pwB662. Extensive crossbreeding analyses, however, showed an unusual genetic relationship between d4-662 and pwB (pwB95 or pwB96). When d4-662 was crossed with pwB mutants, many progeny expressing wild-type phenotype or mixed clones of wild-type and pawn cells were obtained in the F1. Less than 12.5% expressed the pawn phenotype. The appearance of wild-type progeny in this F1 strongly suggests that an inter-allelic interaction between pwB662 and other pwB alleles may occur during development of the macronucleus.     

The molecular basis for the alternative stable phenotype in a behavioral mutant of Paramecium tetraurelia

In the sexual reproduction of Paramecium tetraurelia, the somatic nucleus (macronucleus) undergoes massive genomic rearrangement, including gene amplification and excision of internal eliminated sequences (IESs), in its normal developmental process. Strain d4-662, one of the pawn mutants, is a behavioral mutant of P. tetraurelia that carries a recessive allele of pwB662. ThepwB gene in the macronucleus of the strain has an insertion of the IES because a base substitution within the IES prevents its excision during gene rearrangement. Cultures of this strain frequently contain cells reverting to the wild type in the behavioral phenotype. The mutant and revertant cells maintained stable clonal phenotypes under the various environmental conditions examined unless they underwent sexual reproduction. After sexual reproduction, both mutant and revertant produced 2.7-7.1% reverted progeny. A molecular analysis performed on the macronuclear DNA of the mutant and revertant of d4-662 showed that much less than 1% of the mutant IES was precisely excised at every sexual reproduction of the strain. Therefore, the alternative phenotype of strain d4-662 seems to be caused by an alternative excision of the mutant IES.     

Stable maintenance of duplicated chromosomes carrying the mutant pwB gene in Paramecium tetraurelia

An allele of the behavioural mutant pawn-B96 has been reported as a typical recessive gene but was found to show a peculiar inheritance. When the F2 progeny from crosses between the wild-type and pwB96 were obtained by autogamy, the 1:1 phenotypic segregation ratio was observed as expected. However, two-thirds of the wild-type progeny in the F2 were thought to be heterozygotes because they became mixed progeny of wild-type and pawn clones in successive autogamies. Four marker genes showed the expected segregation ratio and stable phenotypes in these crossings. This result and the results of crossings using segregants from the above crosses indicated that parental pwB96 is a tetrasomy of the chromosome carrying the pwB gene. To determine the cause of chromosomal duplication in the mutant, the stability of the chromosome carrying the pwB locus was examined by genetic analyses. The disomy of both pwB and wild-type and the tetrasomy of pwB showed genotypes that were relatively stable during several autogamous generations. However, in clones initially pure for the tetrasomy of wild-type, disomic cells appeared within a few autogamous generations. The difference between the stabilities of the tetrasomy of pwB96 and that of the wild-type might be due partly to differences between the growth rate of tetrasomy and disomy in pwB96 and the wild-type, but mostly the result of an unknown contribution of the chromosome carrying the pwB96 allele to the tetrasomic composition.     

Tumor suppressor p53: analysis of wild-type and mutant p53 complexes.

It has been suggested that the dominant effect of mutant p53 on tumor progression may reflect the mutant protein binding to wild-type p53, with inactivation of suppressor function. To date, evidence for wild-type/mutant p53 complexes involves p53 from different species. To investigate wild-type/mutant p53 complexes in relation to natural tumor progression, we sought to identify intraspecific complexes, using murine p53. The mutant phenotype p53-246(0) was used because this phenotype is immunologically distinct from wild-type p53-246+ and thus permits immunological analysis for wild-type/mutant p53 complexes. The p53 proteins were derived from genetically defined p53 cDNAs expressed in vitro and also from phenotypic variants of p53 expressed in vivo. We found that the mutant p53 phenotype was able to form a complex with the wild type when the two p53 variants were cotranslated. When mixed in their native states (after translation), the wild-type and mutant p53 proteins did not exhibit any binding affinity for each other in vitro. Under identical conditions, complexes of wild-type human and murine p53 proteins were formed. For murine p53, both the wild-type and mutant p53 proteins formed high-molecular-weight complexes when translated in vitro. This oligomerization appeared to involve the carboxyl terminus, since truncated p53 (amino acids 1 to 343) did not form complexes. We suggest that the ability of the mutant p53 phenotype to complex with wild type during cotranslation may contribute to the transforming function of activated mutants of p53 in vivo.     

Duplication-induced mutation of a new Neurospora gene required for acetate utilization: properties of the mutant and predicted amino acid sequence of the protein product.

A cloned Neurospora crassa genomic sequence, selected as preferentially transcribed when acetate was the sole carbon source, was introduced in extra copies at ectopic loci by transformation. Sexual crossing of transformants yielded acetate nonutilizing mutants with methylation and restriction site changes within both the ectopic DNA and the normally located gene. Such changes are typical of the duplication-induced premeiotic disruption (the RIP effect) first described by Selker et al. (E. U. Selker, E. B. Cambareri, B. C. Jensen, and K. R. Haack, Cell 51:741-752, 1987). The mutants had the unusual phenotype of growth on ethanol but not on acetate as the carbon source. In a cross to the wild type of a mutant strain in which the original ectopic gene sequence had been removed by segregation, the acetate nonutilizing phenotype invariably segregated together with a RIP-induced EcoRI site at the normal locus. This mutant was transformed to the ability to use acetate by the cloned sequence. The locus of the mutation, designated acu-8, was mapped between trp-3 and un-15 on linkage group 2. The transcribed portion of the clone, identified by probing with cDNA, was sequenced, and a putative 525-codon open reading frame with two introns was identified. The codon usage was found to be strongly biased in a way typical of most Neurospora genes sequenced so far. The predicted amino acid sequence shows no significant resemblance to anything previously recorded. These results provide a first example of the use of the RIP effect to obtain a mutant phenotype for a gene previously known only as a transcribed wild-type DNA sequence.     

Evidence for Positive Regulation of the Proline Utilization Pathway in Saccharomyces cerevisiae

A mutation has been identified that prevents Saccharomyces cerevisiae cells from growing on proline as the sole source of nitrogen, causes noninducible expression of the PUT1 and PUT2 genes, and is completely recessive. In the put3-75 mutant, the basal level of expression (ammonia as nitrogen source) of PUT1-lacZ and PUT2-lacZ gene fusions as measured by beta-galactosidase activity is reduced 4- and 7-fold, respectively, compared with the wild-type strain. Normal regulation is not restored when the cells are grown on arginine as the sole nitrogen source and put3-75 cells remain sensitive to the proline analog, L-azetidine-2-carboxylic acid, indicating that the block is not at the level of transport of the inducer, proline. In a cross between the put3-75 strain and the semidominant, constitutive mutation PUT3c-68, only parental ditype tetrads were found, indicating allelism of the two mutations. Further support for allelism derives from the comparison of enzyme levels in heteroallelic and heterozygous diploid strains. The constitutive allele appears to be fully dominant to the noninducible allele but only partially dominant to the wild type, suggesting an interaction between the wild-type and PUT3c-68 gene products. The PUT3 gene maps on chromosome XI, about 5.7 cM from the centromere. The phenotypes of alleles of the PUT3 gene, either recessive and noninducible (the put3-75 phenotype) or semidominant and constitutive (the PUT3c-68 phenotype), and their pleiotropy suggest that the PUT3 gene product is a positive activator of the proline utilization pathway.     

Carbonic anhydrase is essential for growth of Ralstonia eutropha at ambient CO(2) concentrations

Mutant strain 25-1 of the facultative chemoautotroph Ralstonia eutropha H16 had previously been shown to exhibit an obligately high-CO(2)-requiring (HCR) phenotype. Although the requirement varied with the carbon and energy sources utilized, none of these conditions allowed growth at the air concentration of CO(2). In the present study, a gene designated can and encoding a beta-carbonic anhydrase (CA) was identified as the site altered in strain 25-1. The mutation caused a replacement of the highly conserved glycine residue 98 by aspartate in Can. A can deletion introduced into wild-type strain H16 generated mutant HB1, which showed the same HCR phenotype as mutant 25-1. Overexpression of can in Escherichia coli and mass spectrometric determination of CA activity demonstrated that can encodes a functional CA. The enzyme is inhibited by ethoxyzolamide and requires 40 mM MgSO(4) for maximal activity. Low but significant CA activities were detected in wild-type H16 but not in mutant HB1, strongly suggesting that the CA activity of Can is essential for growth of the wild type in the presence of low CO(2) concentrations. The HCR phenotype of HB1 was overcome by complementation with heterologous CA genes, indicating that growth of the organism at low CO(2) concentrations requires sufficient CA activity rather than the specific function of Can. The metabolic function(s) depending on CA activity remains to be identified.     

Characterization of cyanobacterial glycogen isolated from the wild type and from a mutant lacking of branching enzyme

Cyanobacteria produce glycogen as their primary form of carbohydrate storage. The genomic DNA sequence of Synechocystis sp. PCC6803 indicates that this strain encodes one glycogen-branching enzyme (GBE) and two isoforms of glycogen synthase (GS). To confirm the putative GBE and to demonstrate the presence of only one GBE gene, we generated a mutant lacking the putative GBE gene, sll0158, by replacing it with a kanamycin resistance gene through homologous recombination. GBE in sll0158(-) mutant was eliminated; the mutant strain produced less glucan, equivalent to 48% of that produced by the wild type. In contrast to the wild-type strain that had 74% of the glucan being water-soluble, the mutant had only 14% of the glucan water-soluble. Molecular structures of glucans produced by the mutant and the wild type were characterized by using high-performance size-exclusion and anion-exchange chromatography. The glycogen produced by the wild type displayed a molecular mass of 6.6 x 10(7) daltons (degree of polymerization (DP) 40700) and 10% branch linkages, and the alpha-D-glucan produced by the mutant displayed a molecular mass of 4.7-5.6 x 10(3) daltons (DP 29-35) with slight branch linkages. The results indicated that sll0158 was the major functional GBE gene in Synechocystis sp. PCC6803.     

A New GA-Insensitive Semidwarf Mutant of Rice (Oryza sativa L.) with a Missense Mutation in the SDG Gene

A semidwarf line of Indica rice, Xinguiai, was derived from the progeny of a cross between the double dwarf mutant Xinguiaishuangai and the wild-type variety Nanjing 6. The semidwarf phenotype was controlled by the semidwarf gene, sdg. The second sheath and shoot elongation responses of the dwarf mutant to exogenous gibberellin (GA₃) showed that sdg was insensitive to gibberellin (GA), and its endogenous GAs content was higher than that in wild-type cultivars. The SDG gene was cloned by a map-based cloning method and sequencing analysis revealed that the coding region of sdg had a single nucleotide substitution resulting in a single amino acid change from alanine to threonine. A cleaved amplified polymorphic sequence marker was designed according to sequences from mutant and wild-type materials. This sequence marker could be used to distinguish wild types and mutants, and thus, could be used for molecular marker-assisted selection. The dwarf phenotype of the sdg mutant was restored to a normal phenotype by introducing the wild-type SDG gene. Rice transformation experiments and GUS staining demonstrated that the SDG gene was predominantly expressed in vegetative organs.     

Rapid Germination of a Barley Mutant Is Correlated with a Rapid Turnover of Abscisic Acid Outside the Embryo

In our study of the role of abscisic acid (ABA) in controlling the germination of barley grains, we tested a barley mutant line with a gigantum appearance (Hordeum distichum cv Quantum) for an ABA-insensitive phenotype by assaying germination in the presence of 10-4 M ABA. Dissected embryos of the mutant germinated at least 10 h earlier than did those of the wild type. The half-maximal concentrations of ABA inhibitory for germination were determined to be 5 x 10-4 M for the mutant and 10-6 M for the wild type. Expression of an ABA-induced Rab gene was studied to determine ABA responsiveness. The ABA concentration required for a half-maximal induction of Rab gene expression was 4 x 10-6 M in isolated embryos of both the mutant and wild type. This result suggests that ABA signal transduction pathways were not affected in the mutant. When isolated embryos were allowed to imbibe in water, ABA was released from the mutant and wild-type embryos at the same rate. However, the free ABA level in the incubation medium of the mutant showed a much faster decrease than that of the wild type, as demonstrated by two independent ABA assay methods (high-performance liquid chromatography and enzyme-linked immunosorbent assay). Our results suggest that turnover of ABA outside the embryo is a determining factor in the germination of barley seeds.     

The ++Sinorhizobium meliloti lon protease is involved in regulating exopolysaccharide synthesis and is required for nodulation of alfalfa

While screening for Sinorhizobium meliloti Pho regulatory mutants, a transposon mutant was isolated that constitutively expressed higher levels of acid and alkaline phosphatase enzymes. This mutant was also found to form pseudonodules on alfalfa that were delayed in appearance relative to those formed by the wild-type strain, it contained few bacteroids, and it did not fix nitrogen. Sequence analysis of the transposon insertion site revealed the affected gene to have high homology to Lon proteases from a number of organisms. In minimal succinate medium, the mutant strain was found to grow more slowly, reach lower maximal optical density, and produce more extracellular polysaccharide (EPS) than the wild-type strain. The mutant fluoresced brightly on minimal succinate agar containing calcofluor (which binds to EPSI, a constitutively expressed succinoglycan), and gas chromotographic analysis of purified total EPS showed that the glucose-to-galactose ratio in the lon mutant total EPS was 5.0 +/- 0.2 (mean +/- standard error), whereas the glucose-to-galactose ratio in the wild-type strain was 7.1 +/- 0.5. These data suggested that in addition to EPSI, the lon mutant also constitutively synthesized EPSII, a galactoglucan which is the second major EPS known to be produced by S. meliloti, but typically is expressed only under conditions of phosphate limitation. (13)C nuclear magnetic resonance analysis showed no major differences between EPS purified from the mutant and wild-type strains. Normal growth, EPS production, and the symbiotic phenotype were restored in the mutant strain when the wild-type lon gene was present in trans. The results of this study suggest that the S. meliloti Lon protease is important for controlling turnover of a constitutively expressed protein(s) that, when unregulated, disrupts normal nodule formation and normal growth.     

Modified plasma-membrane ATPase in mutants of Saccharomyces cerevisiae

Mutations affecting the plasma membrane ATPase of Saccharomyces cerevisiae were obtained by selecting mutants resistant to Dio-9. In a plasma-membrane-enriched fraction of the mutant MG2130, the ATPase activity was resistant to vanadate (50% inhibition by 26 microM in the mutant compared to 1.3 microM in the parental strain). Several catalytic properties of the membrane-bound ATPase were modified by 60-120% in the mutant which had a higher Km for MgATP and was more heatstable, less sensitive to mercurials, and more stimulated by monovalent cations than the parental type. A single mutation is responsible for the phenotypes of four independent allelic mutants. Resistance to Dio-9 in vivo and resistance to vanadate in vitro segregated together in three tetrads issued from a cross between the wild type and mutant. The mutation is semi-dominant as shown by expression of the mutant phenotype in a heterozygous diploid resulting from the cross between the wild type and mutant. It is concluded that the pma locus, affected by these mutations, is the structural gene either for the 100000-Mr subunit of plasma membrane ATPase or for a protein which tightly controls the conformation of the plasma-membrane ATPase within the membrane.     

Copper-sensitive mutant of Arabidopsis thaliana.

A Cu-sensitive mutant, cup1-1, of Arabidopsis thaliana has a pattern of heavy-metal sensitivity different from that of the cad1 and cad2 mutants, which are deficient in phytochelatin biosynthesis. The latter are significantly sensitive to Cd and Hg and only slightly sensitive to Cu, whereas the cup1-1 mutant is significantly sensitive to Cu, slightly sensitive to Cd, and not more sensitive to Hg, compared to the wild type. Genetic analysis has shown that the sensitive phenotype is recessive to the wild type and segregates as a single Mendelian locus, which has been mapped to chromosome 1. Genetic and biochemical studies demonstrate that the cup1-1 mutant is not affected in phytochelatin biosynthesis or function. The sensitive phenotype of the cup1-1 mutant is associated with, and probably due to, increased accumulation of higher levels of Cd and Cu compared with the wild type. Consistent with this, a Cu-inducible, root-specific metallothionein gene, MT2a, is expressed in cup1-1 roots under conditions in which it is not expressed in the wild type. Undifferentiated cup1-1 callus tissue did not show the Cu-sensitive phenotype, suggesting that the mutant phenotype, in contrast to cad1 and cad2, is not expressed at the cellular level.     

The role of OsBRI1 and its homologous genes, OsBRL1 and OsBRL3, in rice

Since first identifying two alleles of a rice (Oryza sativa) brassinosteroid (BR)-insensitive mutant, d61, that were also defective in an orthologous gene in Arabidopsis (Arabidopsis thaliana) BRASSINOSTEROID INSENSITIVE1 (BRI1), we have isolated eight additional alleles, including null mutations, of the rice BRI1 gene OsBRI1. The most severe mutant, d61-4, exhibited severe dwarfism and twisted leaves, although pattern formation and differentiation were normal. This severe shoot phenotype was caused mainly by a defect in cell elongation and the disturbance of cell division after the determination of cell fate. In contrast to its severe shoot phenotype, the d61-4 mutant had a mild root phenotype. Concomitantly, the accumulation of castasterone, the active BR in rice, was up to 30-fold greater in the shoots, while only 1.5-fold greater in the roots. The homologous genes for OsBRI1, OsBRL1 and OsBRL3, were highly expressed in roots but weakly expressed in shoots, and their expression was higher in d61-4 than in the wild type. Based on these observations, we conclude that OsBRI1 is not essential for pattern formation or organ initiation, but is involved in organ development through controlling cell division and elongation. In addition, OsBRL1 and OsBRL3 are at least partly involved in BR perception in the roots.     

The Anabaena sp. strain PCC 7120 asr1734 gene encodes a negative regulator of heterocyst development

The novel asr1734 gene of Anabaena (Nostoc) sp. strain PCC 7120 inhibited heterocyst development when present in extra copies. Overexpression of asr1734 inhibited heterocyst development in several strains including the wild type and two strains that form multiple contiguous heterocysts (Mch phenotype): a PatS null mutant and a hetR(R223W) mutant. Overexpression of asr1734 also caused increased nblA messenger RNA levels, and increased loss of autofluorescence in vegetative cells throughout filaments after nitrogen or sulphur depletion. Unlike the wild type, an asr1734 knockout mutant formed 5% heterocysts after a nitrogen shift from ammonium to nitrate, and formed 15% heterocysts and a weak Mch phenotype after step-down to medium lacking combined nitrogen. After nitrogen step-down, the asr1734 mutant had elevated levels of ntcA messenger RNA. A green fluorescent protein reporter driven by the asr1734 promoter, P(asr1734)-gfp, was expressed specifically in differentiating proheterocysts and heterocysts after nitrogen step-down. Strains overexpressing asr1734 and containing P(hetR)-gfp or P(patS)-gfp reporters failed to show normal patterned upregulation 24 h after nitrogen step-down even though hetR expression was upregulated at 6 h. Apparent orthologues of asr1734 are found only in two other filamentous nitrogen-fixing cyanobacteria, Anabaena variabilis and Nostoc punctiforme.