Interaction among C, R and Vp in the Control of the Bz Glucosyltransferase during Endosperm Development in Maize

The enzyme UPD glucose: flavonoid 3-O-glucosyltransferase (UFGT), involved in anthocyanin biosynthesis, is controlled by at least four genes (Bz, C, R and Vp) in the maize endosperm. Bz is the structural gene for the enzyme. Early in endosperm development, the enzyme is present in an uninduced low level that is independent of C, R and Vp, and dependent solely on Bz. Beginning at about the fourth week of development, C, R and Vp interact with each other to induce high levels of UFGT. The enzyme accumulates thereafter in normal endosperms, reaching its highest level at maturity. The nature of the developmental signal (s) controlled by C, R and Vp is discussed.     

Gene-dependent flavonoid glucosyltransferase in maize

A direct relationship between a specific gene and a specific enzyme involved in flavonoid biosynthesis is reported for the gene Bz and uridine diphosphoglucose: quercetin glucosyltransferase in maize pollen, seedlings, and seeds. Ratios are presented for specific activities of the glucosyltransferase from pollen, seed, and seedling tissues homozygous and heterozygous for Bz and homozygous for bz.Cooperative Investigations, Agricultural Research Service, United States Department of Agriculture and Missouri Agricultural Experiment Station, Columbia, Missouri 65201. Journal Series No. 7340.     

Identification and Characterization of a Mycobacterial (2R,3R)-2,3-Butanediol Dehydrogenase

Bacterial strain B-009, capable of using racemic 1,2-propanediol (PD), was identified as a rapid-growing member of the genus Mycobacterium. The strain is phylogenetically related to M. gilvum, but has slightly different physiological characteristics. An NAD⁺-dependent enantioselective alcohol dehydrogenase, which acts on R-PD, was purified from the strain. The enzyme was a homodimer of a peptide coded by a 1047-bp gene (mbd1). A highly conserved sequence for medium-chain dehydrogenase/reductases with a preference for secondary alcohols was found in the gene. Hydroxyacetone was produced from R-PD by an enzymatic reaction, indicating that position 2 of the substrate was oxidized. The enzyme activity was highest for (2R,3R)-2,3-butanediol (R,R-BD), enabling the enzyme to be identified as (2R,3R)-2,3-butanediol dehydrogenase (R,R-BD-DH). A homology search revealed M. gilvum, M. vanbaalenii, and M. semegmatis to have ORFs similar to mbd1, suggesting the widespread distribution of genes encoding R,R-BD-DH among mycobacterial strains.     

The alkane oxidation system of Pseudomonas oleovorans: induction of the alk genes in Escherichia coli W3110(pGEc47) affects membrane biogenesis and results in overexpression of alkane hydroxylase in a distinct cytoplasmic membrane subtraction

The alkane hydroxylase system of Pseudomonas oleovorans, which catalyses the initial oxidation of aliphatic substrates, is encoded by three genes. One of the gene products, the alkane hydroxyiase AlkB, is an integral cytoplasmic membrane protein. Induction leads to the synthesis of 1.5–2% AlkB relative to the total cell protein, both in P. oleovorans and in recombinant Escherichia coli DH1. We present a study on the Induction and localization of the alkane hydroxylase in E. coli W3110, which appears to be an interesting host strain because it permits expression levels of AlkB of up to 10–15% of the total cell protein. This expression level had negative effects on cell growth. The phospholipid content of such cells was about threefold higher than that of wild-type W3110. Freeze-fracture electron microscopy showed that induction of the alk genes led to the appearance of membrane vesicles in the cytoplasm; these occurred much more frequently in cells expressing alkB than in the negative control, which contained all of the alk genes except for alkB. Isolation and separation of the membranes of cells expressing alkB by density gradient centrifugation showed the customary cytoplasmic and outer membranes, as well as a low-density membrane fraction. This additional fraction was highly enriched in AlkB, as shown both by SDS-PAGE and enzyme activity measurements. A typical cytoplasmic membrane protein, NADH oxidase, was absent from the low-density membrane fraction, alkB expression in W3110 changed the composition of the phospholipid headgroup in the membrane, as well as the fatty acid composition of the membrane. The major changes occurred in the unsaturated fatty acids: C_16:1 and C_18:1 increased at the expense of C_17:0cyc and C_19:0cyc*     

RSC3K of soybean cv. Kefeng No.1 confers resistance to soybean mosaic virus by interacting with the viral protein P3

Soybean mosaic virus (SMV) is one of the most devastating viral pathogens of soybean (Glycine max (L.) Merr). In total, 22 Chinese SMV strains (SC1–SC22) have been classified based on the responses of 10 soybean cultivars to these pathogens. However, although several SMV-resistance loci in soybean have been identified, no gene conferring SMV resistance in the resistant soybean cultivar (cv.) Kefeng No.1 has been cloned and verified. Here, using F₂-derived F₃ (F_2:3) and recombinant inbred line (RIL) populations from a cross between Kefeng No.1 and susceptible soybean cv. Nannong 1138-2, we localized the gene in Kefeng No.1 that mediated resistance to SMV-SC3 strain to a 90-kb interval on chromosome 2. To study the functions of candidate genes in this interval, we performed Bean pod mottle virus (BPMV)-induced gene silencing (VIGS). We identified a recombinant gene (which we named R_SC3K) harboring an internal deletion of a genomic DNA fragment partially flanking the LOC100526921 and LOC100812666 reference genes as the SMV-SC3 resistance gene. By shuffling genes between infectious SMV DNA clones based on the avirulent isolate SC3 and virulent isolate 1129, we determined that the viral protein P3 is the avirulence determinant mediating SMV-SC3 resistance on Kefeng No.1. P3 interacts with RNase proteins encoded by R_SC3K, LOC100526921, and LOC100812666. The recombinant R_SC3K conveys much higher anti-SMV activity than LOC100526921 and LOC100812666, although those two genes also encode proteins that inhibit SMV accumulation, as revealed by gene silencing in a susceptible cultivar and by overexpression in Nicotiana benthamiana. These findings demonstrate that R_SC3K mediates the resistance of Kefeng No.1 to SMV-SC3 and that SMV resistance of soybean is determined by the antiviral activity of RNase proteins.     

Functional stacking of three resistance genes against Phytophthora infestans in potato

Functional stacking of broad spectrum resistance (R) genes could potentially be an effective strategy for more durable disease resistance, for example, to potato late blight caused by Phytophthora infestans (Pi). For this reason, three broad spectrum potato R genes (Rpi), Rpi-sto1 (Solanum stoloniferum), Rpi-vnt1.1 (S. venturii) and Rpi-blb3 (S. bulbocastanum) were selected, combined into a single binary vector pBINPLUS and transformed into the susceptible cultivar Desiree. Among the 550 kanamycin resistant regenerants, 28 were further investigated by gene specific PCRs. All regenerants were positive for the nptII gene and 23 of them contained the three Rpi genes, referred to as triple Rpi gene transformants. Detached leaf assay and agro-infiltration of avirulence (Avr) genes showed that the 23 triple Rpi gene transformants were resistant to the selected isolates and showed HR with the three Avr effectors indicating functional stacking of all the three Rpi genes. It is concluded that Avr genes, corresponding to the R genes to be stacked, must be available in order to assay for functionality of each stack component. No indications were found for silencing or any other negative effects affecting the function of the inserted Rpi genes. The resistance spectrum of these 23 triple Rpi gene transformants was, as expected, a sum of the spectra from the three individual Rpi genes. This is the first example of a one-step approach for the simultaneous domestication of three natural R genes against a single disease by genetic transformation.     

Double Asymmetric Induction During the Addition of (RP)‐Menthyl Phenyl Phosphine Oxide to Chiral Aldimines

P,C‐Stereogenic α‐amino phosphine oxides were prepared from the addition of (R_P)‐menthyl phenyl phosphine oxide to chiral aldimines under neat condition at 80 °C in up to 91:9 dr_C and 99% yields. The diastereoselectivity was mainly induced by chiral phosphorus that showed matched or mismatched induction with (S)‐ or (R)‐aldimines, respectively. Chirality 28:132–135, 2016. © 2015 Wiley Periodicals, Inc.     

Characterization and fine mapping of the rice blast resistance gene <Emphasis Type="Italic">Pia</Emphasis>

Blast, caused by Magnaporthe oryzae, is one of the most widespread and destructive diseases of rice. Breeding durable resistant cultivars (cvs) can be achieved by pyramiding of various resistance (R) genes. Pia, carried by cv. Aichi Asahi, was evaluated against 612 isolates of M. oryzae collected from 10 Chinese provinces. The Pia gene expresses weak resistance in all the provinces except for Jiangsu. Genomic position-ready marker-based linkage analysis was carried out in a mapping population consisting of 800 F₂ plants derived from a cross of Aichi Asahi×Kasalath. The locus was defined in an interval of approximately 90 kb, flanked by markers A16 and A21. Four candidate genes (Pia-1, Pia-2, Pia-3, and Pia-4), all having the R gene conserved structure, were predicted in the interval using the cv. Nipponbare genomic sequence. Four candidate resistance gene (CRG) markers (A17, A25, A26, and A27), derived from the four candidates, were subjected to genotyping with the recombinants detected at the flanking markers. The first three markers completely co-segregated with the Pia locus, and the fourth was absent in the Aichi Asahi genome and disordered with the Pia locus and its flanking markers, indicating that the fourth candidate gene, Pia-4, could be excluded. Co-segregation marker-based genotyping of the three sets of differentials with known R gene genotypes revealed that the genotype of A26 (Pia-3) perfectly matched the R gene genotype of Pia, indicating that Pia-3 is the strongest candidate gene for Pia.     

An evolutionary model for the duplication and divergence of esterase genes in Drosophila

Summary The esterase 5 (Est-5 = gene, EST 5 = protein) enzyme in Drosophila pseudoobscura is encoded by one of three paralogous genes, Est-5A, Est5B, and Est-5C, that are tightly clustered on the right arm of the X chromosome. The homologous Est-6 locus in Drosophila melanogaster has only one paralogous neighbor, Est-P. Comparisons of coding and flanking DNA sequences among the three D. pseudoobscura and two D. melanogaster genes suggest that two paralogous genes were present before the divergence of D. pseudoobscura from D. melanogaster and that, later, a second duplication occurred in D. pseudoobscura. Nucleotide sequences of the coding regions of the three D. pseudoobscura genes showed 78–85% similarity in pairwise comparisons, whereas the relatedness between Est-6 and Est-P was only 67%. The higher degree of conservation in D. pseudoobscura likely results from the comparatively recent divergence of Est-5B and Est-5C and from possible gene conversion events between Est-5A and Est-5B. Analyses of silent and replacement site differences in the two exons of the paralogous and orthologous genes in each species indicate that common selective forces are acting on all five loci. Further evidence for common purifying selective constraints comes from the conservation of hydropathy profiles and proposed catalytic residues. However, different levels of amino acid substitution between the paralogous genes in D. melanogaster relative to those in D. pseudoobscura suggest that interspecific differences in selection also exist.Offprint requests to: R.C. Richmond     

Overexpression of malic enzyme (ME) of Mucor circinelloides improved lipid accumulation in engineered Rhodotorula glutinis

The oleaginous yeast Rhodotorula glutinis has been known to be a potential feedstock for lipid production. In the present study, we investigated the enhancement of expression of malic enzyme (ME; NADP⁺ dependent; EC 1.1.1.40) from Mucor circinelloides as a strategy to improve lipid content inside the yeast cells. The 26S rDNA and 5.8S rDNA gene fragments isolated from Rhodotorula glutinis were used for homologous integration of ME gene into R. glutinis chromosome under the control of the constitutively highly expressed gene phosphoglycerate kinase 1 to achieve stable expression. We demonstrated that by increasing the expression of the foreign ME gene in R. glutinis, we successfully improved the lipid content by more than twofold. At the end of lipid accumulation phrase (96 h) in the transformants, activity of ME was increased by twofold and lipid content of the yeast cells was increased from 18.74 % of the biomass to 39.35 %. Simultaneously, there were no significant differences in fatty acid profiles between the wild-type strain and the recombinant strain. Over 94 % of total fatty acids were C_16:0, C_18:0, C_16:1, C_18:1, and C_18:2. Our results indicated that heterologous expression of NADP⁺-dependent ME involved in fatty acid biosynthesis indeed increased the lipid accumulation in the oleaginous yeast R. glutinis.     

Characterization and high-resolution mapping of a late blight resistance locus similar to R2 in potato

Identification of resistance (R) genes to Phytophthora infestans is an essential step in molecular breeding of potato. We identified three specific R genes segregating in a diploid mapping population. One of the R genes is located on chromosome 4 and proved phenotypically indistinguishable from the Solanum demissum-derived R2, although S. demissum is not directly involved in the pedigree of the population. By bulked segregant analysis combined with a resistance assay, a genetic linkage map of the R2-like locus was constructed with 30 coupling and 23 repulsion phase AFLP markers. Two markers flanking the R2-like locus were applied to screen an extended population of 1,586 offspring. About 103 recombinants were selected, and an accurate high-resolution map was constructed. The R2-like resistance was localized in a 0.4 cM interval and was found co-segregating with four AFLP markers, which can be used to isolate the R2-like gene by map-based gene cloning. By analyzing race-specificity and R gene-specific molecular markers, we also found that an R1-like gene and an additional unknown R gene are segregating in the population.     

Construction of Double-Copy Glucose Isomerase Gene Engineering Strain of Streptomyces diastaticus by Homologous Recombination

The plasmid pUT for homologous recombination was constructed by the insertion of the 1.1-kb thiostrepton resistance (tsr ^R) gene into the E. coli plasmid pUB1-GI1. Plasmid pUTK was produced through ligating the cleaved plasmid pUT by KpnI. After pUT and pUTK were introduced into Streptomyces diastaticus No.7 strain M1033 (SM33) by protoplast transformation, a series of tsr^R transformants were obtained, further based on enzyme assays. These results for polymerase chain reaction (PCR), DNA sequencing, restriction enzyme digestion, and recovery of cloned fragments from the transformant chromosome demonstrated the plasmid pUT and pUTK had integrated into the SM33 chromosome in three different patterns of single cross-over by homologous recombination. This directly results in double-copy GI gene in the transformant chromosome, of which one is wild-type GI gene, the other mutant GI (GIG138P, GI1) gene. Among the strains of the three kinds of recombinant patterns, one transformant was chosen and named K1, T2, and T3, respectively. The further identification of the three recombinant strains by PCR, DNA sequencing, restriction enzyme digestion, and Southern hybridization also proved there is a double-copy GI gene within their chromosome. Enzyme activity assay and thermostability analysis indicated that all three engineering strains expressed not only wild-type enzyme but also mutant GI. Received: 9 July 2001 / Accepted: 8 August 2001     

银杏毛状根褐化机制的初步研究

该实验依据现有发根农杆菌侵染法,以银杏无菌苗叶片为外植体,对农杆菌诱导银杏毛状根的实验操作进行优化,并观察记录银杏毛状根继代生长情况,测定继代不同天数的毛状根组织内多酚含量、多酚合成相关酶基因和POD基因相对表达量,以探讨银杏毛状根褐化的生理机制。结果显示:(1)银杏农杆菌侵染最适预培养时间为3d、菌种为R1601、共培养基为White、侵染时间为30min,优化侵染操作后的银杏毛状根诱导率可达72.36%;银杏毛状根继代生长的最适IBA浓度为0.5mg/L。(2)银杏毛状根初始发根时颜色为乳白色,多在伤口处簇生,伸长生长时无向地性,不分叶正背面都能在伤口处诱导出根,且在除菌培养20d时毛状根长可达0.4～0.8cm;继代培养25d时毛状根为白色,继代35d时部分毛状根从根部至中部开始转黄,继代45d时大部分毛状根由白转黄,根部至中部开始有褐化出现。(3)继代35d时毛状根的PAL、C4 H、4CL和POD基因表达量分别为25d的68%、44%、51%、52%;继代45d时PAL、C4 H、4CL、POD基因表达量分别为35d的19%、75%、86%、105%。(4)继代35d、45d的银杏毛状根总酚类含量分别为17.14和13.78mg/g。研究发现,PAL基因表达量变化与其下游的两个关键酶基因(C4 H、4CL)表达量变化不一致,且PAL基因表达量的大幅降低并未对下游C4 H、4CL基因表达有明显影响,说明PAL基因表达量变化对其下游合成速率影响不大,可能不是银杏毛状根苯丙氨酸代谢途径的限速酶;而C4 H与4CL基因表达量变化趋势高度一致,说明C4H应是该途径中的限速酶之一;推测继代前期可能是由PPO作为关键酶参与毛状根褐化反应,导致后期毛状根生长受抑制,POD基因表达水平随之上升,POD参与褐化反应。     

Evolution of C4 phosphoenolpyruvate carboxylase in the genus Alternanthera: gene families and the enzymatic characteristics of the C4 isozyme and its orthologues in C3 and C3/C4 Alternantheras

Phosphoenolpyruvate carboxylase (PEPCase, EC 4.1.1.3) is a key enzyme of C₄ photosynthesis. It has evolved from ancestral non-photosynthetic (C₃) isoforms and thereby changed its kinetic and regulatory properties. We are interested in understanding the molecular changes, as the C₄ PEPCases were adapted to their new function in C₄ photosynthesis and have therefore analysed the PEPCase genes of various Alternanthera species. We isolated PEPCase cDNAs from the C₄ plant Alternanthera pungens H.B.K., the C₃/C₄ intermediate plant A. tenella Colla, and the C₃ plant A. sessilis (L.) R.Br. and investigated the kinetic properties of the corresponding recombinant PEPCase proteins and their phylogenetic relationships. The three PEPCases are most likely derived from orthologous gene classes named ppcA. The affinity constant for the substrate phosphoenolpyruvate (K _0.5 PEP) and the degree of activation by glucose-6-phosphate classified the enzyme from A. pungens (C₄) as a C₄ PEPCase isoform. In contrast, both the PEPCases from A. sessilis (C₃) and A. tenella (C₃/C₄) were found to be typical C₃ PEPCase isozymes. The C₄ characteristics of the PEPCase of A. pungens were accompanied by the presence of the C₄-invariant serine residue at position 775 reinforcing that a serine at this position is essential for being a C₄ PEPCase (Svensson et al. 2003). Genomic Southern blot experiments and sequence analysis of the 3′ untranslated regions of these genes indicated the existence of PEPCase multigene family in all three plants which can be grouped into three classes named ppcA, ppcB and ppcC.     

Fine mapping and analyses of <Emphasis Type="Italic">R</Emphasis><Subscript><Emphasis Type="Italic">SC8</Emphasis></Subscript> resistance candidate genes to soybean mosaic virus in soybean

Soybean mosaic virus (SMV) in soybean [Glycine max (L.) Merr.] is a destructive foliar disease in soybean-producing countries worldwide. In this study, F₂, F_2:3, and F_7:11 recombinant inbred lines populations derived from Kefeng No.1 × Nannong 1138-2 were used to study inheritance and linkage mapping of the SMV strain SC8 resistance gene in Kefeng No.1. Results indicated that a single dominant gene (designated R _SC8 ) controls resistance, which is located on chromosome 2 (MLG D1b). A mixed segregating population was developed by selfing two heterozygous plants (RHL153-1 and RHL153-2) at four markers adjacent to the locus and used in fine mapping R _SC8 . In addition, two genomic-simple sequence repeats (SSR) markers BARCSOYSSR_02_0610 and BARCSOYSSR_02_0616 were identified that flank the two sides of R _SC8 . Sequence analysis of the soybean genome indicated that the interval between the two genomic-SSR markers is 200 kb. QRT-PCR analysis of the candidate genes determined that five genes (Glyma02g13310, 13320, 13400, 13460, and 13470) are likely involved in soybean SMV resistance. These results will have utility in cloning, transferring, and pyramiding of the R _SC8 through marker-assisted selection in soybean breeding programs.     

Molecular biology of C4 phosphoenolpyruvate carboxylase: Structure,regulation and genetic engineering

Three to four families of nuclear genes encode different isoforms of phosphoenolpyruvate (PEP) carboxylase (PEPC): C₄-specific, C₃ or etiolated, CAM and root forms. C₄ leaf PEPC is encoded by a single gene (ppc) in sorghum and maize, but multiple genes in the C₄-dicot Flaveria trinervia. Selective expression of ppc in only C₄-mesophyll cells is proposed to be due to nuclear factors, DNA methylation and a distinct gene promoter. Deduced amino acid sequences of C₄-PEPC pinpoint the phosphorylatable serine near the N-terminus, C₄-specific valine and serine residues near the C-terminus, conserved cysteine, lysine and histidine residues and PEP binding/catalytic sites. During the PEPC reaction, PEP and bicarbonate are first converted into carboxyphosphate and the enolate of pyruvate. Carboxyphosphate decomposes within the active site into Pi and CO₂, the latter combining with the enolate to form oxalacetate. Besides carboxylation, PEPC catalyzes a HCO₃ ^--dependent hydrolysis of PEP to yield pyruvate and Pi. Post-translational regulation of PEPC occurs by a phosphorylation/dephosphorylation cascade in vivo and by reversible enzyme oligomerization in vitro. The interrelation between phosphorylation and oligomerization of the enzyme is not clear. PEPC-protein kinase (PEPC-PK), the enzyme responsible for phosphorylation of PEPC, has been studied extensively while only limited information is available on the protein phosphatase 2A capable of dephosphorylating PEPC. The C₄ ppc was cloned and expressed in Escherichia coli as well as tobacco. The transformed E. coli produced a functional/phosphorylatable C₄ PEPC and the transgenic tobacco plants expressed both C₃ and C₄ isoforms. Site-directed mutagenesis of ppc indicates the importance of His¹³⁸, His⁵⁷⁹ and Arg⁵⁸⁷ in catalysis and/or substrate-binding by the E. coli enzyme, Ser⁸ in the regulation of sorghum PEPC. Important areas for further research on C₄ PEPC are: mechanism of transduction of light signal during photoactivation of PEPC-PK and PEPC in leaves, extensive use of site-directed mutagenesis to precisely identify other key amino acid residues, changes in quarternary structure of PEPC in vivo, a high-resolution crystal structure, and hormonal regulation of PEPC expression.Abbreviations OAA oxalacetate - PEP phosphoenolpyruvate - PEPC PEP carboxylase - PEPC-PK PEPC-protein kinase - PPDK pyruvate, orthophosphate dikinase - Rubisco ribulose 1,5-bis-phosphate carboxylase/oxygenase - CAM Crassulacean acid metabolism