The brassinosteroid growth response in pea is not mediated by changes in gibberellin content

The objective of this study was to increase our understanding of the relationship between brassinosteroids (BRs) and gibberellins (GAs) by examining the effects of BR deficiency on the GA biosynthesis pathway in several tissue types of pea (Pisum sativum L.). It was suggested recently that, in Arabidopsis, BRs act as positive regulators of GA 20-oxidation, a key step in GA biosynthesis [Bouquin et al. (2001) Plant Physiol 127:450–458]. However, this may not be the case in pea as GA₂₀ levels were consistently higher in all shoot tissues of BR-deficient (lk and lkb) and BR-response (lka) mutants. The application of brassinolide (BL) to lkb plants reduced GA₂₀ levels, and metabolism studies revealed a reduced conversion of GA₁₉ to GA₂₀ in epi-BL-treated lkb plants. These results indicate that BRs actually negatively regulate GA₂₀ levels in pea. Although GA₂₀ levels are affected by BR levels, this does not result in consistent changes in the level of the bioactive GA, GA₁. Therefore, even though a clear interaction exists between endogenous BR levels and the level of GA₂₀, this interaction may not be biologically significant. In addition to the effect of BRs on GA levels, the effect of altered GA₁ levels on endogenous BR levels was examined. There was no significant difference in BR levels between the GA mutants and the wild type (wt), indicating that altered GA₁ levels have no effect on BR levels in pea. It appears that the BR growth response is not mediated by changes in bioactive GA levels, thus providing further evidence that BRs are important regulators of stem elongation.     

The Arabidopsis DIMINUTO/DWARF1 gene encodes a protein involved in steroid synthesis.

We have identified the function of the Arabidopsis DIMINUTO/DWARF1 (DIM/DWF1) gene by analyzing the dim mutant, a severe dwarf with greatly reduced fertility. Both the mutant phenotype and gene expression could be rescued by the addition of exogenous brassinolide. Analysis of endogenous sterols demonstrated that dim accumulates 24-methylenecholesterol but is deficient in campesterol, an early precursor of brassinolide. In addition, we show that dim is deficient in brassinosteroids as well. Feeding experiments using deuterium-labeled 24-methylenecholesterol and 24-methyldesmosterol confirmed that DIM/DWF1 is involved in both the isomerization and reduction of the Delta24(28) bond. This conversion is not required in cholesterol biosynthesis in animals but is a key step in the biosynthesis of plant sterols. Transient expression of a green fluorescent protein-DIM/DWF1 fusion protein and biochemical experiments showed that DIM/DWF1 is an integral membrane protein that most probably is associated with the endoplasmic reticulum.     

Brassinosteroid/Sterol synthesis and plant growth as affected by lka and lkb mutations of Pea

The dwarf pea (Pisum sativum) mutants lka and lkb are brassinosteroid (BR) insensitive and deficient, respectively. The dwarf phenotype of the lkb mutant was rescued to wild type by exogenous application of brassinolide and its biosynthetic precursors. Gas chromatography-mass spectrometry analysis of the endogenous sterols in this mutant revealed that it accumulates 24-methylenecholesterol and isofucosterol but is deficient in their hydrogenated products, campesterol and sitosterol. Feeding experiments using ²H-labeled 24-methylenecholesterol indicated that the lkb mutant is unable to isomerize and/or reduce the Δ²⁴⁽²⁸⁾ double bond. Dwarfism of the lkb mutant is, therefore, due to BR deficiency caused by blocked synthesis of campesterol from 24-methylenecholesterol. The lkb mutation also disrupted sterol composition of the membranes, which, in contrast to those of the wild type, contained isofucosterol as the major sterol and lacked stigmasterol. The lka mutant was not BR deficient, because it accumulated castasterone. Like some gibberellin-insensitive dwarf mutants, overproduction of castasterone in the lka mutant may be ascribed to the lack of a feedback control mechanism due to impaired perception/signal transduction of BRs. The possibility that castasterone is a biologically active BR is discussed.     

Expression and functional analysis of <Emphasis Type="Italic">ZmDWF4</Emphasis>, an ortholog of <Emphasis Type="Italic">Arabidopsis DWF4</Emphasis> from maize (<Emphasis Type="Italic">Zea mays</Emphasis> L.)

DWF4 encodes a rate-limiting mono-oxygenase that mediates 22α-hydroxylation reactions in the BR biosynthetic pathway and it is the target gene in the BR feedback loop. Knockout of DWF4 results in a dwarfed phenotype and other severe defects in Arabidopsis. Here we report on the isolation of the ZmDWF4 gene in maize. Sequence analysis revealed that the open reading frame of ZmDWF4 was 1,518 bp, which encodes a protein composed of 505 amino acid residues with a calculated molecular mass of 57.6 kD and a predicated isoelectric point (pI) of 9.54. Phylogenetic analysis indicated that ZmDWF4 was very close to the Arabidopsis DWF4. In young maize seedlings, the expression of ZmDWF4 in shoots was much higher than that in roots. The highest expression of ZmDWF4 was observed in husk leaves and the lowest in silks during flowering stage. The expression of ZmDWF4 in maize was significantly down regulated by exogenous brassinolide. A heterogeneous complementary experiment demonstrated that the defects of three Arabidopsis DWF4 mutants could be rescued by constitutive expression of ZmDWF4, with leaf expandability, inflorescence stem heights and fertile capabilities all restored to normal levels. Increases in seed and branch number as well as the height of florescence stem were observed in the over-expressed transformants. These findings suggest that ZmDWF4 may be an ortholog gene of Arabidopsis DWF4 and responsible for BR biosynthesis in maize. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

The pea<Emphasis Type="Italic"> END1</Emphasis> promoter drives anther-specific gene expression in different plant species

END1 was isolated by an immunosubtractive approach intended to identify specific proteins present in the different pea (Pisum sativum L.) floral organs and the genes encoding them. Following this strategy we obtained a monoclonal antibody (mAbA1) that specifically recognized a 26-kDa protein (END1) only detected in anther tissues. Northern blot assays showed that END1 is expressed specifically in the anther. In situ hybridization and immunolocalization assays corroborated the specific expression of END1 in the epidermis, connective, endothecium and middle layer cells during the different stages of anther development. END1 is the first anther-specific gene isolated from pea. The absence of a practicable pea transformation method together with the fact that no END1 homologue gene exists in Arabidopsis prevented us from carrying out END1 functional studies. However, we designed functional studies with the END1 promoter in different dicot species, as the specific spatial and temporal expression pattern of END1 suggested, among other things, the possibility of using its promoter region for biotechnological applications. Using different constructs to drive the uidA (-glucuronidase) gene controlled by the 2.7-kb isolated promoter sequence we have proven that the END1 promoter is fully functional in the anthers of transgenic Arabidopsis thaliana (L.) Heynh., Nicotiana tabacum L. (tobacco) and Lycopersicon esculentum Mill. (tomato) plants. The presence in the –330-bp region of the promoter sequence of three putative CArG boxes also suggests that END1 could be a target gene of MADS-box proteins and that, subsequently, it would be activated by genes controlling floral organ identity.Abbreviations GUS -Glucuronidase - uidA -Glucuronidase gene - Nos Nopaline synthase gene - nptII Neomycin phosphotransferase II gene - SEM Scanning electron microscopy GenBank accession numbers for the END1 cDNA and the END1 promoter: AY 091466 and AY 324651, respectively     

Microtubule Orientation in the Brassinosteroid Mutants <Emphasis Type="Italic">lk,lka</Emphasis> and <Emphasis Type="Italic">lkb</Emphasis> of Pea

Short brassinosteroid (BR) mutants lk, lka and lkb of pea (Pisum sativum L.) were investigated by immunofluorescence microscopy to elucidate the role of brassinosteroids in cell elongation via an effect on the microtubules (MTs). This study adds to our knowledge the fact that brassinolide (BL) can cause MT realignment in azuki bean and rescue the MT organization of BR mutants in Arabidopsis. It provides novel information on both cortical and epidermal cells and presents detailed information about the ratios of all MT orientations present, ranging from transverse (perpendicular to the elongating axis) to longitudinal (parallel to the elongating axis). Experiments were conducted in vivo using intact plants with direct application of a small amount of brassinolide (BL) to the internode. Employing a BR-receptor mutant, lka, and the BR-synthesis mutants, lk and lkb, allowed the identification and isolation of any BR-induced responses in the MT cytoskeleton following BL application. Increases in growth rate were noted in all pea lines including WT following BL application. These increases were strong in the BR-synthesis mutants, but weak in the BR-receptor mutant. Immunofluorescence revealed significant differences in the average MT orientation of cortical cells of mutants versus WTs. Importantly, these mutants possessed abundant MTs, unlike the BR-deficient bul1-1 mutant in Arabidopsis. Following BL application, the epidermal and cortical cells of lk and lkb plants showed a large and significant shift in MT orientation towards more transverse, whereas lka plants showed a small and nonsignificant response in these cells. These results suggest that the BR response pathway is linked to the regulation of MT orientation.     

Competitive nodulation blocking of Afghanistan pea is determined by nodDABC and nodFE alleles in Rhizobium leguminosarum

Summary One well-defined competitive interaction amongst rhizobia is that between compatible and non-compatible strains of Rhizobium leguminosarum with respect to the nodulation of some primitive pea genotypes. The Middle Eastern pea cv Afghanistan is nodulated effectively can R. leguminosarum TOM, but its capacity to nodulate can be blocked if a mixed inoculation is made with R. leguminosarum PF₂. This PF₂ phenotype (Cnb) is encoded by its symbiotic plasmid and cosmid clones thereof. We found that Cnb is also encoded by the well-characterized Sym plasmid pRL1JI of R. leguminosarum strain 248. We have isolated and characterized a 6.9 kb HindIII fragment of pSymPF₂ which confers the Cnb⁺ phentoype on other (Cnb^–) rhizobia. A Tn5 site-directed Cnb^– mutant was constructed by homogenotization and was also found to be Nod^– on the European pea cv Rondo. DNA hybridization and complementation analysis indicated that the 6.9 kb Cnb⁺ fragment contained the nodD, nodABC and nodFE operons. Analysis of the Cnb phenotype of nod::Tn5 alleles of pRL1JI showed that mutations of nodC, nodD or nodE all abolished Cnb activity whereas mutants in nodI and nodJ reduced activity to 50% of the wild-type level.     

Identification of gibberellin A4 in Pisum sativum L. and the effects of applied gibberellins A9, A4, A5 and A3 on the le mutant

Gibberellin A₄ (GA₄) was identified for the first time in the garden pea (Pisum sativum) L.), by gas chromatography-mass spectrometry. However, in wild-type shoots the level of GA₄ was only about 6% of the level of GA₁, and it is therefore unlikely that GA₄ plays a major role per se in the control of pea stem elongation. In shoots of the le mutant, GA₄ was not detected, while the level of GA₉ was approximately twice that found in the wild-type. The le mutation also markedly reduced the elongation response to applied GA₉. It appears, therefore, that in Pisum the le mutation blocks the 3-hydroxylation of GA₉ to GA₄, in addition to the 3-hydroxylation of GA₂₀ to GA₁. In contrast, the le mutation did not reduce the response to applied GA₅, suggesting the step GA₅ to GA₃ is not catalysed by the enzyme controlled by the Le gene. The step GA₅ to GA₃ was confirmed in peas by metabolite analysis after treatment with deuterated GA₅.     

Depletion of Aspergillus nidulans cotA causes a severe polarity defect which is not suppressed by the nuclear migration mutation nudA2

The Aspergillus nidulans homologue of Neurospora crassa cot-1, cotA, encoding a member of the NDR protein kinase family, has been cloned and expressed under the control of the conditional alcA promoter. Depletion of CotA by repression of the alcA promoter led to a severe growth defect accompanied by loss of polarity. Germlings show greatly enlarged volume of the spores and hyphae, accompanied by an increase in number of nuclei per compartment, though the nucleus/volume ratio is not significantly altered. The depleted CotA phenotype was not suppressed by a nuclear migration mutation nudA2. Double mutants showed an additive, defective phenotype, unlike the suppression of the cot-1 ts mutation by ropy mutations seen in N. crassa, suggesting a different relationship between nuclear migration and the cot signalling pathway in A. nidulans. A functional CotA–GFP fusion protein was found in punctate regions of fluorescence similar to the distribution reported for human NDR2, and as a cap at the hyphal tip.     

Identification and fine mapping of a thermo-sensitive chlorophyll deficient mutant in rice (<Emphasis Type="Italic">Oryza sativa </Emphasis>L.)

A thermo-sensitive chlorophyll deficient mutant was isolated from more than 15,000 transgenic rice lines. The mutant displayed normal phenotype at 23°C or lower temperature (permissive temperature). However, when grown at 26°C or higher (nonpermissive temperature) the plant exhibited an abnormal phenotype characterized by yellow green leaves. Genetic analysis revealed that a single nuclear-encoded recessive gene is responsible for the mutation, which is tentatively designed as cde1(t) (chlorophyll deficient 1, temporally). PCR analysis and hygromycin resistance assay indicated the mutation was not caused by T-DNA insertion. To isolate the cde1(t) gene, a map-based cloning strategy was employed and 15 new markers (five SSR and ten InDels markers) were developed. A high-resolution physical map of the chromosomal region around the cde1(t) gene was made using F₂ and F₃ population consisting of 1,858 mutant individuals. Finally, the cde1(t) gene was mapped in 7.5 kb region between marker ID10 and marker ID11 on chromosome 2. Sequence analysis revealed only one candidate gene, OsGluRS, in the 7.5 kb region. Cloning and sequencing of the target region from the cde1(t) mutant showed that a missense mutation occurred in the mutant. So the OsGluRS gene (TIGR locus Os02 g02860) which encode glutamyl-tRNA synthetase was identified as the Cde1(t) gene.     

Molecular cloning and characterization of the dpy-20 gene of Caenorhabditis elegans

We describe the molecular analysis of the dpy20 gene in Caenorhabditis elegans. Isolation of genomic sequences was facilitated by the availability of a mutation that resulted from insertion of a Tc1 transposable element into the dpy-20 gene. The Tc1 insertion site in the m474:: Tc1 allele was identified and was found to lie within the coding region of dpy-20. Three revertants (two wild-type and one partial revertant) resulted from the excision of this Tc1 element. Genomic dpy-20 clones were isolated from a library of wild-type DNA and were found to lie just to the left of the unc-22 locus on the physical map, compatible with the position of dpy-20 on the genetic map. Cosmid DNA containing the dpy-20 gene was successfully used to rescue the mutant phenotype of animals homozygous for another dpy-20 allele, e1282ts. Sequence analysis of the putative dpy-20 homologue in Caenorhabditis briggsae was performed to confirm identification of the coding regions of the C. elegans gene and to identify conserved regulatory regions. Sequence analysis of dpy-20 revealed that it was not similar to other genes encoding known cuticle components such as collagen or cuticulin. The dpy-20 gene product, therefore, identifies a previously unknown type of protein that may be directly or indirectly involved in cuticle function. Northern blot analysis showed that dpy-20 is expressed predominantly in the second larval stage and that the mRNA is not at all abundant. Data from temperature shift studies using the temperature-sensitive allele e1282ts showed that the sensitive period also occurs at approximately the second larval stage. Therefore, expression of dpy-20 mRNA and function of the DPY-20 protein are closely linked temporally.     

Genetic interaction between the Ras-CAMP pathway and the Dis2s1/Glc7 protein phosphatase in Saccharomyces cerevisiae

The Saccharomyces cerevisiae DIS2S1/GLC7 gene encodes a type 1 protein phosphatase indispensable for cell proliferation. We found that introduction of a multicopy DIS2S1 plasmid impaired growth of cells with reduced activity of the cAMP-dependent protein kinase. In order to understand further the interaction between the two enzymes, a temperature-sensitive mutation in the DIS2S1 gene was isolated. The mutant accumulated less glycogen than wild type at the permissive temperature, indicating that activity of the Dis2s1 protein phosphatase is attenuated by the mutation. Furthermore, the dis2s1 ^ts mutation was shown to be suppressed by a multicopy plasmid harboring PDE2, a gene for cAMP phosphodiesterase. These results indicate that the Ras-cAMP pathway interacts genetically with the DIS2S1/GLC7 gene.     

Isolation of the promoter of a root cap expressed pectinmethylesterase gene from Pisum sativum L. (rcpme1) and its use in the study of gene activity

A genomic clone of a pea pectinmethylesterase encoding gene, rcpme1, was isolated; the promoter region was found to include regions of homology to phenylalanine ammonia lyase (PAL) and nodulin gene promoters. Agrobacterium rhizogenes mediated hairy roots were used for rcpme1 expression and functional analysis in pea. Patterns of rcpme1 expression in cultured hairy roots, measured using uidA encoding -glucuronidase (GUS) as a reporter gene, were distinct from patterns which occur in normal pea roots. No reporter gene expression occurred in transgenic Arabidopsis thaliana, whose roots do not produce border cells. Border cell number from transgenic hairy roots expressing rcpme1 anti-sense mRNA under the control of its 2.75 kb 5 flanking sequence was reduced by > 50%. Nodulation genes of Rhizobium leguminosarum were used as a marker to document that roots with reduced production of border cells and other root cap exudates have a corresponding reduction in levels of biologically active signal molecules. Direct measurements were used to confirm that most of the exudate harvested from young, unwounded roots of normal pea plants is derived from the root tip region where rcpme1 is expressed. The potential application of the rcpme1 gene as a molecular marker for root exudate production is discussed.     

The CLS2 gene encodes a protein with multiple membrane-spanning domains that is important Ca2+ tolerance in yeast

Genetic screening of Saccharomyces cerevisiae mutants defective in Ca²⁺ homeostasis identified cls2, which exhibits a specific Ca²⁺-sensitive growth phenotype. We describe here the CLS2 gene and a multicopy suppressor (named BCL21, for bypass of CLS2) of the cls2 mutation. The CLS2 gene encodes a polypeptide of 410 amino acid residues, and its hydropathy profile indicates that the predicted Cls2 protein (Cls2p) contains ten putative membrane spanning regions. Immunofluorescent staining of the yeast cells expressing epitopetagged Cls2p suggests that Cls2p is localized to endoplasmatic reticulum (ER) membrane. A cls2 disruption strain is viable, but shows a Ca²⁺-sensitive phenotype like the original cls2 mutants. BCL21 suppresses the cls2 disruption mutation, indicating that the multicopy suppression does not require the Cls2p. Suppression of cls2 was observed even after introduction of a singlecopy plasmid harboring BCL21. The BCL21 gene encodes a protein of 382 amino acid residues and is identical to the SUR1 gene. sur1 was originally isolated as a suppressor of rvs161, which has reduced viability in nutrient starvation conditions. Possible mechanisms of the multicopy suppression are discussed.     

wiser tsl : a recessive X-linked temperature-sensitive lethal mutation that affects the wings and the eyes in Drosophila melanogaster

In this study, we characterize a recessive X-linked temperature-sensitive mutation of the gene CG32711. The mutation, named wiser ^tsl (wings scalloped-eyes rough), was isolated from a dysgenic cross and is due to a natural P element insertion within the 5′ regulatory region of the gene. Mutant (wiser ^tsl ) individuals exhibit wing notching, rough eyes, tarsal malformations and reduced life-span. At 29°C they die at larval and late pharate stages or during eclosion. The CG32711 (wiser) gene is mainly expressed in the ventral midline cells, the peripheral neural system, the hemocytes and the tracheal system of embryos. It is also expressed in nurse cells of adult female ovaries. Our results show that the wiser gene is alternatively spliced generating two mRNAs, which share the same open reading frame, while western analysis identified two protein isoforms. Their expression pattern depends on the stage of development and the culture temperature. wiser ^tsl and wild-type individuals display different expression patterns of the two isoforms and this difference most probably accounts for the mutant phenotype. Our results indicate that wiser is a vital gene for the development of Drosophila melanogaster which has no orthologs outside the Drosophilidae. Sequence data from this article have been deposited with the EMBL/GenBank Data Libraries under accession nos. bankit1003537 EU071463–bankit1003860 EU071464.     

Escherichia coli parA is an allele of the gyrB gene

Summary A thermosensitive (ts) parA mutant, MFT110, of Escherichia coli carried at least two ts mutations. The major ts defect, resulting from a mutation mapped originally at 95 min and complemented by pLC8-47, was most probably due to psd. A plasmid carrying the 1.6 kb BamHI-PvuII fragment recloned from pLC8-47 complemented the major ts mutation in MFT110 and psd(ts) in two mutants, but did not correct the Par phenotype of MFT110. The second ts mutation was salt-repairable and mapped at 83 min close to recF and tnaA. This mutation was linked with the Par phenotype as shown unambiguously by 4,6-diamidino-2-phenylindole stained nucleoids in parA mutant cells with the W3110 genetic background. Both salt-repairable ts and Par traits were corrected concomitantly by a plasmid carrying the chromosomal region solely for the gyrB gene. This strongly suggests that parA is an allele of gyrB.     

Isolation and preliminary characterization of gas1-1, a mutation causing partial suppression of the phenotype conferred by the gibberellin-insensitive (gai) mutation in Arabidopsis thaliana (L.) Heyhn

The semi-dominant gai mutation of arabidopsis confers a dark-green dwarf phenotype resembling that of gibberellin (GA)-deficient mutants. In contrast to GA-deficient mutants, gai mutants do not respond to GA treatments and accumulate higher levels of bioactive GAs than are found in wild-type controls. The gai mutation thus alters the responses of plant cells to GA, indicating that the GAI (wild-type) gene product is involved in GA reception and/or signal transduction. Here we describe the isolation and preliminary characterization of a mutation, gas1-1, which is not linked to gai and which partially suppresses the effect of the gai mutation. Double mutant, gai gas1-1, homozygotes are less severely dwarfed and lighter green than gai GAS1 controls. However, comparisons of the effects of treatments with exogenous GA demonstrate that gas1-1 does not increase the GA responsiveness of the gai mutant. Thus the gas1-1 mutation appears to reduce the GA-dependency of plant growth, and identifies a gene (GAS1) whose product is a candidate GA signal-transduction component.Abbreviations GA gibberellin - GA₃ gibberellic acid We thank Maarten Koornneef (Wageningen Agricultural University, The Netherlands) for providing mutant seed stocks; Mark Aarts and Bernard Mulligan (University of Nottingham, UK) for performing the -irradiation. This work was made possible by AFRC/BBSRC PMB Grants PG208/520 and PG208/0600, and by a grant from the Gatsby Charitable Foundation. P.C. was supported by a Human Capital and Mobility Fellowship from the EC.     

Gibberellin mutants

Research on gibberellin (GA) mutants is reviewed, focusing on reports, published since 1993. The mutants have usually been identified via a shoot elongation screen. This screen exposes mutations influencing GA synthesis, deactivation and reception, and also those acting further down the elongation pathway. Mutations blocking synthesis lead to a dwarf. GA-responsive phenotype. Numerous such mutations are now known. For some steps homologous mutations are known across 4 to 6 model species. Examples include the early step, geranylgeranyl diphosphate to copalyl diphosphate, and the activation step, GA₂₆to GA₁. Several GA-synthesis mutations have now been characterised at the molecular level and all are in structural genes. It is now clear some steps are controlled by gene families with distinct tissue specificity. Further, some enzymes control more than one step in the biosynthetic pathway. The only mutation known to block deactivation. sin in pea, leads to an elongated phenotype. The GA response mutants are less well understood and are a more diverse group. They include elongated mutants with a constitutive GA response (spy in arabidopsis. la cry-s in pea and sln in barley) or an enhanced GA response (phyB in arabidopsis. lv in pea and Ih in cucumber). Short response mutants include at least three types. One group accumulates GAs and are mostly unresponsive to applied GA (gai in arabidopsis. D8 in maize. Rht3 in wheat). A recently identified group, exemplified by Igr in pea and gas in barley, have a short stature and reduced response but attain full responses with very high doses of exogenous GA. How close these mutations act to GA reception remains to be determined. Lastly, a number of mutants with short stature and reduced GA response differ in overall phenotype from GA-deficient plants and cannot be made to mimic wild type even at high GA application rates. These mutations act beyond GA reception and some have already proved useful in elucidating other pathways that affect shoot elongation. For example, the lk and lkb mutations in pea appear to block brassinolide synthesis and this in turn prevents normal GA-mediated elongation responses.     

Stems of the <Emphasis Type="Italic">Arabidopsis pin1-1</Emphasis> mutant are not deficient in free indole-3-acetic acid

The pin1-1 mutant of Arabidopsis thaliana has been pivotal for studies on auxin transport and on the role of auxin in plant development. It was reported previously that when whole shoots were analysed, levels of the major auxin, indole-3-acetic acid (IAA) were dramatically reduced in the mutant, compared with the WT (Okada et al. 1991). The cloning of PIN1, however, provided evidence that this gene encodes a facilitator of auxin efflux, raising the question of how the pin1-1 mutation might reduce overall IAA levels as well as IAA transport. We therefore re-examined IAA levels in individual parts of pin1-1 and WT plants, focusing on inflorescence stems. Our data show that there is in fact no systemic IAA deficiency in the mutant. The previously reported difference between mutant and WT may have been due to the inclusion of reproductive structures in the WT harvest: we show here that the inflorescence itself contains high levels of IAA. We reconcile the normal IAA levels of pin1-1 inflorescence stems with their (previously-reported) reduced ability to transport IAA by presenting evidence that the auxin in mutant stems is not imported from their apical portion. Our data also indicate that levels of another auxin, indole-3-butyric acid (IBA), are very low in stems of the genotypes used in this study.     

A putative disease-associated haplotype within the SCN1A gene in Dravet syndrome

Dravet syndrome (DS), previously known as severe myoclonic epilepsy of infancy, is one of the most severe forms of childhood epilepsy. DS is caused by a mutation in the neuronal voltage-gated sodium-channel alpha-subunit gene (SCN1A). However, 25–30% of patients with DS are negative for the SCN1A mutation screening, suggesting that other molecular mechanisms may account for these disorders. Recently, the first case of DS caused by a mutation in the neuronal voltage-gated sodium-channel beta-subunit gene (SCN1B) was also reported. In this report we aim to make the molecular analysis of the SCN1A and SCN1B genes in two Tunisian patients affected with DS. The SCN1A and SCN1B genes were tested for mutations by direct sequencing. No mutation was revealed in the SCN1A and SCN1B genes by sequencing analyses. On the other hand, 11 known single nucleotide polymorphisms were identified in the SCN1A gene and composed a putative disease-associated haplotype in patients with DS phenotype. One of the two patients with putative disease-associated haplotype in SCN1A had also one known single nucleotide polymorphism in the SCN1B gene. The sequencing analyses of the SCN1A gene revealed the presence of a putative disease-associated haplotype in two patients affected with Dravet syndrome.