BIN2/DWF12 Antagonistically Transduces Brassinosteroid and Auxin Signals in the Roots of <Emphasis Type="Italic">Arabidopsis</Emphasis>

Plant growth-stimulating hormones brassinosteroids (BRs) function via interactions with other hormones. However, the mechanism of these interactions remains to be elucidated. The unique phenotypes of brassinosteroid insensitive2/dwarf12-D (bin2/dwf12-D) mutants, such as twisted inflorescences and leaves, suggested that BIN2, a negative regulator of BR signaling, may be involved in auxin signaling. Furthermore, previously, we showed that auxin stimulates DWF4 expression. To determine the possible role of BIN2/DWF12 in Auxin signaling, we measured DWARF4pro:GUS activity through both GUS histochemical staining and in vivo GUS assay. We found that the GUS activity in the bin2/dwarf12-1D background dramatically increased relative to control. In addition, the number of lateral roots (LR) in bin2/dwf12-1D was greater than wild type, and the optimal concentration for auxin-mediated lateral root induction was lower in bin2/dwf12-1D; these findings suggest that BIN2 plays a positive role in auxin signaling. In contrast, ABA repressed both DWF4pro:GUS expression and lateral root development. However, the degree of repression was lower in bin2/dwf12-1D background, suggesting that BIN2 plays a role in ABA-mediated DWF4pro:GUS expression and subsequently in lateral root development, too. Therefore, it is likely that BIN2 plays a role of signal integrator for multiple hormones, such as BRs, auxin, and ABA.     

Arabidopsis brassinosteroid-insensitive dwarf12 mutants are semidominant and defective in a glycogen synthase kinase 3beta-like kinase

Mutants defective in the biosynthesis or signaling of brassinosteroids (BRs), plant steroid hormones, display dwarfism. Loss-of-function mutants for the gene encoding the plasma membrane-located BR receptor BRI1 are resistant to exogenous application of BRs, and characterization of this protein has contributed significantly to the understanding of BR signaling. We have isolated two new BR-insensitive mutants (dwarf12-1D and dwf12-2D) after screening Arabidopsis ethyl methanesulfonate mutant populations. dwf12 mutants displayed the characteristic morphology of previously reported BR dwarfs including short stature, short round leaves, infertility, and abnormal de-etiolation. In addition, dwf12 mutants exhibited several unique phenotypes, including severe downward curling of the leaves. Genetic analysis indicates that the two mutations are semidominant in that heterozygous plants show a semidwarf phenotype whose height is intermediate between wild-type and homozygous mutant plants. Unlike BR biosynthetic mutants, dwf12 plants were not rescued by high doses of exogenously applied BRs. Like bri1 mutants, dwf12 plants accumulated castasterone and brassinolide, 43- and 15-fold higher, respectively, providing further evidence that DWF12 is a component of the BR signaling pathway that includes BRI1. Map-based cloning of the DWF12 gene revealed that DWF12 belongs to a member of the glycogen synthase kinase 3beta family. Unlike human glycogen synthase kinase 3beta, DWF12 lacks the conserved serine-9 residue in the auto-inhibitory N terminus. In addition, dwf12-1D and dwf12-2D encode changes in consecutive glutamate residues in a highly conserved TREE domain. Together with previous reports that both bin2 and ucu1 mutants contain mutations in this TREE domain, this provides evidence that the TREE domain is of critical importance for proper function of DWF12/BIN2/UCU1 in BR signal transduction pathways.     

Genetic and physical mapping inBrassica diploid species of a gene cluster defined inArabidopsis thaliana

We report the genetic and physical analysis by pulse field gel electrophoresis (PFGE) in threeBrassica diploid genomes for a cluster of five genes characterized in a selected segment of 15 kb on chromosome 3 ofArabidopsis thaliana, encoding aBradyrhizobium CycJ homologue (At1), a rat p67 translation factor homologue (At2), an Em-like (early methionine) protein (At3), chlorophyll synthase (At4) and a yeast Sac1 homologue (A5). TheArabidopsis gene array was found to be conserved on a single linkage group in each of theBrassica genomes. However, partial complexes were found to be duplicated in other chromosome segments on the same or other linkage groups. Some of the At genes, which could not be genetically mapped because of lack of polymorphism, were assigned to their respective linkage groups by physical mapping. The presence of multiple copies of theA. thaliana gene cluster in the threeBrassica genomes further establishes their complex nature, which results from extensive duplication and chromosomal rearrangement. In general, genetic distances between the At genes agreed with values expected for the physical distances determined inBrassica.     

The DWF4 gene of Arabidopsis encodes a cytochrome P450 that mediates multiple 22alpha-hydroxylation steps in brassinosteroid biosynthesis.

dwarf4 (dwf4) mutants of Arabidopsis display a dwarfed phenotype due to a lack of cell elongation. Dwarfism could be rescued by the application of brassinolide, suggesting that DWF4 plays a role in brassinosteroid (BR) biosynthesis. The DWF4 locus is defined by four mutant alleles. One of these is the result of a T-DNA insertion. Plant DNA flanking the insertion site was cloned and used as a probe to isolate the entire DWF4 gene. Sequence analysis revealed that DWF4 encodes a cytochrome P450 monooxygenase with 43% identity to the putative Arabidopsis steroid hydroxylating enzyme CONSTITUTIVE PHOTOMORPHOGENESIS AND DWARFISM. Sequence analysis of two other mutant alleles revealed deletions or a premature stop codon, confirming that DWF4 had been cloned. This sequence similarity suggests that DWF4 functions in specific hydroxylation steps during BR biosynthesis. In fact, feeding studies utilizing BR intermediates showed that only 22alpha-hydroxylated BRs rescued the dwf4 phenotype, confirming that DWF4 acts as a 22alpha-hydroxylase.     

Identification, fine mapping and characterisation of a dwarf mutant (bnaC.dwf) in Brassica napus

In the present study, we have obtained one dwarf mutant (bnaC.dwf) from the Brassica napus inbred line T6 through chemical mutagen ethyl methanesulfonate (EMS). We have determined the phenotypic effects and genetic characteristics of dwarf mutant (bnaC.dwf). The dwarf mutant was insensitive to exogenous GA(3) for plant height, suggesting that it is significantly playing a crucial role in the gibberellins response pathway. Genetic analysis revealed that one recessive gene is responsible for controlling the phenotypic expression of dwarf mutant. Amplified Fragment Length Polymorphism (AFLP) technique was applied for selecting markers linked to the BnaC.DWF gene which assisted in screening of dwarf and normal individuals in the BC(4) population. We have screened 1,024 primer combinations and then identified nine AFLP markers linked to the BnaC.DWF gene. Identification and linkage of the markers were carried out by analysing 2,000 individuals from a larger population of the BC(4). Two markers EA10MC09 and EA12MC02 were located on the flanking region of the BnaC.DWF gene at a distance of 0.2 and 0.05 cM, respectively. Four AFLP markers EA09MG05, EA02MC07, EA01MC01 and EC04MC07 were successfully converted into Sequence Characterised Amplified Region markers namely SCA9G5, SCA2C7, SCA1C1 and SCC4C7. We further integrated BnaC.DWF linked Simple Sequence Repeat markers into two populations (Piquemal et al. Theor Appl Genet 111:1514-1523, 2005; Cheng et al. Theor Appl Genet 118:1121-1131, 2009). BnaC.DWF was mapped to the linkage region N18. The molecular markers developed from these investigations will greatly accelerate the selection process for developing dwarf varieties in B. napus by Marker Assisted Selection and genetic engineering.     

Dwarf mutants ofBrassica: Responses to applied gibberellins and gibberellin content

Eight rapid-cyclingBrassica genotypes differing in height were treated with gibberellins (GAs) by syringe application to the shoot tip. The height of two genotypes ofBrassica napus, Bn5-2 and Bn5-8, andB. rapa mutants,dwarf 1 (dwf1) anddwarf 2 (dwf2), was unaffected by exogenous GA₃ at dosages up to 0.1 g/plant, a level which increased shoot elongation of normal genotypes. Thus, these dwarf mutants are GA-insensitive. In contrast to theB. napus dwarfs, twoB. rapa mutants,rosette (ros), anddormant (dor), elongated following GA₃ application. The dwarfros was most sensitive, responding to applications as low as 1 ng GA₃/plant. Furthermore,ros also responded to GA₁ and some of its precursors with decreasing efficacy: GA₃>ent-kaurenoic acid GA₁>GA₂₀GA₁₉=GA₄₄GA₅₃. Endogenous GAs were measured by gas chromatography-selected ion monitoring using [²H₂]GA internal standards for calibration, from shoots of the GA-insensitive genotypes Bn5-2, Bn5-8 which contained theB. napus mutantdwarf 1, and from a normal genotype Bn5-1. Concentrations of GA₁ and GA₂₀ averaged 3.2- and 4.6-fold higher, respectively, and GA₁₉ levels also tended to be higher in the dwarfs than in the normal genotype.     

The Bacillus subtilis small cytoplasmic RNA gene and ''dnaX'' map near the chromosomal replication origin.

Summary TheBacillus subtilis small cytoplasmic RNA (scRNA) has an important, although not yet defined function in protein biosynthesis. Here we describe the mapping of the single copy scRNA gene and the flanking homolog todnaZX ofEscherichia coli, termed dnaX. The scRNA gene region of aB. subtilis wild-type strain was marked with acat gene and mapped by scoring chromosomal co-transformation rates of various mutant strains to chloramphenicol resistance and loss of the mutant phenotypes, respectively. This analysis, together with anEcoRI map comparison, places the scRNA gene anddnaX in the vicinity ofrecM near the replication origin region ofB. subtilis.     

Genetic and physical mapping inBrassica diploid species of a gene cluster defined inArabidopsis thaliana

We report the genetic and physical analysis by pulse field gel electrophoresis (PFGE) in threeBrassica diploid genomes for a cluster of five genes characterized in a selected segment of 15 kb on chromosome 3 ofArabidopsis thaliana, encoding aBradyrhizobium CycJ homologue (At1), a rat p67 translation factor homologue (At2), an Em-like (early methionine) protein (At3), chlorophyll synthase (At4) and a yeast Sac1 homologue (A5). TheArabidopsis gene array was found to be conserved on a single linkage group in each of theBrassica genomes. However, partial complexes were found to be duplicated in other chromosome segments on the same or other linkage groups. Some of the At genes, which could not be genetically mapped because of lack of polymorphism, were assigned to their respective linkage groups by physical mapping. The presence of multiple copies of theA. thaliana gene cluster in the threeBrassica genomes further establishes their complex nature, which results from extensive duplication and chromosomal rearrangement. In general, genetic distances between the At genes agreed with values expected for the physical distances determined inBrassica.     

The Rice brassinosteroid-deficient dwarf2 mutant, defective in the rice homolog of Arabidopsis DIMINUTO/DWARF1, is rescued by the endogenously accumulated alternative bioactive brassinosteroid, dolichosterone

We have identified a rice (Oryza sativa) brassinosteroid (BR)-deficient mutant, BR-deficient dwarf2 (brd2). The brd2 locus contains a single base deletion in the coding region of Dim/dwf1, a homolog of Arabidopsis thaliana DIMINUTO/DWARF1 (DIM/DWF1). Introduction of the wild-type Dim/dwf1 gene into brd2 restored the normal phenotype. Overproduction and repression of Dim/dwf1 resulted in contrasting phenotypes, with repressors mimicking the brd2 phenotype and overproducers having large stature with increased numbers of flowers and seeds. Although brd2 contains low levels of common 6-oxo-type BRs, the severity of the brd2 phenotype is much milder than brd1 mutants and most similar to d2 and d11, which show a semidwarf phenotype at the young seedling stage. Quantitative analysis suggested that in brd2, the 24-methylene BR biosynthesis pathway is activated and the uncommon BR, dolichosterone (DS), is produced. DS enhances the rice lamina joint bending angle, rescues the brd1 dwarf phenotype, and inhibits root elongation, indicating that DS is a bioactive BR in rice. Based on these observations, we discuss an alternative BR biosynthetic pathway that produces DS when Dim/dwf1 is defective.     

Cloning of a putative monogalactosyldiacylglycerol synthase gene from rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.) plants and its expression in response to submergence and other stresses

Suppression subtractive hybridization was used to construct a subtractive cDNA library from plants of non-submerged and 7-day-submerged rice (Oryza sativa L., FR13A, a submergence-tolerant cultivar). One clone of the subtractive cDNA library, S23, was expressed abundantly during submergence. The full length of S23 was amplified using 5- and 3-rapid amplification of cDNA ends, and found to consist of 1,671 bp with an open reading frame of 1,077 bp (181–1257) encoding 358 amino acids. Its deduced amino acid sequence showed a high homology with monogalactosyldiacylglycerol synthase (UDPgalactose: 1,2-diacylglycerol 3--d-galactosyl transferase; EC 2.4.1.46, MGDG synthase) from Arabidopsis thaliana; therefore, we named the gene OsMGD. Time-course studies showed that the expression of OsMGD in the rice cultivars FR13A and IR42 (submergence-susceptive cultivar) during submergence was gradually increased and that expression in FR13A was higher than in IR42. The expression of OsMGD in FR13A was influenced by benzyladenine and illumination. The accumulation of OsMGD mRNA in both FR13A and IR42 was also increased by ethephon, gibberellin, drought and salt treatment, but cold stress had no effect on the expression of the gene. These results suggest that the expression of OsMGD mRNA requires benzyladenine or illumination, and that the process is also mediated by ethephon and gibberellin. Salt and drought stress have an effect similar to that of submergence. Furthermore, the enhanced expression of OsMGD may relate to photosynthesis, and play an important role during submergence.Abbreviations BA N⁶-Benzyladenine - GA Gibberellin - MGD Monogalactosyldiacylglycerol synthase - RACE Rapid amplification of cDNA ends     

High Temperature Stimulates <Emphasis Type="Italic">DWARF4 (DWF4)</Emphasis> Expression to Increase Hypocotyl Elongation in <Emphasis Type="Italic">Arabidopsis</Emphasis>

Hypocotyl growth occurs as a result of an interaction between environmental factors and endogenous phytohormones. In Arabidopsis, high temperature promotes auxin synthesis to increase hypocotyl growth. We previously showed that exogenously provided auxin stimulates expression of the brassinosteroid (BR) biosynthetic gene DWARF4. To determine whether temperature-induced hypocotyl elongation depends on BR biosynthesis, we examined the morphological responses to high temperature and the expression pattern of DWF4pro:GUS in different genetic backgrounds, which are as follows: Ws-2 wild-type, iaa19/msg2, bri1-5, and dwf7-1. In contrast to the wild-type, growth of the three genotypes at 29°C did not significantly increase hypocotyl length; whereas, with the exception of iaa19/msg2, the roots were elongated. These results confirm that BR biosynthesis and signaling pathways are required for hypocotyl growth at high temperature. Furthermore, a GUS histochemical assay revealed that a temperature of 29°C greatly increased DWF4pro:GUS expression in the shoot and root tips compared to a temperature of 22°C. Quantitative measurements of GUS activity in DWF4pro:GUS revealed that growth at 29°C is similar to the level of growth after addition of 100 nM IAA to the medium. Our results suggest that temperature-dependent synthesis of free auxin stimulates BR biosynthesis, particularly via the key biosynthetic gene DWF4, and that the BRs thus synthesized are involved in hypocotyl growth at high temperature.     

Inhibition of growth by ancymidol and tetcyclacis in the gibberellin-deficientdwarf-5 mutant ofZea mays L. and its prevention by exogenous gibberellin

Leaf sheath length and shoot dry matter of the gibberellin-deficientdwarf-5 mutant ofZea mays L. were further reduced by micromolar concentrations of two putative gibberellin biosynthesis inhibitors, ancymidol [-cyclopropyl--(p-methoxyphenyl)-5-pyrimidine methyl alcohol] and tetcyclacis [5-(4-chlorophenyl)-3,4,5,9,10-pentaazatetracyclo-5,4,1,0^2,6,0^8,11-dodeca-3,9-diene]. Growth retardant action was prevented by the subsequent application of gibberellin (GA₄₊₇). Plants treated with both gibberellin and growth retardants were identical in all outward respects to those treated with gibberellin alone. Although thedwarf-5 mutant is blocked in the synthesis ofent-kaurene and does not contain detectable quantities of gibberellin, the above results are consistent with the interpretation that biologically active levels of endogenous gibberellin are present in the dwarf which can be decreased by biosynthesis inhibitors.Mention of a trademark or proprietary product does not constitute a guarantee or warranty of the product by the United States Department of Agriculture and does not imply its approval to the exclusion of other products that may also be suitable.     

Induced expression of the Aspergillus nidulans QUTE gene introduced by transformation into Neurospora crassa

Summary Theqa-2 gene ofNeurospora crassa encodes catabolic dehydroquinase which catabolizes dehydroquinic acid to dehydroshikimic acid. TheQUTE gene ofAspergillus nidulans corresponds to theqa-2 gene ofN. crassa. The plasmid pEH1 containing theQUTE gene fromA. nidulans was used to transform aqa-2 ^– strain ofN. crassa. In Southern blot analyses, DNAs isolated from these transformants hybridized specifically to theQUTE gene probe. Northern blot analyses indicated thatQUTE mRNA was produced in the transformants. The functional integrity of theQUTE gene inN. crassa was indicated by transformants which had regained the ability to grow on quinic acid as sole carbon source. Enzyme assays indicated that the specific activities of catabolic dehydroquinase induced by quinic acid in the transformants ranged from 4% to 32% of that induced in wild-typeN. crassa. The evidence that theQUTE structural gene ofA. nidulans is inducible when introduced into theN. crassa genome implies that theN. crassa qa activator protein can recognize, at least to a limited extent, DNA binding sequences 5 to theQUTE gene.     

Thi1, a thiamine biosynthetic gene inArabidopsis thaliana, complements bacterial defects in DNA repair

AnArabidopsis thaliana cDNA was isolated by complementation of theEscherichia coli mutant strain BW535 (xth, nfo, nth), which is defective in DNA base excision repair pathways. This cDNA partially complements the methyl methane sulfonate (MMS) sensitive phenotype of BW535. It also partially corrects the UV-sensitive phenothpe ofE. coli AB1886 (uvrA) and restores its ability to reactivate UV-irradiated phage. It has an insert of ca. 1.3 kb with an open reading frame of 1047 bp (predicting a protein with a molecular mass of 36 kDa). This cDNA presents a high homology to a stress related gene from two species ofFusarium (sti35) and to genes whose products participate in the thiamine biosynthesis pathway,THI4, fromSaccharomyces cerevisiae andnmt2 fromSchizosaccharomyces pombe. TheArabidopsis predicted polypeptide has homology to several protein motifs: amino-terminal chloroplast transit peptide, dinucleotide binding site, DNA binding and bacterial DNA polymerases. The auxotrophy for thiamine in the yeastthi4::URA3 disruption strain is complemented by theArabidopsis gene. Thus, the cloned gene, namedthi1, is likely to function in the biosynthesis of thiamine in plants. The data presented in this work indicate thatthi1 may also be involved in DNA damage tolerance in plant cells.Depto. de Microbiologia, Instituto de Ciências Biomédicas, Universidade de São Paulo     

Recombination protein A gene,recA, fromSpirulina platensis IAM-M135

We report the cloning and sequencing of therecA gene fromSpirulina platensis. A genomic library ofSpirulina was constructed in pUC19 and screened by PCR using oligonucleotides corresponding to the conserved amino acid sequences ofAnabaena variabilis andSynechococcus RecA proteins. TheSpirulina recA gene consists of an open reading frame (ORF) of 1095 nucleotides encoding a protein (365 residues) which shares an identity of 79%, 70% and 57% with the RecA proteins ofAnabaena variabilis, Synechococcus andEscherichia coli respectively. TherecA gene is located close to one end of the clonedBglII fragment and has only 53 bp of 5 nucleotides. The isolation of this gene has implications for the development of gene transfer system(s) forSpirulina.     

Volatiles released from cotton plants in response to<Emphasis Type="Italic"> Helicoverpa zea</Emphasis> feeding damage on cotton flower buds

Feeding of Helicoverpa zea larvae on cotton (Gossypium hirsutum L.) flower buds (squares) for 24 or 48 h induced the release of a number of terpenes [(E)--ocimene, linalool, (E)--farnesene, (E,E)--farnesene, (E)-4,8-dimethyl-1,3,7-nonatriene, (E,E)-4,8,12-trimethyl-1,3,7,11-tridecatetraene], isomeric hexenyl butyrates, 2-methylbutyrates, indole and (Z)-3-hexenyl acetate. These compounds are not released in significant amounts from undamaged squares and freshly damaged squares. The release of inducible compounds was not limited to the damaged squares themselves. The compounds were also released systemically from the upper undamaged leaves of the same plant after 72 h. However, the composition of the blend of systemically released volatiles differed from the blend released by damaged squares. The compounds that were systemically released from undamaged leaves in response to feeding on the squares were (Z)-3-hexenyl acetate, (E)--ocimene, linalool, (E)-4,8-dimethyl-1,3,7-nonatriene, (E)--farnesene, (E,E)--farnesene, and indole. This study shows that insect damage inflicted to the reproductive parts of a plant causes a systemic emission of volatiles from its vegetative parts.     

<Emphasis Type="Italic">CaVIL1</Emphasis>, a plant homeodomain gene that promotes flowering in pepper

Key message

CaVIL1 is a homolog of VIL1, a regulator of vernalization response in Arabidopsis and acts as a flowering promoter in pepper which does not respond to vernalization and photoperiod.

Abstract

As part of our goal to study the genetic and molecular basis of transition to flowering in pepper, we isolated the late-flowering mutant E-2698. Aside from late flowering, multiple pleiotropic alterations of the shoot structure, such as enlarged and distorted leaves, weak apical dominance, and reduced angle of the lateral branches were observed, indicating a broad role for the mutated gene in pepper development. Genetic mapping and sequence analyses revealed that the disrupted gene in E-2698 is the pepper homolog of VERNALIZATION INSENSITIVE 3-LIKE 1 (VIL1) that acts as a regulator of vernalization in Arabidopsis through chromatin modification. The pepper gene, CaVIL1, contains a plant homeodomain motif associated with chromatin modification and a VERNALIZATION INSENSITIVE 3-interacting domain that is truncated in E-2698 and in two other allelic mutants. Because pepper flowering does not respond to vernalization, we postulate that CaVIL1 regulates flowering time via chromatin modification of unknown targets. Expression analysis indicated that CaVIL1 activates the flowering promoter CaFLOWERING LOCUS T and represses the flowering repressor CaAPETALA2. Furthermore, CaVIL1 represses several genes from the FLOWERING LOCUS C (FLC)-LIKE clade that are clustered together in the pepper genome. This indicates their possible involvement in flowering regulation in this species. Our results show that CaVIL1 is a major regulator of flowering and interacts with other flowering promoters and repressors, as well as with FLC-LIKE genes whose function in flowering regulation is not yet known in pepper.

     

PWP2, a member of the WD-repeat family of proteins, is an essentialSaccharomyces cerevisiae gene involved in cell separation

WD-repeat proteins contain four to eight copies of a conserved motif that usually ends with a tryptophan-aspartate (WD) dipeptide. TheSaccharomyces cerevisiae PWP2 gene, identified by sequencing of chromosome III, is predicted to contain eight so-called WD-repeats, flanked by nonhomologous extensions. This gene is expressed as a 3.2-kb mRNA in all cell types and encodes a protein of 104 kDa. ThePWP2 gene is essential for growth because spores carrying thepwp21::HIS3 disruption germinate before arresting growth with one or two large buds. The growth defect ofpwp21::HIS3 cells was rescued by expression ofPWP2 or epitope-taggedHA-PWP2 using the galactose-inducibleGAL1 promoter. In the absence of galactose, depletion of Pwp2p resulted in multibudded cells with defects in bud site selection, cytokinesis, and hydrolysis of the septal junction between mother and daughter cells. In cell fractionation studies, HA-Pwp2p was localized in the particulate component of cell lysates, from which it would be solubulized by high salt and alkaline buffer but not by nonionic detergents or urea. Indirect immunofluorescence microscopy indicated that HA-Pwp2p was clustered at multiple points in the cytoplasm. These results suggest that Pwp2p exists in a proteinaceous complex, possibly associated with the cytoskeleton, where it functions in control of cell growth and separation.