A Study of the graft union in in vitro micrografted apple

Light microscopy was used to study graft union formation in in vitro micrografts of tissue cultured apple (Malus domestica. Borkh). Micrografts were constructed using horizontal incisions to form the grafting surface, and placing the cut ends of rootstock and scion into sterile silicon tubing to permit graft formation to occur.The outer morphological and histological development was similar for different stock-scion micrograft combinations but graft union formation was slower in heterografts than in autografts. Initial leaf expansion at the scion shoot apex occurred in all micrografted plantlets within 1–4 days and was not indicative of graft success. Progressive scion growth and development could be used as an indication of graft success by ten to fourteen days after grafting and probably was related to establisment of cell to cell contact at the graft interface. Microscopy showed initiation of callus proliferation in the vascular cumbium and the pith ten days after grafting. Differentiation was observed subsequently and this was reflected in scion development. Longitudinally orientated cambial cells began to differentiate between twenty and forty days after grafting, and formed a bridge between the vascular cylinders of scion and rootstock. The scions at this stage had as many as eight newly expanded leaves and micrografts were strong enough to permit silicon sleeve removal without damage. Continuity of new vascular elements in rootstock and scion was established around forty days. New vascular elements curved slightly in towards the pith to form a c shaped bridge across the graft union. Vascular development continued until it reached completion after six months.     

巴西橡胶树嫁接接合区接穗和砧木径向生长差异的研究

采用树皮嫁接后不锯砧和光镜观察的方法,研究了巴西橡胶树(Hevea brasiliensis)嫁接后8个月的接合区接穗和砧木木质部径向生长的差异现象。结果表明,接合区接穗木质部的径向生长普遍地小于砧木,这种生长差异是由接穗和砧木亲本固有生长特性的差异引起的,与嫁接亲和性无关。(1)对于同一无性系,接穗的发育阶段决定其生长能力,幼态接穗新分化的木质部显著地大于老态接穗,而两类接穗旁边的砧木之间没有明显差别。(2)砧木生长势明显地影响接穗木质部的生长,砧木生长势越强,砧木和接穗的生长就越快,两者的径向差异也越大。(3)同一砧木上各品系接穗木质部生长差异取决于接穗自身的生长特性,砧木的生长不受接穗品系的明显影响。显微观察表明橡胶树的嫁接是亲和的,接穗新分化的木质部镶嵌在砧木新分化的木质部中,维管组织如导管上下连接畅通,砧穗树皮厚度一致,愈合良好。     

Changes in the anatomical structure of tree rings of the rootstock and scion in the heterografts of Siberian pine

The analysis of the anatomical characteristics of tree rings of the Pinus sibirica scions and Pinus sylvestris rootstocks is presented. The main anatomical features maintain the seasonal dynamics characteristic of the reference (ungrafted) trees of scion and rootstock, pointing to the stability of the genetic control of the xylem differentiation. However, various anatomical characteristics are reduced for rootstocks and increased for scions relative to the reference trees. A mechanism consistent with our results is that the graft union zone creates a barrier for the ascending and descending transport of substances, including phytohormones. The reaction of the scion and rootstock to climatic factors is weakened relative to the reaction of the reference trees. Thus, the presumed shift towards phytohormone disbalance reduces the influence of external factors on xylem differentiation. The interannual variation of the individual characteristics of the scions and rootstocks is increased relative to the reference trees, reflecting either the influence of the graft partners on each other or the non-uniform distribution of the growth regulators across the graft union. Thus, heterografts can be used to evaluate the interaction of the internal and external mechanisms of xylem differentiation.     

Survival capacity of cacao top grafted with scions infected by vascular streak dieback pathogen: potential source of the disease long-distance spread

Abstract

Vascular streak dieback (VSD) disease, caused by Ceratobasidium theobromae, is a significant cocoa diseases in Indonesia. Planting materials are often produced by top grafting raising the possibility that VSD may be spread through the use of infected grafting materials. When scions from VSD-infected stems were used in grafting, both the rootstock and new growth from the scion developed symptoms of VSD. Infected scions often failed to establish when used for top grafting. This finding proves that the use of infected scions when top grafting can result in infected planting material with potential for spreading VSD.     

The Function of Phloem Connections in Regenerating In Vitro-Grafts*

In order to answer the question whether functioning phloem connections exist between graft partners, phloem transport has been studied in cultured explant-grafts after application of ¹⁴C-sucrose and carboxyfluorescein (CF) to the scion. Autografts of Lycopersicon esculentum and Helianthus annuus were investigated at various regeneration periods. Ungrafted internodes served as controls. A segmental analysis was used to determine the tissue distribution of ¹⁴C-sucrose in a graft. The ¹⁴C-profiles obtained show that sucrose translocation across the graft interface started 4 days after grafting and increased later. The observed translocation appears to occur via wound phloem, since at this time the first complete wound-phloem bridges (shown as files of aniline-blue-positive sieve plates) traverse the graft interface. In 7-d-old autografts, sucrose transport across the graft interface returned to normal again, as indicated by the distribution of the label. In addition, ¹⁴C-profiles reveal accumulation of label in sink tissues. Here the basal callus of the stock, and temporarily the graft union itself, represent the main sinks for labelled sucrose. Translocation of CF was analyzed in hand sections of the grafts. The beginning of translocation into the stock was confirmed with the dye. Moreover, effective phloem translocation across the graft interface, visualized with CF, could undoubtedly be assigned to wound-phloem bridges reconnecting the cut vascular bundles of scion and stock. Thus, the function of phloem connections in regenerated in vitro-grafts is directly shown.     

Long‐distance ABA transport can mediate distal tissue responses by affecting local ABA concentrations

Environmental stresses that perturb plant water relations influence abscisic acid (ABA) concentrations, but it is unclear whether long‐distance ABA transport contributes to changes in local ABA levels. To determine the physiological relevance of ABA transport, we made reciprocal‐ and self‐grafts of ABA‐deficient flacca mutant and wild‐type (WT) tomato plants, in which low phosphorus (P) conditions decreased ABA concentrations while salinity increased ABA concentrations. Whereas foliar ABA concentrations in the WT scions were rootstock independent under conditions, salinity resulted in long‐distance transport of ABA: flacca scions had approximately twice as much ABA when grafted on WT rootstocks compared to flacca rootstocks. Root ABA concentrations were scion dependent: both WT and flacca rootstocks had less ABA with the flacca mutant scion than with the WT scion under conditions. In WT scions, whereas rootstock genotype had limited effects on stomatal conductance under conditions, a flacca rootstock decreased leaf area of stressed plants, presumably due to attenuated root‐to‐shoot ABA transport. In flacca scions, a WT rootstock decreased stomatal conductance but increased leaf area of stressed plants, likely due to enhanced root‐to‐shoot ABA transport. Thus, long‐distance ABA transport can affect responses in distal tissues by changing local ABA concentrations.     

Effects of mutual grafting on the cadmium accumulation characteristics of two ecotypes of Solanum photeinocarpum

Abstract

The effects of mutual grafting on the cadmium (Cd) accumulation characteristics of two ecotypes (farmland and mining) of the potential Cd-hyperaccumulator Solanum photeinocarpum were studied through a pot experiment for one month. Four treatments were used in the experiment: ungrafted farmland ecotype (F-CK), ungrafted mining ecotype (M-CK), the farmland ecotype as the scion grafted onto rootstocks of the mining ecotype (F-Scion), and the mining ecotype as the scion grafted onto rootstocks of the farmland ecotype (M-Scion). Mutual grafting increased the rootstock biomass of both S. photeinocarpum ecotypes. However, mutual grafting decreased the scion biomass of F-Scion compared with F-CK and M-CK, and the scion biomass of M-Scion was higher than that of M-CK and lower than that of F-CK. The Cd content in the rootstock of M-Scion increased compared with F-CK, and the Cd content in the rootstock of F-Scion increased compared with M-CK, but mutual grafting decreased the Cd content in scions of both S. photeinocarpum ecotypes. Mutual grafting increased Cd extraction by rootstocks of both S. photeinocarpum ecotypes, but decreased extraction by scions. Therefore, mutual grafting can increase Cd accumulation in S. photeinocarpum rootstocks but not increase Cd accumulation in S. photeinocarpum scions in a short period.     

Studies on graft unions. I. Plasmodesmata between cells of plants belonging to different unrelated taxa

Summary In order to answer the question whether plasmodesmata exist between the cells of stock and scion in a graft union of higher plants, a heteroplastic graft has been selected with species-specific cell markers.Vicia faba was used as scion andHelianthus annuus as stock. In the mixed callus of the graft union, individual cells of the two partners differ in the structure of the nuclei, plastids and microbodies. In the fused cell walls betweenVicia andHelianthus cells, plasmodesmata interconnect the protoplasts of the unrelated cells. Two types of plasmodesma occur: single strands and branched connections. The fine structure of the interspecific cell bridges, which have been secondarily formed in non-division walls, is similar to that of normal plasmodesmata in division walls. Some questions concerning compatibility/incompatibility in the heterograft are discussed.     

Shifts in xylem vessel diameter and embolisms in grafted apple trees of differing rootstock growth potential in response to drought

We investigated responses of plant growth rate, hydraulic resistance, and xylem cavitation in scion-rootstock-combinations of Malus domestica L. cv. Honeycrisp scions grafted onto a high-shoot vigor (HSV) rootstock, (semi-dwarfing Malling111), or onto a low-shoot vigor (LSV) rootstock, (dwarfing Budagovsky 9), in response to substrate moisture limitation. Adjustments in xylem vessel diameter and frequency were related to hydraulic resistance measurements for high- versus low- vigor apple trees. We observed a greater tolerance to water deficit in the high-shoot compared to the low-shoot vigor plants under water deficit as evidenced by increased growth in several plant organs, and greater scion anatomical response to limited water availability with ca. 25% increased vessel frequency and ca. 28% narrower current season xylem ring width. Whereas water limitation resulted in greater graft union hydraulic resistance of high-shoot vigor trees, the opposite was true when water was not limiting. The graft union of the low-shoot vigor rootstock exhibited higher hydraulic resistance under well-watered conditions. Scions of high-shoot vigor rootstocks had fewer embolisms at low plant water status compared to scions of low-shoot vigor rootstocks, presumably as a result of large differences in xylem vessel diameter. Our results demonstrated that anatomical differences were related to shifts in hydraulic conductivity and cavitation events, a direct result of grafting, under limited soil water.     

Apple phloem cells contain some mRNAs transported over long distances

Apple (Malus × domestica Borkh.), like many fruit trees, cannot be propagated clonally from seed and is instead propagated by the grafting onto rootstocks. Rootstocks affect the growth of scions, but it is not known why. The circulation of some mRNAs throughout the phloem has recently been shown. To clarify whether RNAs are transported long distance through the graft union of apple trees, we analyzed cDNAs derived from shoot phloem cells by laser capture microdissection. We detected several mRNAs that have already been reported as phloem-transported RNAs in other plants. One of them, MpSLR/IAA14, was probed to transport a long distance through the graft union in grafted apple plant. These results suggest that a phloem RNA transport system may be involved in the effects of rootstocks on scion growth and cropping.     

Application of Electrical Wave Transmission in Basic Research of Grafting

Electrical wave (EW) transmission from scion to stock across the grafting interface was related to the histological changes during the development of graft union. Variation wave (VW) could not be transmitted to stock from scion before isolation layer broken and callus interdigitation. As plasmodesmata formed secondarily at the interface between stock and scion where the isolation layer had disappeared, VW could be transmitted from scion to stock, but its velocity was not rapid until the vascular bridges form between two partners of graft union. Hence, the authors could deduce the degree of graft union formation by measuring whether VW could be transmitted from scion to stock or not and its velocity. EW trans mission method was a new tool for quickly detecting the formation of graft union.     

电波传递在嫁接基本理论研究中的应用

研究发现电波从接穗跃过嫁接面向砧木传递与嫁接的组织学变化相关。砧木和接穗愈伤组织细胞突破隔离层互相嵌合之前,接穗中产生的电波不能传到砧木。砧木和接穗细胞间产生次生胞间连丝后,电波即可沿接穗传至砧木,但此时传递速度慢。当砧木和接穗间产生维管束桥时,电波下传的速度加快。由此可见,通过检测电波跃过嫁接面与否及下传的速度,就可推断嫁接接合部组织学变化状况。电波传递法是一种快速鉴定嫁接植株发育过程的新方法。     

Auxin redistribution and shifts in PIN gene expression during Arabidopsis grafting

Auxin is important in the development of plant vascular tissues. Reconnection of vascular bundles between scion and stock is a primary aim of grafting, and polar auxin transport greatly affects the formation of a continuous vascular model. The role of auxin in the process of graft-union development was studied by grafting the seedlings of Arabidopsis thaliana (L.) Heynh. DR5:GUS marker plants, which exert the auxinspecific responses. Auxin induced the DR5:GUS expression in the vascular bundles around graft surface and stimulated the formation of multiple vascular bundle reconnections on the third day after grafting (DAG). DR5:GUS expression was delayed for one day in both scion and stock and dramatically declined by the auxin transport inhibitor N-1-naphthylphthalamic acid (NPA). Vascular bundle reconnection was observed only on the 4th DAG. These results suggest that auxin stimulates the reconnection of the vascular bundles, whereas NPA inhibits it. We studied the role of PIN proteins in graft development by grafting seedlings of PIN:GUS plants. PIN had different expression patterns in the graft process. Expression levels of PIN genes were analyzed by real-time PCR. All PIN genes had the higher expression level at the third DAG. We conclude that auxin stimulates the development of graft unions, and the patterns of expressions of PIN family genes can affect the development of graft-union by controlling the auxin flow.     

Evidence for graft transmission of structural phloem proteins or their precursors in heterografts of Cucurbitaceae

Interspecific and intergeneric grafts of Cucurbitaceae were used to study the mobility of structural P-proteins in the phloem. When Cucumis sativus L. scions were grafted onto Cucurbita rootstocks, at least nine additional proteins appeared on sodium dodecyl sulfate-polyacrylamide electrophoresis gels of scion exudate, 9–11 d after grafting. These proteins corresponded exactly to those of the respective Cucurbita sp. rootstock, including the filament-forming phloem protein PP1 and the phloem lectin PP2, as shown by the apparent molecular weights and peptide maps. According to probing at three sites, the additional proteins were evenly distributed within the scion. The appearance of additional proteins was correlated with the establishment of phloem bridges across the graft union. The developmental coincidence establishes that the structural proteins or their precursors are translocated in the phloem. This translocation was a universal phenomenon in Cucurbitaceae as shown by a comparative screening for additional proteins in eleven graft combinations, using Benincasa hispida (Thunb.) Cogn., Citrullus colocynthis (L.) Schrad., Cucumis melo L, C. sativus, Cucurbita ficifolia Bouché, Cucurbita maxima Duchesne ex Lam., and Trichosanthes cucumerina var. lobata Roxb. According to this screening, the direction of transmission of additional proteins depended upon the combination tested. While some graft partners failed to show exchange, some behaved as “donor” for additional proteins and still others could be both “donor” or “acceptor”. However, whether used as scion or stock, C. sativus was consistently identified as an acceptor. The occurrence of additional proteins in heterografts is discussed with regard to the transport mechanism of structural P-proteins in the phloem and its relationship to assimilate transport. Received: 18 February 1998 / Accepted: 12 May 1998     

Regenerative Xylem in Inflorescence Stems of <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

By inserting entomological needles into the lower parts of young inflorescence stems of three-month-old Arabidopsis thaliana (L.) Heynh var. Colombia plants, we studied the process of regenerative xylem production. Regenerative xylem was formed only in one- to two-day-old inflorescence stems but not in older ones. The regenerative vessels originated from re-differentiation of cortical parenchyma. To characterize the process of regenerative xylem formation, we conducted a histological study from the time of wounding to day 30 after wounding. In the first day after wounding the tissues showed no structural responses except for the wounding itself. After six days, regenerative vessel members were already differentiating in a basipetal pattern, forming a vascular bypass around the wound. Regenerative vessel member formation reached a maximal level on the twelfth day after wounding. Sixteen days after wounding the pith parenchyma started to become loose as if indicating tissue senescence. Altogether, vascular regeneration following wounding in inflorescence stems of Arabidopsis thaliana is similar to that in other dicotyledon plants. These findings provide the basis for the use of Arabidopsis thaliana as a model system to study the genetics, physiology and cell biology of wound healing and regenerative vascular tissue formation.