A rice <Emphasis Type="Italic">White-stripe leaf3</Emphasis> (<Emphasis Type="Italic">wsl3</Emphasis>) mutant lacking an HD domain-containing protein affects chlorophyll biosynthesis and chloroplast development

Leaf-color mutants are ideal genetic materials for understanding the mechanism of chloroplast development and chlorophyll (Chl) biosynthesis. Here we isolated and identified a new leaf-color mutant of rice, named white-stripe leaf3 (wsl3), from a ⁶⁰Co-irradiated mutant pool. The wsl3 mutant displayed a visible white-stripe leaf in both young seedlings and flag leaves of mature plant. Chl content in homozygous wsl3 mutant was approximately 47% of that in the wild type. Besides, chloroplast development in the mutant was severely arrested. By a map-based cloning strategy, the wsl3 gene was finely confined to a 50.8 kb region on chromosome 1. Moreover, a 9-bp deletion was identified in the genomic region of LOC_Os01g01920, which encodes an HD (histidine and aspartic acid) domaincontaining protein. Genetic complementation confirmed that LOC_Os01g01920 could recover the lesion of wsl3 mutation. Real-time PCR analyses showed that the expression levels of WSL3 were the highest in young and flag leaves among various tissues, and most of the genes associated with Chl biosynthesis were significantly down-regulated in the wsl3 mutant. Meanwhile, in contrast to many nuclear gene-encoded phage-type RNA polymerase(s) (NEP) transcribed genes were up-regulated, most of plastid-encoded bacterialtype RNA polymerase (PEP) transcribed genes were downregulated. These results demonstrated that the WSL3 gene, as an HD domain-containing protein, is involved in chl biosynthesis and chloroplast development in rice.     

Genetics and fine mapping of a yellow-green leaf gene (<Emphasis Type="Italic">ygl</Emphasis>-<Emphasis Type="Italic">1</Emphasis>) in cabbage (<Emphasis Type="Italic">Brassica oleracea</Emphasis> var. <Emphasis Type="Italic">capitata</Emphasis> L.)

Cabbage (Brassica oleracea var. capitata L.) is one of the most popular cultivated vegetables worldwide. Cabbage has rich phenotypic diversity, including plant height, head shape, head color, leaf shape and leaf color. Leaf color plays an important role in cabbage growth and development. At present, there are few reports on fine mapping of leaf color mutants in B. oleracea. In this study, a naturally occurring yellow-green leaf cabbage mutant (YL-1), derived from the self-pollinated progenies of the hybrid ‘Hosom’, was used for inheritance analysis and gene mapping. Segregation populations including F₂ and BC₁ were generated from the cross of two inbred lines, YL-1 and 01–20. Genetic analysis with the F₂ and BC₁ populations demonstrated that the yellow-green leaf color was controlled by a single recessive nuclear gene, ygl-1. Insertion–deletion (InDel) markers, designed based on the parental re-sequencing data, were used for the preliminary mapping with BSA (bulked segregant analysis) method. A genetic map constructed with 15 InDels indicated that ygl-1 was located on chromosome C01. The ygl-1 gene is flanked by InDel markers ID2 and M8, with genetic distances of 0.4 cM and 0.35 cM, respectively. The interval distance between two markers is 167 kb. Thus, it enables us to locate the ygl-1 gene for the first time in B. oleracea. This study lays the foundation for candidate gene prediction and ygl-1gene cloning.     

Deletion of <Emphasis Type="Italic">ldh</Emphasis>A and <Emphasis Type="Italic">ald</Emphasis>H genes in <Emphasis Type="Italic">Klebsiella</Emphasis><Emphasis Type="Italic">pneumoniae</Emphasis> to enhance 1,3-propanediol production

Objectives

To improve 1,3-propanediol (1,3-PD) production and reduce byproduct concentration during the fermentation of Klebsiella pneumonia.

Results

Klebsiella. pneumonia 2-1ΔldhA, K. pneumonia 2-1ΔaldH and K. pneumonia 2-1ΔldhAΔaldH mutant strains were obtained through deletion of the ldhA gene encoding lactate dehydrogenase required for lactate synthesis and the aldH gene encoding acetaldehyde dehydrogenase involved in the synthesis of ethanol. After fed-batch fermentation, the production of 1,3-PD from glycerol was enhanced and the concentrations of byproducts were reduced compared with the original strain K. pneumonia 2-1. The maximum yields of 1,3-PD were 85.7, 82.5 and 87.5 g/l in the respective mutant strains.

Conclusion

Deletion of either aldH or ldhA promoted 1,3-PD production in K. pneumonia.

     

Further insight into the role of <Emphasis Type="Italic">KAN1</Emphasis>, a member of <Emphasis Type="Italic">KANADI</Emphasis> transcription factor family in rice

The rice EMS-derived mutant leaf adaxialized 1 (lad1) was isolated based on its upward rolling leaf phenotype. Besides the adaxially rolled leaf, many other agronomic traits were also compromised in lad1. The rolling trait was characterized by a noticeable alteration of bulliform cells in the adaxial side of the leaves. Map-based cloning showed a single nucleotide substitution in the promoter region of the KAN1 gene in lad1 mutant. Further, over-expressing and CRISPR/cas9-edited knockdown transgenic plants confirmed that KAN1 was responsible for the mutant phenotype of lad1. Yeast two-hybrid and bimolecular fluorescence complementation assay demonstrated that KAN1 can interact with the auxin response factors ARF3, ARF7 and ARF15. Physiologically, the contents of auxin (IAA), abscisic acid (ABA), jasmonic acid (JA) and gibberellin (GA) were all significantly increased in the lad1 mutant. Moreover, the GA3 content dramatically decrease in wild-type, but increased in lad1 under IAA induction. Additionally, the expression levels of several IAA and GA biosynthesis and responsive-related genes and genes involved in leaf polarity determination were altered in lad1. Therefore, we hypothesized that KAN1/ARFs protein complexes act as auxin-dependent regulatory units that play a conserved role in leaf development.     

Horizontal transfer of the C-termini of <Emphasis Type="Italic">tccC</Emphasis> genes in <Emphasis Type="Italic">Photorhabdus</Emphasis> and <Emphasis Type="Italic">Xenorhabdus</Emphasis>

The high molecular weight insecticidal toxin complexes (Tcs), including four toxin-complex loci (tca, tcb, tcc and tcd), were first identified in Photorhabdus luminescens W14. Each member of tca, tcb or tcc is required for oral toxicity of Tcs. However, the sequence sources of the C-termini of tccC3, tccC4, tccC6 and tccC7 are unknown. Here, we performed a whole genome survey to identify the orthologs of Tc genes, and found 165 such genes in 14 bacterial genomes, including 40 genes homologous to tccC1-7 in P. luminescens TT01. The sequence sources of the C-termini of tccC2-6 were determined by sequence analysis. Further phylogenetic investigations suggested that the C-termini of 6 tccC genes experienced horizontal gene transfer events.     

Comparative Genomics and Synteny Analysis of <Emphasis Type="BoldItalic">KCS17</Emphasis>-<Emphasis Type="BoldItalic">KCS18</Emphasis> Cluster Across Different Genomes and Sub-genomes of Brassicaceae for Analysis of Its Evolutionary History

Comparative genomics-based synteny analysis has proved to be an effective strategy to understand evolution of genomic regions spanning a single gene (micro-unit) to large segments encompassing hundreds of kilobases to megabases. Brassicaceae is in a unique position to contribute to understanding genome and trait evolution through comparative genomics because whole genome sequences from as many as nine species have been completed and are available for analysis. In the present work, we compared genomic loci surrounding the KCS17-KCS18 cluster across these nine genomes. KCS18 or FAE 1 gene encodes beta-ketoacyl synthase, (β-KCS) a membrane-bound enzyme that catalyses the key rate-limiting step during synthesis of VLCFAs such as erucic acid (C22) present in seed oil in Brassicaceae by elongating carbon chain from C18 to C22; knowledge on role of KCS17 in plant development is however lacking. Synteny across the genomic segments harbouring FAE1 showed variable levels of gene retention ranging between 26% (Arabidopsis thaliana and Brassica napus C03) and 89% (between A. thaliana and Brassica rapa A01), and gene density ranged between 1 gene/2.86 kb and 1 gene/4.88 kb. Interestingly, in diploid Brassica species, FAE1 was retained in only one of the sub-genomes in spite of the presence of three sub-genomes created as a result of genome triplication; in contrast, FAE1 was present at three loci, with four copies in Camellina sativa which is also known to have experienced a recent genome triplication revealing contrasting fates upon duplication. The organization of KCS17 and KCS18 as head-to-tail cluster was conserved across most of the species, except the C genome containing Brassicas, namely B. oleracea and B. napus, where disruptions because of other genes were observed. Even in the conserved blocks, the distance between KCS17 and KCS18 varied; the functional implication of the organization of KCS17-KCS18 as a cluster vis-à-vis fatty acid biosynthesis needs to be dissected, as the cis-regulatory region is expected to be present in the intergenic space. Phylogenetic analysis of KCS gene family along with KCS17-KCS18 from members of Brassicaceae reveals their ancestral relationship with KCS8-KCS9 block. Further comparative functional analysis between KCS8, KCS9, KCS16, KCS17 and KCS18 across evolutionary time-scale will be required to understand the conservation or diversification of roles of these members of KCS family in fatty acid biosynthesis during course of evolution.     

Role of Arabidopsis <Emphasis Type="Italic">ABF1</Emphasis>/<Emphasis Type="Italic">3</Emphasis>/<Emphasis Type="Italic">4</Emphasis> during <Emphasis Type="Italic">det1</Emphasis> germination in salt and osmotic stress conditions

Key message

Arabidopsis det1 mutants exhibit salt and osmotic stress resistant germination. This phenotype requires HY5, ABF1, ABF3, and ABF4.

Abstract

While DE-ETIOLATED 1 (DET1) is well known as a negative regulator of light development, here we describe how det1 mutants also exhibit altered responses to salt and osmotic stress, specifically salt and mannitol resistant germination. LONG HYPOCOTYL 5 (HY5) positively regulates both light and abscisic acid (ABA) signalling. We found that hy5 suppressed the det1 salt and mannitol resistant germination phenotype, thus, det1 stress resistant germination requires HY5. We then queried publically available microarray datasets to identify genes downstream of HY5 that were differentially expressed in det1 mutants. Our analysis revealed that ABA regulated genes, including ABA RESPONSIVE ELEMENT BINDING FACTOR 3 (ABF3), are downregulated in det1 seedlings. We found that ABF3 is induced by salt in wildtype seeds, while homologues ABF4 and ABF1 are repressed, and all three genes are underexpressed in det1 seeds. We then investigated the role of ABF3, ABF4, and ABF1 in det1 phenotypes. Double mutant analysis showed that abf3, abf4, and abf1 all suppress the det1 salt/osmotic stress resistant germination phenotype. In addition, abf1 suppressed det1 rapid water loss and open stomata phenotypes. Thus interactions between ABF genes contribute to det1 salt/osmotic stress response phenotypes.

     

Identification and fine mapping of a stay-green gene (<Emphasis Type="Italic">Brnye1</Emphasis>) in pakchoi (<Emphasis Type="Italic">Brassica campestris</Emphasis> L. ssp. <Emphasis Type="Italic">chinensis</Emphasis>)

Key message

Using bulked segregant analysis combined with next-generation sequencing, we delimited the Brnye1 gene responsible for the stay-green trait of nye in pakchoi. Sequence analysis identified Bra019346 as the candidate gene.

Abstract

“Stay-green” refers to a plant trait whereby leaves remain green during senescence. This trait is useful in the cultivation of pakchoi (Brassica campestris L. ssp. chinensis), which is marketed as a green leaf product. This study aimed to identify the gene responsible for the stay-green trait in pakchoi. We identified a stay-green mutant in pakchoi, which we termed “nye”. Genetic analysis revealed that the stay-green trait is controlled by a single recessive gene, Brnye1. Using the BSA-seq method, a 3.0-Mb candidate region was mapped on chromosome A03, which helped us localize Brnye1 to an 81.01-kb interval between SSR markers SSRWN27 and SSRWN30 via linkage analysis in an F₂ population. We identified 12 genes in this region, 11 of which were annotated based on the Brassica rapa annotation database, and one was a functionally unknown gene. An orthologous gene of the Arabidopsis gene AtNYE1, Bra019346, was identified as the potential candidate for Brnye1. Sequence analysis revealed a 40-bp insertion in the second exon of Bra019346 in nye, which generated the TAA stop codon. A candidate gene-specific Indel marker in 1561 F₂ individuals showed perfect cosegregation with Brnye1 in the nye mutant. These results provide a foundation for uncovering the molecular mechanism of the stay-green trait in pakchoi.

     

Fine mapping of <Emphasis Type="Italic">BoGL1</Emphasis>, a gene controlling the glossy green trait in cabbage (<Emphasis Type="Italic">Brassica oleracea</Emphasis> L. Var. <Emphasis Type="Italic">capitata</Emphasis>)

The cuticular wax covering epidermal cells causes the glaucous appearance in cabbage. As a protective barrier, cuticular wax plays various roles in protection against biotic and abiotic stresses. This is the first gene mapping report of a dominant glossy green cabbage mutant. In the present paper, scanning electron microscopy (SEM) demonstrated that the wax crystals were severely reduced in the mutant, which indicates that the glossy green phenotype is caused by cuticular wax reduction. Genetic analysis revealed that the glossy trait is controlled by a single dominant gene. Through primer screening and fine mapping, the mutant gene BoGL1 (Brassica oleracea glossy 1) was delimited to the end of chromosome C08 by the flanking marker SSRC08–76 at a genetic distance of 0.2 cM. Two genes homologous to CER1 (ECERIFERUM 1), a gene related to wax biosynthesis in Arabidopsis, were located in the mapped region. Expressional analysis revealed that the Bol018504 gene was severely suppressed but that no nucleotide variation was found by sequencing. These results lay the foundation for the functional analysis of BoGL1, and they will accelerate the research on wax metabolism in cabbage.     

Multilocus phylogeny of <Emphasis Type="Italic">Clonostachys</Emphasis> subgenus <Emphasis Type="Italic">Bionectria</Emphasis> from Brazil and description of <Emphasis Type="Italic">Clonostachys chloroleuca</Emphasis> sp. nov.

Phylogenetic analyses based on protein-encoding gene exons and introns of ATP citrate lyase (ACL1), beta tubulin (TUB), the largest subunit of RNA polymerase II (RPB1), and translation elongation factor 1-α (TEF1) are used for inferring the existence of a new Clonostachys species from the Cerrado biome in Brazil, described here as C. chloroleuca. The species produces dimorphic, primary, and secondary conidiophores that form consistently greenish conidial masses on artificial media. It resembles therefore C. rosea f. catenulata although it differs from this species by less adpressed branches in the secondary conidiophores. The new species is also phylogenetically related to C. byssicola and C. rhizophaga. Our inventory suggests that C. byssicola, C. chloroleuca, C. pseudochroleuca, C. rhizophaga, C. rogersoniana, and C. rosea commonly occur in native and agriculturally used soils of the Cerrado and Amazon Forest. Using sequences available from two genome-sequenced strains employed as biological control agents, we confirm the identity of the European strain IK726 as C. rosea and identify strain 67-1 from China as C. chloroleuca.     

Identification of a novel <Emphasis Type="Italic">SPLIT</Emphasis>-<Emphasis Type="Italic">HULL</Emphasis> (<Emphasis Type="Italic">SPH</Emphasis>) gene associated with hull splitting in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

Key message

The split-hull phenotype caused by reduced lemma width and low lignin content is under control of SPH encoding a type-2 13-lipoxygenase and contributes to high dehulling efficiency.

Abstract

Rice hulls consist of two bract-like structures, the lemma and palea. The hull is an important organ that helps to protect seeds from environmental stress, determines seed shape, and ensures grain filling. Achieving optimal hull size and morphology is beneficial for seed development. We characterized the split-hull (sph) mutant in rice, which exhibits hull splitting in the interlocking part between lemma and palea and/or the folded part of the lemma during the grain filling stage. Morphological and chemical analysis revealed that reduction in the width of the lemma and lignin content of the hull in the sph mutant might be the cause of hull splitting. Genetic analysis indicated that the mutant phenotype was controlled by a single recessive gene, sph (Os04g0447100), which encodes a type-2 13-lipoxygenase. SPH knockout and knockdown transgenic plants displayed the same split-hull phenotype as in the mutant. The sph mutant showed significantly higher linoleic and linolenic acid (substrates of lipoxygenase) contents in spikelets compared to the wild type. It is probably due to the genetic defect of SPH and subsequent decrease in lipoxygenase activity. In dehulling experiment, the sph mutant showed high dehulling efficiency even by a weak tearing force in a dehulling machine. Collectively, the results provide a basis for understanding of the functional role of lipoxygenase in structure and maintenance of hulls, and would facilitate breeding of easy-dehulling rice.

     

<Emphasis Type="Italic">LMI1</Emphasis>-like genes involved in leaf margin development of <Emphasis Type="Italic">Brassica napus</Emphasis>

In rapeseed (Brassica napus L.), leaf margins are variable and can be entire, serrate, or lobed. In our previous study, the lobed-leaf gene (LOBED-LEAF 1, BnLL1) was mapped to a 32.1 kb section of B. napus A10. Two LMI1-like genes, BnaA10g26320D and BnaA10g26330D, were considered the potential genes that controlled the lobed-leaf trait in rapeseed. In the present study, these two genes and another homologous gene (BnaC04g00850D) were transformed into Arabidopsis thaliana (L.) Heynh. plants to identify their functions. All three LMI1-like genes of B. napus produced serrate leaf margins. The expression analysis indicated that the expression level of BnaA10g26320D determined the difference between lobed- and entire-leaved lines in rapeseed. Therefore, it is likely that BnaA10g26320D corresponds to BnLL1.     

An NB-LRR gene, <Emphasis Type="Italic">TYNBS1</Emphasis>, is responsible for resistance mediated by the <Emphasis Type="Italic">Ty</Emphasis>-<Emphasis Type="Italic">2 Begomovirus</Emphasis> resistance locus of tomato

Key message

An NB-LRR gene, TYNBS1, was isolated from Begomovirus-resistance locus Ty-2. Transgenic plant analysis revealed that TYNBS1 is a functional resistance gene. TYNBS1 is considered to be synonymous with Ty-2.

Abstract

Tomato yellow leaf curl disease caused by Tomato yellow leaf curl virus (TYLCV) is a serious threat to tomato (Solanum lycopersicum L.) production worldwide. A Begomovirus resistance gene, Ty-2, was introduced into cultivated tomato from Solanum habrochaites by interspecific crossing. To identify the Ty-2 gene, we performed genetic analysis. Identification of recombinant line 3701 confirmed the occurrence of a chromosome inversion in the Ty-2 region of the resistant haplotype. Genetic analysis revealed that the Ty-2 gene is linked to an introgression encompassing two markers, SL11_25_54277 and repeat A (approximately 200 kb). Genomic sequences of the upper and lower border of the inversion section of susceptible and resistant haplotypes were determined. Two nucleotide-binding domain and leucine-rich repeat-containing (NB-LRR) genes, TYNBS1 and TYNBS2, were identified around the upper and lower ends of the inversion section, respectively. TYNBS1 strictly co-segregated with TYLCV resistance, whereas TYNBS2 did not. Genetic introduction of genomic fragments containing the TYNBS1 gene into susceptible tomato plants conferred TYLCV resistance. These results demonstrate that TYNBS1 is a functional resistance gene for TYLCV, and is synonymous with the Ty-2 gene.

     

The <Emphasis Type="Italic">angora</Emphasis> gene weakens the effect of interaction of the mutant genes <Emphasis Type="Italic">wellhaarig</Emphasis> and <Emphasis Type="Italic">waved alopecia</Emphasis> in mice

The interaction of the mutant genes wellhaarig (we) and waved alopecia (wal) in mice was earlier demonstrated in our laboratory. The we gene significantly accelerates the appearance of alopecia in double we/wewal/wal homozygotes as compared to that in single +/+wal/wal homozygotes. It has been found in this work that the mutant gene angora-Y (Fgf5 ^go-Y ) weakens the effect of interaction of the we and wal genes. The first signs of alopecia appear in mice of the we/wewal/wal genotype at the age of 14 days, in triple Fgf5 ^go-Y /Fgf5 ^go-Y we/wewal/wal homozygotes alopecia is observed seven days later, i. e., in 21-day-old animals. The progression of alopecia in triple homozygotes is expressed to a lesser degree than in double +/+we/wewal/wal homozygotes. A single dose of the Fgf5 ^go-Y gene also decreases the effect of interaction of the we and wal genes, but less than a double dose of this gene. The first signs of alopecia in mice of the +/Fgf5 ^go-Y we/wewal/wal genotype appear only three days later than in double +/+we/wewal/wal homozygotes. The data obtained demonstrate that the Fgf5 ^go-Y gene is a powerful modifier of mutant genes determining the process of alopecia.     

<Emphasis Type="Italic">Wsi18</Emphasis> promoter from wild rice genotype, <Emphasis Type="Italic">Oryza nivara</Emphasis>, shows enhanced expression under soil water stress in contrast to elite cultivar, <Emphasis Type="Italic">IR20</Emphasis>

Identification and characterization of plant promoters from wild rice genotypes showing inducible expression under soil water stress (SWS) is desirable for transgene expression to generate stress tolerant rice cultivars. A comparative expression profiling of Wsi18, a group 3 LEA gene, revealed differential response under SWS conditions between modern cultivated rice (IR20) and its wild progenitor (Oryza nivara). Wsi18 promoter from O. nivara showed enhanced inducible expression of the reporter gusA gene, encoding β-glucuronidase, in transgenic rice plants in comparison to similar promoter from IR20. Deletion analysis unravelled the cis-acting regulatory elements minimally required for optimal expression of Wsi18 promoter from O. nivara under SWS condition. This is the first report of characterization of an inducible promoter from a wild rice genotype to drive the gene expression under water stress conditions. The Wsi18 promoter element from the wild rice genotype can be used in future genetic manipulation strategies for the generation of SWS tolerant rice cultivars with improved yield characteristics.     

Revision of the <Emphasis Type="Italic">Serrulati</Emphasis> species of <Emphasis Type="Italic">Penstemon</Emphasis> section <Emphasis Type="Italic">Saccanthera</Emphasis> subsection <Emphasis Type="Italic">Serrulati</Emphasis>

A revision of Penstemon sect. Saccanthera subsect. Serrulati includes a new species (P. salmonensis), a new variety (P. triphyllus var. infernalis), and the elevation of a subspecies to species (P. curtiflorus), bringing the total number of species to eight, which are keyed and described, complete with nomenclature and type citations.