Studies on the biochemical basis of physiological processes in the potato tuber

Summary The breakdown of starch in potato tubers which starts when buds begin to grow, stops if the sprouts are removed. The sprout controls the utilization and translocation of food reserves from the tuber. Movement of reserves can occur over the whole cross section of the tuber and is not restricted to the vascular shell. The presence of a growing sprout does not affect the permeability of the tuber tissue to sugar or amino acid.Previous part: Edelman and Singh (1968).     

Characterization of the early events of potato tuber development

The early events of potato ( Solanum tuberosum L. cv. Superior) tuberization were examined by using a model system of axillary bud tuber development from petiole-leaf single-node cuttings. Both fresh weight and starch accumulation were monitored to establish a developmental framework for morphological changes. Fresh weight and starch content began to increase in axillary buds after 2 days. Visible changes in bud morphology could be detected 4 days after the start of incubation. Substantial increases in both total protein and total RNA were observed at the onset of tuber morphology. Immunoblot analysis showed that the major tuber protein, patatin, could be initially detected in day 4 buds and that a 22-kDa proteinase inhibitor could be initially detected at day 8. Northern blot analysis corroborated this pattern of accumulation at the RNA level for both protein types. Substantial accumulation of the two proteinase inhibitor mRNAs occurred later than patatin mRNA accumulation. The results of this study showed that there is considerable accumulation of both protein and mRNA occurring during the early stages of tuber development prior to the substantial accumulation of the major tuber storage proteins.     

Patatin and four serine proteinase inhibitor genes are differentially expressed during potato tuber development

A highly efficient and synchronousin vitro tuberization system is described. One-node stem pieces from potato (Solanum tuberosum cv. Bintje) plants grown under short day-light conditions containing an axillary bud were cultured in the dark on a tuber-inducing medium. After 5 or 6 days all axillary buds started to develop tubers. To study gene expression during tuber development, RNA isolated from tuberizing axillary buds was used for bothin vitro translation and northern blot hybridizations. The genes encoding the proteinase inhibitors I and II (PI-I and PI-II), a Kunitz-and a Bowman-Birk-type proteinase inhibitor were already expressed in uninduced axillary buds. The length of the day-light conditions differently influenced the expression level of the individual genes. In addition, the expression of each of these genes changed specifically during the development of the axillary bud to tuber. In contrast to the expression of these proteinase inhibitor genes, patatin gene expression was only detectable from the day tuberization was manifested as a radial expansion of the axillary bud.These results are discussed with respect to the regulation of the expression of the genes studied in relation to the regulation of tuber development.     

类芽孢杆菌QHZ11-gfp在马铃薯植株上的定殖特征及促生效果

[背景] 生防菌在作物根系的有效定殖是其功能发挥的前提,而直观的跟踪技术和有效的定量方法是研究生防菌根系分布规律的重要工具。[目的] 研究马铃薯黑痣病病原菌立枯丝核菌（Rhizo ctonia solani） JT18的拮抗菌QHZ11在马铃薯植株上的定殖特征及对马铃薯的促生效果。[方法] 采用绿色荧光蛋白（Green Fluorescent Protein,GFP）对QHZ11进行标记,将标记菌株菌悬液、生物有机肥和无菌水分别接种至灭菌土壤,通过激光共聚焦显微技术和实时荧光定量PCR等方法观察和测定标记菌株在马铃薯植株不同部位的定殖特征、数量变化及对马铃薯的促生效果。[结果] pHAPII质粒成功导入QHZ11并可稳定遗传40代,记为QHZ11-gfp;菌株标记前后的菌落形态、生长曲线和对R.solani JT18的拮抗能力等基本一致。从第7天开始,相继在马铃薯芽上和根上发现了绿色荧光,说明QHZ11-gfp成功定殖到了马铃薯的芽、根等部位。QHZ11-gfp在根系和匍匐茎的定殖数量均呈现先升高至块茎形成期达到峰值后下降的趋势,并且在整个生育期根系的定殖数量始终大于匍匐茎。菌悬液和生物有机肥处理均显著促进了马铃薯根系的生长,并通过增加株高等农艺性状提高了块茎产量。其中,生物有机肥处理在各部位的荧光强度、定殖数量和对马铃薯的促生效果均显著优于菌悬液。[结论] QHZ11-gfp可在马铃薯植株上成功定殖并对马铃薯有良好的促生效果,将其制成生物有机肥促进了其定殖,使促生效果也更好。     

Cell Cycling and the Fate of Potato Buds

The cell cycling characteristics of the regions of the apicalmeristems of underground shoots and buds of Solanum tuberosumL. were investigated by stathmokinesis and labelling. The apicaldomes of orthotropic shoots produce cells at twice the elementalrate of those of stolons, and their youngest leaf primordiaat twelve times the rate. Changing the fate of stolons so thatthey will become orthotropic by decapitating the tuber sproutsthat bear them results within 24 h in a general increase incell production especially in the leaf primordia. Axillary buds on tuber sprouts induced to become precursorsof orthotropic shoots instead of stolons undergo a spectacularincrease in cell division within 24 h in all regions, especiallyin the primordia and bud anlagen where the rate increases 20-foldor more. The summit is slower to react than other regions, but,by 24 h, its rate of cell division increases 11-fold and itis contributing 14 cells per day to the flanks from its 80 cells. In all the axillary buds the rate of mitosis in the summit ishalf that of the flanks of the apical dome, but, in both stolonsand orthotropic underground shoots, the rate is higher in thesummit than in the flanks or rib meristem. The results are discussed in relation to what is known of cellcycling changes after floral evocation. Solanum tuberosum L., potato, fate, cell division, apical meristem, stathmokinesis     

Deoxyuridine triphosphatase expression defines the transition from dormant to sprouting potato tuber buds

Identification of molecular markers defining the end of tuber dormancy prior to visible sprouting is of agronomic interest for potato growers and the potato processing industry. In potato tubers, breakage of dormancy is associated with the reactivation of meristem function. In dormant meristems, cells are arrested in the G₁/G₀ phase of the cell cycle and re-entry into the G₁ phase followed by DNA replication during the S phase enables bud outgrowth. Deoxyuridine triphosphatase (dUTPase) is essential for DNA replication and was therefore tested as a potential marker for meristem reactivation in tuber buds. The corresponding cDNA clone was isolated from potato by PCR. The deduced amino acid sequence showed 94% similarity to the tomato homologue. By employing different potato cultivars, a positive correlation between dUTPase expression and onset of tuber sprouting could be confirmed. Moreover, gene expression analysis of tuber buds during storage time revealed an up-regulation of the dUTPase 1 week before visible sprouting occurred. Further analysis using an in vitro sprout assay supported the assumption that dUTPase is a good molecular marker to define the transition from dormant to active potato tuber meristems.     

The Control of Branch Growth on Potato Tubers: II. THE PATTERN OF SPROUT GROWTH

Following the end of dormancy or after desprouting, many budson a potato tuber start to grow. However, if the storage temperaturefavours rapid growth, a number may remain inhibited. After atime, the smaller sprouts stop growing. This inhibition affectsonly those sprouts below a certain length, which is proportionalto the length of the longest sprout. This critical length isrelatively greater for small tubers than for large ones (i.e.longer sprouts are inhibited); it is also greater for tubersstored under dry conditions than for those under moist conditions.The results are interpreted in terms of a correlative inhibitior,continuously produced under the influence of growing buds andcontinuously destroyed as it moves up into all stems. It issuggested that in the terminal bud of the stem there is a sensitiveregion which controls the growth of the other stem tissues andon which the inhibitor acts. It stems longer than the criticallength the inhibitor is possibly inactivated before it reachesthis sensitive tissue; in shorter stems the inhibitor acts onthe tissue and hence inhibits stem elongation.     

Overexpression of jasmonic acid carboxyl methyltransferase increases tuber yield and size in transgenic potato

Jasmonates control diverse plant developmental processes, such as seed germination, flower, fruit and seed development, senescence and tuberization in potato. To understand the role of methyl jasmonate (MeJA) in potato tuberization, the Arabidopsis JMT gene encoding jasmonic acid carboxyl methyltransferase was constitutively overexpressed in transgenic potato plants. Increases in tuber yield and size as well as in vitro tuberization frequency were observed in transgenic plants. These were correlated with JMT mRNA level––the higher expression level, the higher the tuber yield and size. The levels of jasmonic acid (JA), MeJA and tuberonic acid (TA) were also higher than those in control plants. Transgenic plants also exhibited higher expression of jasmonate-responsive genes such as those for allene oxide cyclase (AOC) and proteinase inhibitor II (PINII). These results indicate that JMT overexpression induces jasmonate biosynthesis genes and thus JA and TA pools in transgenic potatoes. This results in enhanced tuber yield and size in transgenic potato plants.     

Immunolocalisation of two tropinone reductases in potato (Solanum tuberosum L.) root, stolon, and tuber sprouts

Tropinone reductases (TRs) are essential enzymes in the tropane alkaloid biosynthesis, providing either tropine for hyoscyamine and scopolamine formation or providing pseudotropine for calystegines. Two cDNAs coding for TRs were isolated from potato (Solanum tuberosum L.) tuber sprouts and expressed in E. coli. One reductase formed pseudotropine, the other formed tropine and showed kinetic properties typical for tropine-forming tropinone reductases (TRI) involved in hyoscyamine formation. Hyoscyamine and tropine are not found in S. tuberosum plants. Potatoes contain calystegines as the only products of the tropane alkaloid pathway. Polyclonal antibodies raised against both enzymes were purified to exclude cross reactions and were used for Western-blot analysis and immunolocalisation. The TRI (EC 1.1.1.206) was detected in protein extracts of tuber tissues, but mostly in levels too low to be localised in individual cells. The function of this enzyme in potato that does not form hyoscyamine is not clear. The pseudotropine-forming tropinone reductase (EC 1.1.1.236) was detected in potato roots, stolons, and tuber sprouts. Cortex cells of root and stolon contained the protein; additional strong immuno-labelling was located in phloem parenchyma. In tuber spouts, however, the protein was detected in companion cells.     

马铃薯全生育期内根际微生物组变化规律

[目的]陆生植物根际环境与土壤中的微生物菌群关系密切,其根际微生物群落动态极可能直接影响着植物健康及养分高效利用。虽然根际益生菌已被证实可用于提高作物生产力,但由于缺乏对这些菌群组成动态变化规律的认识了解,它们的开发受到限制。研究马铃薯全生育期根际菌群的动态变化规律,探讨根际菌群变化与马铃薯发育时期的相关性,为针对马铃薯不同生长时期开发专用生物益生菌肥奠定理论基础。[方法]本研究着眼于马铃薯田间全生命周期微生物组动态变化,通过Illumina MiSeq高通量测序技术对不同时间点马铃薯根际细菌16S rRNA基因V3-V4区和真菌ITS区测序并对操作分类单位(OTU)进行聚类,分析样品间微生物群落的多样性特征,并通过机器学习的方法建立模型,将根际菌群与田间马铃薯发育时间相关联。[结果]根际菌群在马铃薯各个发育阶段随时间变化明显,营养生长阶段的微生物群落结构发生了显著变化,随着结薯期的开始逐渐稳定,直到块茎成熟后期根际菌群再次出现较大变化,且在不同施肥处理间呈现较大差异。进一步基于模型挖掘了与马铃薯发育时间相关联的22个特征细菌类群和16个特征真菌类群,其中苗期和结薯末期的特征类群分别为梭菌(Clostridium)和放线菌(Actinobacteria)。[结论]马铃薯的生长发育时期是影响根际微生物群落组成的主要因素,益生菌肥的添加主要影响马铃薯结薯末期的细菌微生物菌群结构。     

A role for symplastic gating in the control of the potato tuber life cycle

The control of the potato tuber life cycle has been the subject of significant interest over many years. A number of different approaches have been adopted and data is available regarding hormonal, metabolic and gene expression changes that occur over the tuber life cycle. Despite this intense effort, no unifying model for the control of the potato tuber life cycle has emerged. We have undertaken a detailed analysis of the tuber life cycle utilising physiological, biochemical and cell-biological techniques. It has emerged that a major factor contributing to both tuber induction and dormancy break is symplastic gating which controls the allocation of resources to meristematic or vegetative tissues. Future challenges include the determination of factors regulating symplastic gating at the molecular level and the extrapolation of these findings to other systems.Key words: development, tuber, potato     

The Control of Branch Growth on Potato Tubers: III. THE BASIS OF CORRELATIVE INHIBITION

Correlatively inhibited lateral buds on potato tubers were suppliedwith various nutrient solution through the surfaces of leafprimorida. The media, which also supported the growth of isolatedbuds in tissue culture, stimulated the growth of the dominant(growing) sprotus but the inhibition was not due to a shortageof nutrients. The neutral fraction of the ether extract frompotato tubers bearning inhibited sprotus contained a substancesor substances capable, at physiological concentrations, of inhibitingthe growth of buds both in situ and when isolated. Buds on-eyepieceswere not inhibited when supplied with a tissue-culture mediumas well as the neutral fraction. The latter contained both growth-inhibitingand growth-promoting substances. The inhabitor complex was partiallypurified. It was soluble in water and ether and was most unstable.When treated with fluorescein followed by bromine it gave acharacteristic reddish-brown fluorescence. Attempts to establishits chemical nature were unsuccessful. The available evidenceindicated that the substance(s) was effective in preventingthe extension of potato buds at concentrations approximatingto those found in situ and that it disappeared from tuber tissuewithin 24 h of removing the growing sprouts. It is suggestedthat this complex, which is rapidly metabloized in tissue, isthe prime component involved in apical dominance. Nutrient supplydoes not appear to be directly involved although a ready supplyof nutrients can partially offset the effect of the inhibitor.     

Synthesis of intraspecific somatic hybrids of Solanum tuberosum: assessments of morphological, biochemical and nematode (Globodera pallida) resistance characteristics

In an attempt to produce novel agronomic traits, a number ofintraspecific somatic hybrid plants have been produced followingleaf mesophyll protoplast fusion between S. tuberosum dihaploidclones PDH 40 (possessing good tuber shape and yield) and PDH417 (possessing resistance to potato cyst nematode, G. pallida).PDH 417 protoplast-derived calli failed to regenerate plantsusing the described culture conditions preventing this parentaltype amongst the mass of regenerated fusion products. Initially,somatic hybrid plants were selected based on differential pigmentationin tuber sprouts and where possible on petal colour. Differentialmobility of patatin bands in electrophoresed tuber extractsfurther confinned hybridity. The intraspecific somatic hybridsalso showed different levels of resistance to G. pallida pathotypesPa2 and Pa3 in the somatic hybrid plants examined. Key words: Somatic hybridization, dihaploids, patatin, nematode resistance, Solanum tuberosum, potato     

Bisanthraquinones,Inhibitors of Plant Transformation

A potato tuber disk assay of culture broths which had been confirmed to show neither antibacterial nor phytotoxic activity resulted in the discovery of a novel type of crown gall formation inhibitors, julimycin B-II and julichrome Q_1.3 These two bisanthraquinones, products of Streptomyces sp. TM-71, inhibited crown gall formation on potato tuber disks at a minimum inhibitory dose of 1.6 μg/disk without affecting the growth of Agrobacterium tumefaciens or the germination of alfalfa seeds.