Interaction ofFLC and late-flowering mutations inArabidopsis thaliana

The phenotype caused by mutations that affect the timing of flowering inArabidopsis thaliana has been most extensively analyzed in the Landsbergerecta (Ler) genetic background. In Ler, the late-flowering phenotype ofFRIGIDA and mutations inLUMINIDEPENDENS is suppressed by the Ler allele ofFLC. In this study, the interactions of nine mutations conferring late flowering with theFLC allele of the Columbia ecotype (FLC-Col), which does not suppress late flowering, were examined. The effect on flowering time of combining six of the mutations withFLC-Col was additive; plants containingFLC-Col withfd, gi, fwa, fha, ft, andfe flowered slightly later than plants containing these mutations with theLer allele ofFLC. In contrast, a synergistic effect was observed betweenFLC-Col and three mutations;fca, fpa, andfve plants became extremely late flowering when combined withFLC-Col. Maximum delay in flowering for the majority of the mutant strains requiredFLC-Col in a homozygous state, although forfpa andfe a single copy ofFLC-Col allowed maximum lateness. In addition, thefd andfe mutations became more dominant in the presence ofFLC-Col.     

The late-flowering phenotype of FRIGIDA and mutations in LUMINIDEPENDENS is suppressed in the Landsberg erecta strain of Arabidopsis

The late-flowering phenotype of mutations in the LUMINIDEPENDENS (LD) gene and the late flowering caused by the naturally occurring dominant gene FRIGIDA (FRI) are suppressed in the Landsberg erecta (Ler) strain of Arabidopsis thaliana. This suppression is dependent on a locus on chromosome 5 designated FLC. Of the ecotypes tested, only the Ler strain contains the suppressor allele of FLC; ld mutations and FRI cause late flowering in the other genetic backgrounds. The allele at FLC also has a moderate effect on flowering time in the absence of FRI or ld mutations. The flowering time effects of FLC are gene dosage dependent.     

QTL analysis of flowering time inArabidopsis thaliana

Quantitative trait loci (QTL) analyses based on restriction fragment length polymorphism maps have been used to resolve the genetic control of flowering time in a cross between twoArabidopsis thaliana ecotypes H51 and Landsbergerecta, differing widely in flowering time. Five quantitative trait loci affecting flowering time were identified in this cross (RLN1-5), four of which are located in regions containing mutations or loci previously identified as conferring a late-flowering phenotype. One of these loci is coincident with theFRI locus identified as the major determinant for late flowering and vernalization responsiveness in theArabidopsis ecotype Stockholm.RLN5, which maps to the lower half of chromosome five (between markers mi69 and m233), only affected flowering time significantly under short day conditions following a vernalization period. The late-flowering phenotype of H51 compared to Landsbergerecta was due to alleles conferring late flowering at only two of the five loci. At the three other loci, H51 possessed alleles conferring early flowering in comparison to those of Landsbergerecta. Combinations of alleles conferring early and late flowering from both parents accounted for the transgressive segregation of flowering time observed within the F₂ population. Three QTL,RLN1,RLN2 andRLN3 displayed significant genotype-by-environment interactions for flowering time. A significant interaction between alleles atRLN3 andRLN4 was detected.     

Mutations in somePolycomb group genes ofDrosophila interfere with regulation of segmentation genes

Mutations in severalPolycomb (Pc) group genes cause maternal-effect or zygotic segmentation defects, suggesting thatPc group genes may regulate the segmentation genes ofDrosophila. We show that individuals doubly heterozygous for mutations inpolyhomeotic and six otherPc group genes show gap, pair rule, and segment polarity segmentation defects. We examined double heterozygous combinations ofPc group and segmentation mutations for enhancement of adult and embryonic segmentation defects.Posterior sex combs andpolyhomeotic interact withKrüppel ² and enhance embryonic phenotypes ofhunchback andknirps, andpolyhomeotic enhanceseven-skipped. Surprisingly, flies carrying duplications ofextra sex combs (esc), that were heterozygous for mutations ofeven-skipped (eve), were extremely subvital. Embryos and surviving adults of this genotype showed strong segmentation defects in even-numbered segments. Antibody studies confirm that expression ofeve is suppressed by duplications ofesc. However,esc duplications have no effect on other gap or pair rule genes tested. To our knowledge, this is only the second triplo-abnormal phenotype associated withPc group genes. Duplications of nine otherPc group genes have no detectable effect oneve. Expression ofengrailed (en) was abnormal in the central nervous systems of mostPc group mutants. These results support a role forPc genes in regulation of some segmentation genes, and suggest thatesc may act differently from otherPc group genes.     

Indirect evidence of alteration in the expression of the rDNA genes in interspecific hybrids betweenDrosophila melanogaster andDrosophila simulans

Crosses betweenDrosophila melanogaster females andD. simulans males produce viable hybrid females, while males are lethal. These males are rescued if they carry theD. simulans Lhr gene. This paper reports that females of the wild-typeD. melanogaster population Staket do not produce viable hybrid males when crossed withD. simulans Lhr males, a phenomenon which we designate as the Staket phenotype. The agent responsible for this phenomenon was found to be the StaketX chromosome (X ^mel ,Stk). Analysis of the Staket phenotype showed that it is suppressed by extra copies ofD. melanogaster rDNA genes and that theX ^mel ,Stk chromosome manifests a weak bobbed phenotype inD. melanogaster X ^mel ,Stk/0 males. The numbers of functional rDNA genes inX ^mel ,Stk andX ^mel ,y w (control) chromosomes were found not to differ significantly. Thus a reduction in rDNA gene number cannot account for the weak bobbedX ^mel ,Stk phenotype let alone the Staket phenotype. The rRNA precursor molecules transcribed from theX ^mel ,Stk rDNA genes seem to be correctly processed in both intraspecific (melanogaster) and interspecific (melanogaster-simulans) conditions. It is therefore suggested that theX ^mel ,Stk rDNA genes are inefficiently transcribed in themelanogaster-simulans hybrids.     

The mitochondrial genome of Chlamydomonas. II. Genetic analysis of non-mendelian obligate photautotrophic mutants

Summary Among a collection of obligate photoautotrophic (dark-dier,dk) mutants isolated inChlamydomonas reinhardtii, two have been found which are inherited in crosses to wild type in a non-Mendelian, biparental and apparently random fashion. F₁ progeny include not only cells which show thedk and wildtype parental phenotypes but also many which possess intermediate phenotypes between wild type anddk. When F₁ progeny withdk, intermediate or wild-type phenotype were backcrossed to wild type, thedk phenotype continued to be inherited in a biparental and random fashion. Upon selection, neither mutant formed stable clones producing onlydk progeny, suggesting that the two mutants segregatedk and wild-type progeny somatically and that the homozygousdk condition may be lethal. The biparental transmission of these two non-Mendeliandk mutations resembles the transmission of acriflavin-inducedminute mutations ofChlamydomonas and is distinct from the uniparentally inherited chloroplast mutations of this alga. Both thedk andminute mutations may alter mitochondrial DNA and thereby alter mitochondrial functions.     

Environmental and genetic interactions reveal FLOWERING LOCUS C as a modulator of the natural variation for the plasticity of flowering in Arabidopsis

The timing of flowering initiation depends strongly on the environment, a property termed as the plasticity of flowering. Such plasticity determines the adaptive potential of plants because it provides phenotypic buffer against environmental changes, and its natural variation contributes to evolutionary adaptation. We addressed the genetic mechanisms of the natural variation for this plasticity in Arabidopsis thaliana by analysing a population of recombinant inbred lines derived from Don‐0 and Ler accessions collected from distinct climates. Quantitative trait locus (QTL) mapping in four environmental conditions differing in photoperiod, vernalization treatment and ambient temperature detected the folllowing: (i) FLOWERING LOCUS C (FLC) as a large effect QTL affecting flowering time differentially in all environments; (ii) numerous QTL displaying smaller effects specifically in some conditions; and (iii) significant genetic interactions between FLC and other loci. Hence, the variation for the plasticity of flowering is determined by a combination of environmentally sensitive and specific QTL, and epistasis. Analysis of FLC from Don identified a new and more active allele likely caused by a cis‐regulatory deletion covering the non‐coding RNA COLDAIR. Further characterization of four FLC natural alleles showed different environmental and genetic interactions. Thus, FLC appears as a major modulator of the natural variation for the plasticity of flowering to multiple environmental factors.     

The phenotype of some late-flowering mutants is enhanced by a locus on chromosome 5 that is not effective in the Landsberg erecta wild-type

Late-flowering mutants that have been described in ecotypes other than Landsberg erecta (Ler) have been found to be dominant alleles of the FRI locus located on chromosome 4, which determines lateness in many very late ecotypes. The extreme lateness of dominant FRI alleles depends on dominant alleles at the FLC locus that maps on the top of chromosome 5. FLC alleles with this effect have been found in all ecotypes tested (Col, Ws, S96, Est and Li) except Ler. Most likely the same locus confers lateness to the luminidependens (ld) mutant. Genotypes with a dominant FRI allele and the monogenic recessive ld mutant are only slightly later with recessive Ler alleles at the FLC locus. Genotypes where the dominant FLC alleles are combined with FRI or with the ld mutant, are strongly responsive to vernalization, which is much less effective in the FLC-Ler background.     

Characterization of type II protein secretion (xcp) genes in the plant growth-stimulatingPseudomonas putida, strain WCS358

InPseudomonas aeruginosa, the products of thexcp genes are required for the secretion of exoproteins across the outer membrane. Despite structural conservation of the Xcp components, secretion of exoproteins via the Xcp pathway is generally not found in heterologous organisms. To study the specificity of this protein secretion pathway, thexcp genes of another fluorescent pseudomonad, the plant growth-promotingPseudomonas putida strain WCS358, were cloned and characterized. Nucleotide sequence analysis revealed the presence of at least five genes, i.e.,xcpP, Q, R, S, andT, with homology toxcp genes ofP. aeruginosa. Unlike the genetic organization inP. aeruginosa, where thexcp cluster consists of two divergently transcribed operons, thexcp genes inP. putida are all oriented in the same direction, and probably comprise a single operon. Upstream ofxcpP inP. putida, an additional open reading frame, with no homolog inP. aeruginosa, was identified, which possibly encodes a lipoprotein. Mutational inactivation ofxcp genes inP. putida did not affect secretion, indicating that no proteins are secreted via the Xcp system under the growth conditions tested, and that an alternative secretion system is operative. To obtain some insight into the secretory pathway involved, the amino acid sequence of the N-terminus of the major extracellular protein was determined. The protein could be identified as flagellin. Mutations in thexcpQ andR genes ofP. aeruginosa could not be complemented by introduction of the correspondingxcp genes ofP. putida. However, expression of a hybrid XcpR protein, composed of the N-terminal one-third ofP. aeruginosa XcpR and the C-terminal two-thirds ofP. putida XcpR, did restore protein secretion in aP. aeruginosa xcpR mutant.     

Partial Deletion of both the Spermine Synthase Gene and thePexGene in the X-linked Hypophosphatemic, Gyro (Gy) Mouse

Gy, along withHyp, is a dominant mutation of the normal genePexcausing X-linked hypophosphatemia in the mouse. HemizygousGymale mice, however, have greater defects in survival, bodily growth, skeletal mineralization, and neurological function than those found in heterozygousGyfemales or inHypmice. Since the gene for spermine synthase is immediately upstream of the homologous human genePEX, we compared the effects of theGyandHypmutations on both the spermine synthase gene and thePexgene. Barely detectable levels of spermine (<5 % of normal) with elevated levels of its precursor, spermidine, were found in organs ofGymale mice compared to normal male littermates. NeitherGyfemales norHypmale mice were significantly affected. Four missing introns of the spermine synthase gene were identified inGymale mice, suggesting extensive gene disruption. A pseudogene for spermine synthase was also identified in the mouse genome.PexmRNA was found in several but not all tissues studied in adult normal mice.PexmRNA was altered in bothGyandHypmice. All maleHypmice were lacking the 3′ end of thePexmessage, whereas all maleGymice were deficient at the 5′ end. In summary, theGymutation is associated with a recessively expressed mutation of the spermine synthase gene, leading to spermine deficiency, and a dominantly expressed mutation of thePexgene, leading to hypophosphatemia. Alterations in two contiguous genes inGymay explain the additional phenotypic abnormalities present in theGymale mouse.     

S-related protein can be recombined with self-compatibility in interspecific derivatives ofLycopersicon

Stylar proteins involved in the self-incompatible (SI) response ofLycopersicon hirsutum have been identified and mapped to the locus that controls SI (S locus).L. esculentum, a self-compatible (SC) species of cultivated tomato, does not display these proteins. Hybrids between SCL. esculentum and SIL. hirsutum are self-sterile despite these individuals bearing pollen containing theS allele ofL. esculentum. In progeny derived from backcrossing the hybrids toL. esculentum, there was a strong correlation between the presence of theS allele fromL. hirsutum and self-infertility. However, this relationship was uncoupled in a number of backcross (BC) progeny. The SI response appeared to be nonexistent in two self-fertile BC individuals that were heterozygous for theS allele ofL. hirsutum, based on Mendelian segregation of a tightly linked DNA marker,CD15, in selfed progeny. Among these progeny self-fertile individuals that were homozygous for theL. hirsutum allele of the linked marker were also determined to be homozygous for anS-related protein ofL. hirsutum through test crosses withL. esculentum. Therefore, plants were produced that were homozygous for a functionalS allele but were self-fertile. This result and other evidence suggest that theS-related proteins are not sufficient to elicit a self-incompatible response inL. esculentum and that there is a mutation(s) inL. esculentum somewhere other than theS locus that leads to self-compatibility.     

Cloning of the polyketide synthase gene atX from Aspergillus terreus and its identification as the 6-Methylsalicylic acid synthase gene by heterologous expression

The geneCAL1 (also known asCDC43) ofSaccharomyces cerevisiae encodes the subunit of geranylgeranyl transferase I (GGTase I), which modifies several small GTPases. Biochemical analyses of the mutant enzymes encoded bycall-1, andcdc43-2 tocdc43-7, expressed in bacteria, have shown that all of the mutant enzymes possess reduced activity, and that none shows temperature-sensitive enzymatic activities. Nonetheless, all of thecall/cdc43 mutants show temperature-sensitive growth phenotypes. Increase in soluble pools of the small GTPases was observed in the yeast mutant cells at the restrictive temperature in vivo, suggesting that the yeast prenylation pathway itself is temperature sensitive. Thecall-1 mutation, located most proximal to the C-terminus of the protein, differs from the othercdc43 mutations in several respects. An increase in soluble Rholp was observed in thecall-1 strain grown at the restrictive temperature. The temperature-sensitive phenotype ofcall-1 is most efficiently suppressed by overproduction of Rholp. Overproduction of the other essential target, Cdc42p, in contrast, is deleterious incall-1 cells, but not in othercdc43 mutants or the wild-type strains. Thecdc43-5 mutant cells accumulate Cdc42p in soluble pools andcdc43-5 is suppressed by overproduction of Cdc42p. Thus, several phenotypic differences are observed among thecall/cdc43 mutations, possibly due to alterations in substrate specificity caused by the mutations.     

A vital function for mitochondrial DNA in the petite-negative yeastKluyveromyces lactis

Petite-negative yeasts do not form viable respiratory-deficient mutants on treatment with DNA-targeting drugs that readily eliminate the mitochondial DNA (mtDNA) from petite-positive yeasts. However, in the petite-negative yeastKluyveromyces lactis, specific mutations in the nuclear genesMGI2 andMGI5 encoding the- and-subunits of the mitochondrial F₁-ATPase, allow mtDNA to be lost. In this study we show that wild-typeK. lactis does not survive in the absence of its mitochondrial genome and that the function ofmgi mutations is to suppress lethality caused by loss of mtDNA. Firstly, we find that loss of a multicopy plasmid bearing amgi allele readily occurs from a wild-type strain with functional mtDNA but is not tolerated in the absence of mtDNA. Secondly, we cloned theK. lactis homologue of theSaccharomyces cerevisiae mitochondrial genome maintenance geneMGM101, and disrupted one of the two copies in a diploid. Following sporulation, we find that segregants containing the disrupted gene form minicolonies containing 6-8000 inviable cells. By contrast, disruption ofMGM101 is not lethal in a haploidmgi strain with a specific mutation in a subunit of the mitochondrial F₁-ATPase. These observations suggest that mtDNA inK. lactis encodes a vital function which may reside in one of the three mitochondrially encoded subunits of F₀.     

Genetic factors affecting allelic recombination at the histidine-3 locus ofNeurospora crassa

Summary In addition to the generec-4, other genetic factors affect the frequency of allelic recombination in thehis-3 locus. One dominant factor, designated asrec-6 ⁺, in association withrec-4 ⁺ causes greater reduction in prototrophic frequency than obtained withrec-4 ⁺ alone. The action ofrec 6 ⁺ in crosses recessive homozygous forrec-4 is not established at the present. The effect ofrec-6 ⁺ is recognised only with onehis-3 allele but not with another. Interaction ofrec-4 ⁺ orrec-4 with other genetic factors can give approximately ten fold variation in the prototrophic frequencies obtained with a pair of alleles. It is suggested that the control of the rate of mutations during meiosis might be one of the roles of the recombination genes.     

Interaction of alleles of therelA, relC andspoT genes inEscherichia coli: Analysis of the interconversion of GTP, ppGpp and pppGpp

Summary Mutants in thespoT gene have been isolated as stringent second site revertants of therelC mutation. These show varying degrees of the characteristics associated with thespoT1 gene,viz relative amount and absolute levels of both pppGpp and ppGpp and the decay rate of the latter. The entry of³H-guanosine into GTP and ppGpp pools inspoT ⁺ andspoT1 cells either growing exponentially or during amino acid starvation was determined, and the rate of ppGpp synthesis and its decay constant calculated. During exponential growth the ppGpp pool is 2-fold higher, its decay constant 10-fold lower, and its synthesis rate 5-fold lower inspoT ^- than inspoT ⁺ cells; during amino acid starvation the ppGpp pool is 2-fold higher, its decay constant 20-fold lower, and its synthesis rate 10-fold lower inspoT than inspoT ⁺ cells. In one of the “intermediate”spoT mutants the rate of entry of³H-guanosine into GTP, ppGpp and pppGpp was measured during amino acid starvation. The data form the basis of a model for the interconversion of the guanosine nucleotides in which the flow is:GDP→GTP→pppGpp→ppGpp→Y. Calculations of the rates of synthesis and conversion of pppGpp and ppGpp under various conditions in variousspoT ⁺ andspoT ^- strains indicate that the ppGpp concentration indirectly controls the rate of pppGpp synthesis. ThespoT1 allele was introduced into various relaxed mutants. It was shown that many phenomena associated with the relaxed response ofrelC and “intermediate”relA mutants were phenotypically suppressed when thespoT1 allele was introduced into these mutants. These double mutants exhibit ppGpp accumulation, rate of RNA accumulation, rate of β-galactosidase synthesis, and heat lability of β-galactosidase synthesized during amino acid starvation similar to the stringent wild-type. It is concluded that the relaxed response is due directly to the lack of ppGpp and that the stringest response is due directly to ppGpp.     

Genes conferring late flowering inArabidopsis thaliana

Three naturally occurring late flowering, vernalization responsive ecotypes ofArabidopsis thaliana, Pitztal, Innsbruck and Kiruna-2, were each crossed with the early flowering ecotypes of Landsbergerecta, Columbia and Niederzenz. Analysis of the subsequent generations suggested that late flowering in Kiruna-2 is recessive and mainly determined by a single, late flowering gene. This late flowering gene is not, however, the same as that in any of the late flowering mutants generated in the Landsbergerecta background. Both Pitztal and Innsbruck appear to contain the same dominant gene which confers late flowering to these ecotypes. The early flowering parents Niederzenz and Landsberg both contain genes which modify the phenotype of this dominant late flowering locus, causing F₁ plants to flower either earlier (Landsberg) or later (Niederzenz) than the late parent. Mapping of the dominant late flowering locus from Pitztal demonstrated that late flowering co-segregated with an RFLP marker from one end of chromosome 4. This is a similar position to that ofFLA, the gene responsible for late flowering of theArabidopsis ecotypes Sf-2 and Le-O.     

A comparison of symbiotic nitrogen fixation in Scotland inAlnus glutinosa andAlnus rubra

Summary Alnus glutinosa andAlnus rubra growing in the field in Scotland show specific nitrogenase activities of the same order of magnitude. The period of maximum potential nitrogenase activity coincides with that of maximum growth in late Spring and Summer. It is suggested that the retention of nitrogenase activity into the Autumn when growth has virtually ceased may be important as a contribution to the nitrogenous reserves of the tree.Bioassay of different Scottish soils, all collected from the locality of natural stands ofAlnus glutinosa, showed wide variation in the nodulation of seedlings, although generally a soil poor for nodulation ofAlnus glutinosa generally gave poor nodulation ofAlnus rubra. Soils of pH 4.5 to 6.5, best suited for growth and nitrogen fixation of the two species, often gave nodules showing highest specific nitrogen fixing activity. Young (2 to 3 year old) plants in glasshouse or controlled environment cabinet, inoculated withAlnus glutinosa endophyte, differed from mature field grown plants, however, sinceAlnus rubra required a much larger (up to 2.5 times) mass of root nodules to fix a unit quantity of N. Microscopic comparison of the nodules of glasshouse plants showed that the proportion of cells containing the vesicular (nitrogen fixing) form of the endophyte was only slightly lower inAlnus rubra than inAlnus glutinosa and it is suggested that the differences in specific nitrogen fixing activity between the two species may reflect some incompatibility of function of theAlnus glutinosa endophyte when in symbiosis withAlnus rubra.     

拟南芥At1g10300基因调节叶形和开花时间

核仁G蛋白1(Nucleolar G protein 1,NOG1)是一种高度保守的核仁GTP酶,在真核生物中广泛存在,参与60 S核糖体亚基前体的组装。在线虫中敲减NOG1的表达造成生长缓慢、虫体变小和寿命延长的表型,而过量表达NOG1则使线虫的寿命缩短。拟南芥的At1g10300基因注释为NOG1-2,但是其生物学功能还有待研究。该研究对其功能进行了初步研究,首先检测了该基因在拟南芥各个器官的表达情况。结果表明:该基因在7 d龄幼苗、茎生叶和花中均有表达,其中在花中表达量最高。获得了At1g10300基因的T-DNA插入突变体,发现在长日照条件下,At1g10300突变体植株的莲座紧凑,莲座叶片长宽比降低,但叶面积和植株高度与野生型相比无显著差异,表明其叶形发生改变;突变体植株的抽薹时间晚于野生型。荧光定量RT-PCR结果表明,突变体植株中开花促进因子FT、CO和GI的表达水平下调,而开花抑制因子FLC的表达水平上调。以上结果揭示At1g10300基因的突变影响了FT、CO、GI及FLC基因的表达,使植株出现晚花表型。