Characterization of the wound-inducible protein ipomoelin from sweet potato

The ipomoelin (IPO) gene, a wound- and methyl jasmonate-inducible gene, was isolated from sweet potato (Ipomoea batatas cv. Tainung 57), and previously demonstrated to be regulated by dephosphorylated proteins and calcium ion (Chen Y.-C. et al. Plant Cell and Environment 26, 1373–1383, 2003). In this report, the function of the IPO protein was further studied. The IPO gene was characterized as having one intron and presenting two copies within the genome of sweet potato. The IPO protein appeared 1 d after the leaves of sweet potato were wounded. Surprisingly, the accumulation of the IPO protein remained for 7 d after wounding. Additionally, after the IPO protein was fused to a histidine tag , the His-IPO fusion protein produced from Escherichia coli BL21DE3 was then used to perform the haemagglutination test, which demonstrated that His-IPO fusion protein agglutinated human blood cells. Furthermore, several carbohydrates, including methyl α- d -glucopyranoside, methyl α- d -mannopyranoside, maltose, mannose, glucose, galactose, and lactose, reduced the efficiency of the His-IPO fusion protein in agglutinating human blood cells. These experimental results may indicate that the IPO protein is a lectin , a carbohydrate-binding protein. Notably, the IPO protein retarded the growth and development of silkworm, and thus reduced silkworm survival rates. Therefore, these findings indicate that the function of the IPO protein is to protect plants from insect attack.     

Molecular cloning and nucleotide sequence of cDNA for sporamin,the major soluble protein of sweet potato tuberous roots

Summary Sporamin accounts for more than 80% of the total soluble proteins of tuberous roots of sweet potato, but very little, if any, in other tissues of the same plant. In vitro translation of RNA fractions from the tuberous roots in wheat germ extract and subsequent immunoprecipitation with the antibody to sporamin indicated that this protein is synthesized by membrane-bound polysomes as a precursor 4 000 daltons larger than the mature protein. A cDNA expression library was constructed from the total poly(A)⁺ RNA from the tuberous roots by a vector-primer method, and an essentially full-length cDNA clone for the sporamin mRNA was selected by direct immunological screening of the colonies. Northern blot analysis showed that sporamin mRNA is approximately 950 nucleotides in length and is specifically present in tuberous roots and very little, if any, in leaves, petioles and non-tuberous roots. Nucleotide sequence of the cDNA predicts a 37 amino acid extension in the precursor at the amino-terminus of the mature protein.     

Expression of the ipomoelin gene from sweet potato is regulated by dephosphorylated proteins, calcium ion and ethylene

A wound‐inducible cDNA, ipomoelin (IPO) was isolated from the subtraction library of sweet potato (Ipomoea batatas cv. Tainung 57) and used as a molecular probe to investigate the transduction pathway of wounding signal within plant cells. Following mechanical wounding of the leaves of sweet potato, IPO mRNA accumulation peaked at 6 h and then continuously declined. However, IPO gene expression in the apical unwounded leaves began at 6 h after wounding and continued for a further 10 h. Besides mechanical wounding, methyl jasmonate (MeJA) was identified as a signal transducer leading to the accumulation of IPO mRNA. Treatment with salicylic acid reduced the production of IPO mRNA, further supporting the involvement of the octadecanoid pathway in the signal transduction of wounding in sweet potato. In addition, ethylene was involved in the signal pathway and induced the expression of the IPO gene. Furthermore, the application of okadaic acid, a protein phosphatase inhibitor, blocked the accumulation of IPO mRNA induced by MeJA or ethylene, indicating that activation of the IPO gene by both MeJA and ethylene was via dephosphorylated proteins. The presence of a calcium ion chelator or channel blockers also inhibited the expression of the IPO gene after wounding. However, investigation by confocal scanning microscopy further pointed out that mechanical wounding rather than the application of MeJA induced the accumulation of the calcium ion. These results may indicate that the calcium ion is also involved in the activation of IPO mRNA. In addition, wounding signals the accumulation of calcium ion first and then stimulates the biosynthesis of MeJA in sweet potato. Hence, the reaction sequence of signal transducers, including the calcium ion, MeJA and protein kinase/phosphatase, in the wounding signalling pathway of sweet potato is suggested in this report.     

Aspects of resistance to sweet potato virus disease in sweet potato

In field trials during the first and the second rainy season of 1996 in Uganda, whiteflies were similarly abundant and aphids were absent on three clones of sweet potato (NIS-93–63, cv. Tanzania and cv. New Kawogo) although the three clones differed considerably in their resistance to sweet potato virus disease (SPVD), a complex disease resulting from infection by both the aphid-borne sweet potato feathery mottle virus (SPFMV) and the whitefly-borne sweet potato chlorotic stunt virus (SPCSV). This suggests that vector resistance does not determine the relative SPVD resistance of these genotypes. SPFMV alone had only a low virus titre in sweet potato cvs Tanzania and New Kawogo, became increasingly difficult to detect in plants of these cultivars and was seldom acquired by aphids. However, this resistance to SPFMV was not apparent in plants which were also infected with SPCSV. Plants then had a high SPFMV titre, appeared unable to eliminate SPFMV and provided good sources for aphids to acquire it.     

土壤干旱对转基因甘薯光合曲线的响应

采用盆栽试验的方法,设置适宜水分、中度干旱和重度干旱(土壤田间持水量的75%—80%、60%—65%和35%—40%)等3个土壤水分条件,以叶片同时转入Cu/Zn SOD和APX基因的甘薯和未转基因对照植株为材料,研究它们在不同水分条件下的光合响应特性。结果表明:在不同的土壤水分条件下,转基因(TS)和未转基因(NS)植株光响应曲线的变化趋势均基本一致,但转基因甘薯叶片的光合速率都高于未转基因植株,尤其是在严重的干旱胁迫下两者的差异最为显著,表明同时转入的Cu/Zn SOD和APX抗氧化酶基因有利于甘薯在干旱逆境下维持较高的光合能力。正常的水分水平及中度干旱胁迫下,TS和NS植株叶片的Pmax无明显差别,但在严重干旱条件下TS叶片的Pmax显著高于NS。在本试验中,与适宜水分处理相比,NS植株叶片的表观量子效率(φ)在中度干旱胁迫下就开始显著下降,而TS植株只是轻微下降,到严重干旱时,两者都显著下降,但是TS仍略高于NS植株。随着土壤干旱程度增加,甘薯叶片光补偿点(LCP)增高,光饱和点(LSP)、表观量子效率(φ)、暗呼吸速率(Rd)下降,表明干旱胁迫使气孔关闭,光能利用率降低,同时利用CO2的能力降低,光合产物消耗增加,不利于同化产物的积累,在干旱胁迫条件下,转基因甘薯叶片光补偿点(LCP)、光呼吸增高以及光饱和点下降的幅度均明显小于未转基因植株,这可能是因为转入的抗氧化酶基因提高干旱胁迫下叶片中酶促防御系统的活性,适度缓解了干旱逆境引起的膜脂过氧化伤害。     

Structural differences in full-length cDNAs for two classes of sporamin,the major soluble protein of sweet potato tuberous roots

Summary Sporamin, which accounts for 80% of the total soluble proteins in sweet potato tuberous roots, consists of two polypeptide classes, A and B. The sporamin cDNA clones can also be classified into sporamin A and B subfamilies based on their sequence homologies, with intra-subfamily homologies being much higher than inter-subfamily homologies. The sequence of an essentially full-length cDNA for sporamin B was compared with that for sporamin A. The coding sequences of two cDNAs share 83% sequence homology. The sequences in the 5- and 3-noncoding regions show many deletions in addition to base substitutions. The endpoints of deletions longer than 4 bp match precisely to the endpoints of short direct repeats present in the other sequence, which suggests that these deletions are generated by slipped mispairing during DNA replication. In the 5- and 3-noncoding region of sporamin B cDNA, there are 5 bp direct repeats with sequences complementary to each other. Since most of these repeats are absent in sporamin A cDNA, these structural features may cause a difference in the secondary structure between A and B mRNAs and affect the translational efficiencies or stabilities of the mRNAs. Precursors for both classes of sporamin carry N-terminal extra-sequences which can be separated into a putative signal peptide segment and a segment enriched with basic amino acids. A two-step processing mechanism for the maturation of sporamin is suggested.     

The sweet potato sporamin promoter confers high-level phytase expression and improves organic phosphorus acquisition and tuber yield of transgenic potato

The sweet potato sporamin promoter was used to control the expression in transgenic potato of the E. coli appA gene, which encodes a bifunctional enzyme exhibiting both acid phosphatase and phytase activities. The sporamin promoter was highly active in leaves, stems and different size tubers of transgenic potato, with levels of phytase expression ranging from 3.8 to 7.4% of total soluble proteins. Phytase expression levels in transgenic potato tubers were stable over several cycles of propagation. Field tests showed that tuber size, number and yield increased in transgenic potato. Improved phosphorus (P) acquisition when phytate was provided as a sole P source and enhanced microtuber formation in cultured transgenic potato seedlings when phytate was provided as an additional P source were observed, which may account for the increase in leaf chloroplast accumulation (important for photosynthesis) and tuber yield of field-grown transgenic potato supplemented with organic fertilizers. Animal feeding tests indicated that the potato-produced phytase supplement was as effective as a commercially available microbial phytase in increasing the availability of phytate-P to weanling pigs. This study demonstrates that the sporamin promoter can effectively direct high-level recombinant protein expression in potato tubers. Moreover, overexpression of phytase in transgenic potato not only offers an ideal feed additive for improving phytate-P digestibility in monogastric animals but also improves tuber yield, enhances P acquisition from organic fertilizers, and has a potential for phytoremediation.     

Structural relationship among the members of a multigene family coding for the sweet potato tuberous root storage protein

Sporamin, the major soluble protein of the sweet potato tuberous root, is coded for by a multigene family. Fourty-nine essentially full-length sporamin cDNAs isolated from tuberous root cDNA library have been classified by cross hybridization, restriction endonuclease cleavage pattern and ribonuclease cleavage mapping. All the cDNAs fall into one of the two distinct homology groups, subfamilies A and B, which correspond to the polypeptide classes sporamin A and B, respectively. At least 5 different sequences are detected in both of the 22 sporamin A and 27 sporamin B cDNAs. Comparison of the nucleotide sequences of the coding region of three each of sporamin A and B subfamily members, four from cDNAs and two from genomic clones, indicates that intra-subfamily homologies (94 to 98%) are much higher than inter-subfamily homologies (82 to 84%), and there are deletions or insertions of one or two codons at three locations which characterize each subfamily. Large portions of base substitutions in the coding region accompany amino acid substitutions. In contrast to the coding region, most of the structural differences among the members in the 5 and 3 noncoding regions are deletions or insertions.     

Isolation and characterization of signal transduction mutants of Arabidopsis thaliana that constitutively activate the octadecanoid pathway and form necrotic microlesions

Thionins are a group of antimicrobial polypeptides that form part of the plant's defense mechanism against pathogens. The Thi 2.1 thionin gene of Arabidopsis thaliana has been shown to be inducible by jasmonic acid (JA), an oxylipin-like hormone derived from oxygenated linolenic acid and synthesized via the octadecanoid pathway. The JA-dependent regulation of the Thi 2.1 gene has been exploited for setting up a genetic screen for the isolation of signal transduction mutants that constitutively express the Thi 2.1 gene. Ten cet-mutants have been isolated which showed a constitutive expression of the thionin gene. Allelism tests revealed that they represent at least five different loci. Some mutants are dominant, others recessive, but all cet mutations behaved as monogenic traits when backcrossed with Thi 2.1-GUS plants. Some of the mutants overproduce JA and its bioactive precursor 12-oxophytodienoic acid (OPDA) up to 40-fold while others have the same low levels as the control wildtype plants. Two of the mutants showed a strong induction of both the salicylic acid (SA)- and the JA-dependent signaling pathways, while the majority seems to be affected only in the octadecanoid pathway. The Thi 2.1 thionin gene and the Pdf 1.2 defensin gene are activated independently, though both are regulated by JA. The cet-mutants, except for one, also show a spontaneous leaf cell necrosis, a reaction often associated with the systemic acquired resistance (SAR) pathway.     

甘薯肉桂酸-4-羟化酶基因克隆及序列分析

肉桂酸-4-羟化酶(Cinnamic acid-4-hydroxylase,C4H,EC 1.14.13.11)是苯丙烷途径中第二步反应酶,同时也是花色素苷前体生物合成途径中关键酶。该研究根据植物C4H的同源序列设计引物,通过RTPCR结合RACE的方法,在紫色甘薯中获得了与其相应的C4H基因,命名为Ib C4H(Gen Bank登录号GQ373157)。结果表明:(1)序列分析表明Ib C4H长1 668 bp,编码505个氨基酸,该氨基酸序列与其c DNA序列与Ib C4H蛋白与马铃薯C4H蛋白序列最为接近,与苹果、黑莓、大阿米芹、油菜一致性很高,均在70%以上。(2)二级结构预测表明α-螺旋和无规则卷曲是Ib C4H蛋白最大量的结构元件,而延伸链则散布于整个蛋白中。(3)三维结构建模预测,Ib C4H蛋白具备细胞色素P450氧和铁离子结合位点等典型的C4H结构。该研究结果为进一步了解花色素苷生物合成途径中的作用奠定了基础,也为花青素生物合成分子机理和代谢调控提供了靶位点和理论参考。     

The incidence of sweet potato virus disease and virus resistance of sweet potato grown in Uganda

Sweet potato virus disease (SPVD) was common (25–30% average incidences), and farmers recognised it as an important disease, in sweet potato crops in southern Mpigi, Masaka and Rakai Districts in Uganda, but SPVD was rare in Soroti and Tororo Districts. Whiteflies, which are the vector of sweet potato chlorotic stunt crinivirus (SPCSV) a component cause of SPVD, were correspondingly common on sweet potato crops in Mpigi and rare on crops in Tororo. However, aphids, which are the vectors of sweet potato feathery mottle potyvirus (SPFMV), the other component cause of SPVD, were not found colonising sweet potato crops, and itinerant alate aphids may be the means of transmission. Different sweet potato cultivars were predominant in the different districts surveyed and four local cultivars obtained from Kanoni in S. Mpigi, where whiteflies and SPVD were common, were more resistant to SPVD than four cultivars from Busia in Tororo District, where whiteflies and SPVD were rare. However, nationally released cultivars were even more resistant than the local cultivars from Kanoni. Yield results and interviews with farmers indicated that farmers in S. Mpigi were making compromises in their choice of cultivars to grow, some key factors being SPVD susceptibility, and the yield, taste, and marketability, duration of harvest and in-ground storability of the storage roots. These compromises need to be included in an assessment of yield losses attributable to SPVD.     

Characterization of major proteins in sweet potato tuberous roots

The tuberous roots, but not other organs, of sweet potato contained large quantities of two proteins which accounted for more than 80% of the total proteins. The two proteins, tentatively named sporamins A and B, were monomeric forms with similar M,s (25 000). They were separated from each other by electrophoresis on polyacrylamide gels in a non-denaturing buffer or a buffer containing sodium dodecyl sulphate without being reduced by dithiothreitol. They were very similar to each other with respect to amino acid composition, peptide map and immunological properties. These proteins decreased in preference to other proteins during sprouting. The amino acid sequencing of the amino terminal part of sporamin A suggested that it consists of at least two molecular species with different combinations of a few amino acids.     

A new isopentenyl diphosphate isomerase gene from sweet potato: cloning,characterization and color complementation

Isopentenyl diphosphate isomerase (IDI, EC 5.3.3.2) catalyzes the revisable conversion of 5-carbon isopentenyl diphosphate and its isomer dimethylallyl diphosphate, which are the essential precursors for isoprenoids, including carotenoids. Here we report on the cloning and characterization of a novel cDNA encoding IDI from sweet potato. The full-length cDNA is 1155 bp with an ORF of 892 bp encoding a polypeptide of 296 amino acids, which was designated as IbIDI (GenBank Acc. No: DQ150100). The computational molecular weight is 33.8 kDa and the theoretical isoelectric point is 5.76. The deduced amino acid sequence of IbIDI is similar to the known plant IDIs. The tissue expression analysis revealed that IbIDI expressed at higher level in sweet-potato’s mature leaves and tender leaves than that in tubers, meanwhile, no expression signal could be detected in veins. Recombinant IbIDI was heterologously expressed in engineered Escherichia coli which led to the reconstruction of the carotenoid pathway. In the engineered E. coli, IbIDI could take the role of Arabidopsis IDI gene to produce the orange β-carotene. In summary, cloning and characterization of the novel IDI gene from sweet potato will facilitate our understanding of the molecular genetical mechanism of carotenoid biosynthesis and promote the metabolic engineering studies of carotenoid in sweet potato.     

Agroinfection of sweet potato by vacuum infiltration of an infectious sweepovirus

Sweepovirus is an important monopartite begomovirus that infects plants of the genus Ipomoea worldwide. Development of artificial infection methods for sweepovirus using agroinoculation is a highly efficient means of studying infectivity in sweet potato. Unlike other begomoviruses, it has proven difficult to infect sweet potato plants with sweepoviruses using infectious clones. A novel sweepovirus, called Sweet potato leaf curl virus-Jiangsu (SPLCV-JS), was recently identified in China. In addition, the infectivity of the SPLCV-JS clone has been demonstrated in Nicotiana benthamiana. Here we describe the agroinfection of the sweet potato cultivar Xushu 22 with the SPLCV-JS infectious clone using vacuum infiltration. Yellowing symptoms were observed in newly emerged leaves. Molecular analysis confirmed successful inoculation by the detection of viral DNA. A synergistic effect of SPLCV-JS and the heterologous betasatellite DNA-β of Tomato yellow leaf curl China virus isolate Y10 (TYLCCNV-Y10) on enhanced symptom severity and viral DNA accumulation was confirmed. The development of a routine agroinoculation system in sweet potato with SPLCV-JS using vacuum infiltration should facilitate the molecular study of sweepovirus in this host and permit the evaluation of virus resistance of sweet potato plants in breeding programs.     

Involvement of nitrogen in storage root growth and related gene expression in sweet potato (Ipomoea batatas)

• Nitrogen (N) could affect storage root growth and development of sweet potato. To manage external N concentration fluctuations, plants have developed a wide range of strategies, such as growth changes and gene expression.
• Five sweet potato cultivars were used to analyse the functions of N in regulating storage root growth. Growth responses and physiological indicators were measured to determine the physiological changes regulated by different N concentrations. Expression profiles of related genes were analysed via microarray hybridization data and qRT‐PCR analysis to reveal the molecular mechanisms of storage root growth regulated by different N concentrations.
• The growth responses and physiological indicators of the five cultivars were changed by N concentration. The root fresh weight of two of the sweet potato cultivars, SS19 and GS87, was higher under low N concentrations compared with the other cultivars. SS19 and GS87 were found to be having greater tolerance to low N concentration. The expression of N metabolism and storage root growth related genes was regulated by N concentration in sweet potato.
• These results reveal that N significantly regulated storage root growth. SS19 and GS87 were more tolerant to low N concentration and produced greater storage root yield (at 30 days). Furthermore, several N response genes were involved in both N metabolism and storage root growth.

     

Expression of green-fluorescent protein gene in sweet potato tissues

Green-fluorescent protein (GFP) gene expression, transient and stable after electroporation and particle bombardment, was analyzed in tissues of sweet potato cv.Beauregard. Leaf and petiole tissues were used for protoplast isolation and electroporation. After 48 h, approximately 25–30% of electroporated mesophyll cell protoplasts regenerated cell walls, and of these, 3% expressed GFP. Stable expression of GFP after four weeks of culture was observed in 1.0% of the initial GFP positive cells. In a separate experiment, we observed 600–700 loci expressing GFP 48 h after bombarding leaf tissue or embryogenic calli, and stable GFP-expressing sectors were seen in leaf-derived embryogenic calli after four weeks of protoplast culture without selection. These results demonstrate GFP gene expression in sweet potato tissues. Screening for GFP gene expression may prove useful to improve transformation efficiency and to facilitate detection of transformed sweet potato plants.     

内生型解淀粉芽孢杆菌YTB1407对甘薯根系的促生作用及其调控机理

本实验室从西洋参根中分离筛选获得兼具生防和促生效果的内生型解淀粉芽孢杆菌YTB1407.为调查其应用潜力,以甘薯为材料,以无菌水灌根处理(CK)为对照,采用不同浓度YTB1407菌悬液灌根盆栽甘薯植株,通过对甘薯生长前期3个主要生育时间点YTB1407在植株内的内生定殖检测和根系表型效应比较,筛选菌悬液灌根的最适处理浓度.对根系内源生长素吲哚乙酸(IAA)、细胞分裂素玉米素核苷(ZR)、反式玉米素核糖核苷(t-ZR)的含量和吲哚乙酸氧化酶类中的吲哚乙酸氧化酶(IAAO)、过氧化物酶(POD)和多酚氧化酶(PPO)的活性进行分析.结果表明: YTB1407促进了甘薯生长前期根系统的定殖、不定根幼根的伸长生长及侧根的发生,提高了根系活力;在甘薯生长后期形成了更大的吸收根系生物量和更低的地上部和总根系生物量比.其中OD₆₀₀值为0.50的菌悬液处理(T_0.50)促生效应显著,在甘薯茎叶封垄期的单株块根鲜质量和有效薯块数量最高.YTB1407通过提高ZR、t-ZR含量,降低IAAO活性、提高PPO活性和IAA含量以及(t-ZR+ZR)/IAA,促进块根分化建成初期甘薯不定根幼根向块根的分化;通过降低IAAO、PPO活性和提高IAA含量,降低(t-ZR+ZR)/IAA,促进块根分化建成后期甘薯分化根向块根的建成.