Interaction between day length and phytohormones in the control of potato tuberization in the in vitro culture

We studied the interaction of the day length, cytokinins, and gibberellins in the control of tuberization in potato (Solanum tuberosum L, cv. Desire) plants and derived transgenic plants with the inserted PHYB gene from Arabidopsis encoding the synthesis of phytochrome B apoprotein and put under the control of the 35S CaMV promoter. Plantlets were cultured in vitro on hormone-free MS medium containing 5% sucrose and kinetin (1 mg/l) or/and GA (0.5 and 1.0 mg/l), at long day (LD, a 16-h photoperiod), short day (SD, a 10-h photoperiod), or continuous darkness conditions. The content of cytokinins (Ck, zeatin, and zeatin riboside) in various plant organs was determined by the immunoenzyme method, and GA activity was measured in bioassay with dwarf pea. Potato plant transformation with the PHYB gene enhanced substantially tuber initiation inhibition by LD. Kinetin addition to culture medium enhanced tuberization and reduced Ck content in aboveground shoots and Ck redistribution in the favor of underground organs. GA addition to the culture medium suppressed tuberization and induced Ck accumulation in aboveground organs. We concluded that Ck role in tuberization depends on their predominant localization in above- or underground potato organs. The involvement of Ck and GA in the competitive relations between growing tubers and shoots is considered.     

Photoperiodic and Hormonal Control of Tuberization in Potato Plants Transformed with the <Emphasis Type="Italic">PHYB</Emphasis> Gene from <Emphasis Type="Italic">Arabidopsis</Emphasis>

We studied photoperiodic and hormonal regulation of tuberization in wild-type potato (Solanum tuberosum L., cv, Desiree) plants and derivative transgenic plants harboring the PHYB gene from Arabidopsis, which encodes the phytochrome B apoprotein, under the control of the cauliflower mosaic virus 35S promoter. Plants were cultured on hormone-free Murashige and Skoog nutrient medium containing 5% sucrose or on the same medium supplemented with 1 mg/l kinetin under conditions of long day (LD, 16 h), short day (SD, 10 h), or SD with interrupted long night. We estimated cytokinins (zeatin and zeatin riboside) in underground and aboveground plant organs by the ELISA technique and GA activity in a bioassay with dwarf pea seedlings. Under LD conditions, transgenic plants produced substantially less tubers than wild-type plants. Kinetin addition to the culturing medium resulted in stimulation of tuberization under LD conditions, especially pronounced in the PHYB plants. The content of cytokinins and the activity of GA were much higher under LD conditions, especially in leaves. The total level of both phytohormones was higher in transformed as compared to wild-type plants. A relation of phytochrome-dependent tuberization to the hormonal status of underground and above-ground plant organs and possible reasons for kinetin stimulatory effect on this process are discussed.     

Phytochrome B mediates the photoperiodic control of tuber formation in potato

To determine whether phytochrome B is involved in the response of potato plants to photoperiod, a potato PHYB cDNA fragment was inserted in the antisense orientation behind the 35S CaMV promoter in Bin19 and this construct was transformed into Solanum tuberosum ssp. andigena plants which normally require short days for tuberization. Two independent transformants were obtained that had much lower levels of PHYB mRNA and protein, and which exhibited phenotypes characteristic of phyB mutants, for example, elongated stems and decreased chlorophyll content. The level of phyA, and of several phytochrome A-controlled responses, was unaffected in these plants. The photoperiodic control of tuberization in these antisense PHYB plants was abolished, the plants tuberizing in short day, long day, or short day plus night break conditions. This result shows that phytochrome B is required for the photoperiodic control of tuberization in potato ( Solanum tuberosum ssp. andigena ) and that it regulates this developmental process by preventing tuber formation in non-inductive photoperiods rather than by promoting tuberization in inductive photoperiods.     

Sucrose application causes hormonal changes associated with potato tuber induction

Stems of potato plants (Solanum tuberosum L. cv. Dianella) were immersed in solutions containing water (control), sucrose, glucose, paclobutrazol, and gibberellic acid. The effects of these treatments on the ethylene release, levels of endogenous gibberellins, glucose, sucrose, and starch were correlated with tuberization of nodal cuttings, excised from potato stems. Paclobutrazol and sucrose improved the percent of tuberization and/or increased tuber weight. In contrast, GA₃ inhibited tuber formation compared with the control. The level of endogenous free GAs was negatively correlated with percent tuberization. However, the level of conjugated GAs was positively correlated with both percent tuberization and tuber weight. The effect of sucrose on potato tuber induction in relation to the possible role of sucrose in GA-conjugate formation is discussed.     

Phytochrome F plays critical roles in potato photoperiodic tuberization

The transition to tuberization contributes greatly to the adaptability of potato to a wide range of environments. Phytochromes are important light receptors for the growth and development of plants, but the detailed functions of phytochromes remain unclear in potato. In this study, we first confirmed that phytochrome F ( St PHYF ) played essential roles in photoperiodic tuberization in potato. By suppressing the St PHYF gene, the strict short‐day potato genotype exhibited normal tuber formation under long‐day ( LD ) conditions, together with the degradation of the CONSTANTS protein St COL 1 and modulation of two FLOWERING LOCUS  T ( FT ) paralogs, as demonstrated by the repression of St SP 5G and by the activation of St SP 6A during the light period. The function of St PHYF was further confirmed through grafting the scion of St PHYF ‐silenced lines, which induced the tuberization of untransformed stock under LD s, suggesting that St PHYF was involved in the production of mobile signals for tuberization in potato. We also identified that St PHYF exhibited substantial interaction with St PHYB both in vitro and in vivo . Therefore, our results indicate that St PHYF plays a role in potato photoperiodic tuberization, possibly by forming a heterodimer with St PHYB .     

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.     

Phenotypic changes in T-cyt-transformed potato plants are consistent with enhanced sensitivity of specific cell types to normal regulation by root-derived cytokinin

From over forty independently isolated potato lines transformed with wild-type and promoter-mutated T-cyt genes [12], a number of lines were selected for examination of phenotypic changes in growth and development for plants grown in soil in a controlled environment. The three lines chosen for most detailed examination showed a wide spectrum of phenotypic changes. In comparisons with control potato cv. Désirée, the plants of one line had a two- to three-fold increase in biomass production during early vegetative growth, advanced senescence and a shortened plant life-span. Another line showed abnormal cellulytic senescence. In two lines there were increases in tuber numbers and more skewed tuber size distributions which correlated with reduced shoot apical dominance and shortened dormancy of the stored tubers. None of the lines showed altered timing of onset of tuberization or flowering, although tuberization was consistently delayed when expressed as a function of increasing total plant weight. A hypothesis is proposed to explain the diverse phenotypes which postulates that (1) T-cyt transformation causes enhanced sensitivity to cytokinins in specific types of shoot cells which are already targets for regulation by normal root-derived cytokinins; (2) two distinct types of shoot target cells are present, one in shoot meristems and one in leaves; (3) the two types can acquire enhanced sensitivity, either separately or in combination depending on the particular T-cyt transformation event. The scope for using the transformed plants in subsequent physiological, biochemical and molecular studies, aimed at examining the molecular basis of the model or selected consequences of T-cyt transformation in altering regulation of potato plant growth and development, is discussed. The attention is drawn to the possible involvement at the subcellular level of sucrose phosphate synthase in mediating the phenotypic effects caused by T-cyt transformation.     

马铃薯块茎发育机理及其基因表达

马铃薯(Solanum tuberosum L.)块茎是有块茎马铃薯植物的地下变态器官,它由匍匐茎顶端膨大形成。对于马铃薯块茎形成的生理机制已有许多研究,这些研究表明,块茎发生受许多因素的影响,总体来讲短日照、较低的温度以及离体条件下培养基较高的蔗糖浓度等有利于块茎形成,同时,块茎形成过程中内源激素亦发生一系列变化。然而,对于块茎形成中相关基因表达,进而调控块茎形成的系统研究目前还较滞后。已有研究显示,块茎形成与膨大涉及到一系列基因的表达与关闭,同时它也与淀粉合成和块茎储藏蛋白基因的表达有关。综述了这一领域现有的研究进展。     

马铃薯块茎发育机理及其基因表达

马铃薯（Solanum tuberosum L.)块茎是有块茎马铃薯植物的地下变态器官,它由匍匐茎顶端膨大形成,对于马铃薯块茎形成的生理机制已有许多研究,这些研究表明,块茎发生受许多因素的影响,总体来讲短日 照,较低的温度以及离体条件下培养基较高的蔗糖浓度等有利于块茎形成,同时,块茎形成过程中内源激素亦发生一系列变化,然而,对于块茎形成中相关基因表达,进而调控块茎形成的系统研究目前还较滞后,已有研究显示,块茎形成与膨大涉及到一系列基因的表达与关闭,同时它也与淀粉合成和块茎储藏蛋白基因的表达有关,综述了这一领域现有的研究进展。     

Down regulation of StGA3ox genes in potato results in altered GA content and affect plant and tuber growth characteristics

GA biosynthesis and catabolism has been shown to play an important role in regulating tuberization in potato. Active GAs are inactivated in the stolon tips shortly after induction to tuberization. Overexpression of a GA inactivation gene results in an earlier tuberization phenotype, while reducing expression of the same gene results in delayed tuberization. In addition, overexpression of genes involved in GA biosynthesis results in delayed tuberization, while decreased expression of those genes results in earlied tuberization. The final step in GA biosynthesis is catalysed by StGA3ox1 and StGA3ox2 activity, that convert inactive forms of GA into active GA₁ and GA₄. In this study we cloned StGA3ox2 gene in an RNAi construct and used this construct to transform potato plants. The StGA3ox2 silenced plants were smaller and had shorter internodes. In addition, we assayed the concentrations of various GAs in the transgenic plants and showed an altered GA content. No difference was observed on the time point of tuber initiation. However, the transgenic clones had increased number of tubers with the same yield, resulting in smaller average tuber weight. In addition, we cloned the promoter of StGA3ox2 to direct expression of the GUS reporter gene to visualize the sites of GA biosynthesis in the potato plant. Finally, we discuss how changes of several GA levels can have an impact on shoot, stolon and tuber development, as well as the possible mechanisms that mediate feed-forward and feed-back regulation loops in the GA biosynthetic pathway in potato.     

The effect of an elevated cytokinin level using the ipt gene and N 6-benzyladenine on single node and intact potato plant tuberization in vitro

Two models of potato (Solanum tuberosum L.) tuberization in vitro (intact plants and single nodes) were used to study the role of cytokinins in this process. We applied hormone in two different ways. The exogenous addition of 10 mg · L^-1 N ⁶-benzyladenine (BA) into the tuberization medium resulted in advanced tuber formation in intact plants, and microtubers appeared 10–20 days earlier than in the experiments in which no cytokinin was supplied. Transformation with the Agrobacterium tumefaciens ipt gene provided potato clones with endogenously elevated cytokinin levels (3–20 times higher zeatin riboside content in different clones). The onset of tuberization in intact ipt-transformed plants with low transgene expression was advanced in comparison with control material, and exogenously applied BA further promoted the tuberization process. On the contrary, tuberization was strongly inhibited in ipt-transformed nodes, and an external increase of the cytokinin level caused complete inhibition of expiant growth. In untransformed (control) nodes cytokinin application resulted in primary and secondary tuber formation, which depended on the BA concentration in cultivation media.Abbreviations BA N ⁶-benzyladenine - PCR polymerase chain reaction - HPLC high performance liquid chromatography - ELISA enzyme-linked immunosorbent assay - NAA -naphthylacetic acid     

Sucrose increases calcium-dependent protein kinase and phosphatase activities in potato plants.

The effect of sucrose on tuber formation, calcium-dependent protein kinase (CDPK) and phosphatase activities was analysed using in vitro cultured potato plants. In short treatments, sucrose induced CDPK and phosphatase activities. In long treatments, sucrose induced tuber formation in the absence of other tuber inducing stimuli. Sorbitol caused a minor increase in CDPK activity and affected plant morphology but did not induce tuber development. The addition of the protein kinase inhibitor Staurosporine precluded sucrose-induced tuberization. Altogether, our results suggest that phosphorylation/dephosphorylation events are involved in sucrose-induced tuber development.     

Relative importance of maltose and sucrose supplied during a 2-step potato microtuberization process

A 2-stage in vitro tuberization process comprising first micropropagation via nodal explants and then tuber induction in the resultant in vitro plantlets was studied using 2 cultivars of potato, Iwa and Daeji. In particular, the effects on both plantlet growth and subsequent in vitro tuberization of Murashige and Skoog (1962) basal medium containing either sucrose or maltose, each at 3 % (w/v), used for micropropagation were investigated. Sucrose and maltose were found to be equally effective in supporting development of vigorous plantlets from the nodal explants of both potato cultivars. Upon transfer to a medium with an optimised level of sucrose (i.e. 8 %, w/v) for in vitro tuberization, only the plantlets previously grown in the sucrose-containing medium were capable of forming more microtubers of the larger size category (greater than 0.5 g). The relative importance of sucrose supply at the mircropropagation stage was further confirmed when the resultant plantlets grown in the 3 % sucrose-containing medium were transferred to an in vitro tuberization medium containing either sucrose or maltose, each at 8 % (w/v). In this experiment, maltose and sucrose had indistingushable effects on in vitro tuberization.     

Regeneration and characterization of plants from potato root lines transformed by Agrobacterium rhizogenes

Summary Transformed root lines were obtained after infection of leaf segments and tuber discs of tetraploid potato cvs Bintje and Desirée with Agrobacterium rhizogenes. In response to shoot induction, about 10% of the root lines produced shoots through callus formation. The tests for opine suggest that all 26 shoot lines of cv Bintje (Ri-Bintje) and 13 of Desirée (Ri-Desirée) were transformed. All shoot lines were tetraploid except for one octoploid subshoot line of cv Desirée; no aneuploids were observed. With the exception of two shoot lines derived from the same root line, all other Ri-Bintje plants showed a pattern of phenotypic variation, generally observed among transformed plants. In contrast, the phenotype of Ri-Desirée plants was uniform and normal; variation was observed in tuber form and size. Phenotypic variation observed among Ri-plants appeared to be mainly root line-dependent, particularly for height of plants and tuber size and form. Variation was also observed within root and shoot lines and was more pronounced among the Ri-Bintje plants. Segregation of phenotypic characteristics was observed among transformed plants, resulting in the occurrence of phenotypes resembling the control. Chromosomal stability and the frequent reversion to normal phenotype of Ri-plants make A. rhizogenes particularly suitable as a virulence vector in the binary transformation system for the transfer of desirable genes.