Identification and characterization of SHORTENED UPPERMOST INTERNODE 1, a gene negatively regulating uppermost internode elongation in rice

In rice, the elongated internodes are derived from the vegetative shoot apical meristem (SAM), and the transition of the SAM from the vegetative to the reproductive stage induces internode elongation. In this study, we characterize two shortened uppermost internode mutants (sui1-1 and sui1-2). During the seedling and tillering stages, sui1 plants are morphologically similar to wild-type plants. However, at the heading stage, the sui1-1 mutant exhibits a shortened uppermost internode and a partly sheathed panicle, and the sui1-2 mutant shows an extremely shortened uppermost internode and a fully sheathed panicle. Gibberellin treatment results in elongation of every internode, but the shortened uppermost internode phenotype remains unaltered. Microscopic analysis indicates that cell length of sui1-1 uppermost internode exhibits decreased. Map-based cloning revealed that SUI1 is located on Chromosome 1, and encodes a putative phosphatidyl serine synthase (PSS) family protein. Searches for matches in protein databases showed that OsSUI1 contains the InterPro domain IPR004277, which is conserved in both animal and plant kingdoms. Introduction of a wild-type SUI1 gene fully rescued the mutant phenotype of sui1-1 and sui1-2, confirming the identity of the cloned gene. Consistent with these results, the SUI1-RNAi transgenic plants displayed decreased elongation of the uppermost internode. Our results suggest that SUI1 plays an important role in regulating uppermost internode length by decreasing longitudinal cell length in rice.     

Characterization and fine mapping of a shortened uppermost internode mutant in rice

Internode elongation is an important agronomic trait in rice that is associated with lodging, yield, flooding adaptation, and hybrid seed production. We identified a novel rice mutant line showing a shortened uppermost internode among the rice Ac/Ds insertional mutant population and named it shortened uppermost internode 4 (sui4). Interestingly, T1 plants of this line segregated into three phenotypes: extremely shortened uppermost internode-type, normal wild-type, and intermediate-type. The phenotypes of F1 plants and F2 plants from the cross of sui4 with its original variety, Dongjin, indicated that the SUI4 gene shows incomplete dominance or semidominance. Because the Ds genotypes did not co-segregate with the sui4 phenotypes, we performed mapping of this gene with 273 F2 plants from a cross between sui4 and Milyang23. Primary mapping revealed that the SUI4 locus was located between the S07012 and S07015 markers on rice chromosome 7. Further fine mapping with 36 F3 lines derived from F2 plants that have recombination in this region narrowed down the location of SUI4 to the 1.1-Mbp interval of RM1253–S07015.     

The biophysical basis of elongation growth in internodes of deepwater rice

Partial submergence induces rapid internodal elongation in deepwater rice (Oryza sativa L., cv Habiganj Aman II). We measured in vivo extensibility, tissue tension, hydraulic conductance and osmotic potential in the region of cell elongation in the uppermost internode. The in vivo extensibility of the internode, measured by stretching of living tissue with a custom-made constant stress extensiometer, rose rapidly following submergence of the plant. Both the elastic (E_el) and plastic (E_pl) extensibility increased when growth of the internode was induced. The submerged internode displayed tissue tension (elastic outward bending of longitudinally split internode sections); in air-grown control internodes, no such bending occurred. The hydraulic conductance, estimated from the kinetics of tissue shrinkage in 0.5 molar mannitol and subsequent swelling in distilled water, was not changed by submergence. The osmotic potential, measured with a dew-point hygrometer using frozen-thawed tissue, was only 18% less negative in the submerged internode than in the air-grown control. This indicates that osmoregulation takes place in rapidly elongating rice internodes. We suggest that the rapid expansion of the newly formed internodal cells of submerged plants is controlled by the yielding properties (E_pl) of the cell walls. Experiments with excised stem sections indicate that gibberellin is involved in increasing the E_pl of the elongating cell walls.     

Involvement of cell wall-bound phenolic acids in decrease in cell wall susceptibility to expansins during the cessation of rapid growth in internodes of floating rice

The cell walls in the elongating zone of submerged floating rice internodes show high susceptibility to expansins. When internode sections corresponding to such an elongation zone were incubated for 24 h under osmotic stress conditions produced by treatment with 100 mM polyethylene glycol 4000 (PEG), the cell wall susceptibility to expansins remained at its initial level, while the susceptibility of internode sections incubated under unstressed conditions decreased considerably during the same period. The contents of polysaccharides and phenolic acids as ferulic, diferulic and p-coumaric acids in the cell walls of internode sections increased substantially under unstressed conditions, but the increases were almost completely prevented by osmotic stress. Ferulic acid applied to internode sections under osmotic stress reduced the susceptibility of the cell walls to expansins and increased the levels of ferulic and diferulic acids in the cell walls, with little effect on the accumulation of polysaccharides. In contrast, applied p-coumaric acid increased the level of p-coumaric acid in the cell walls without a change in the levels of ferulic and diferulic acids but did not reduce the susceptibility to expansins. These results suggest that the deposition of ferulic and diferulic acids is a primary determinant in regulating the reduction of the susceptibility of cell walls to expansins in floating rice internodes.     

The Cellular Pathway of Short-distance Transfer of Photosynthates and Potassium in the Elongating Stem ofPhaseolus vulgarisL. A Physiological Assessment

Plasmolytic disruption of plasmodesmata interconnecting metaphloemsieve element-companion cell complexes with small and largephloem parenchyma cells in the elongating region of internode2 ofPhaseolus vulgarisL. seedlings did not affect accumulationof phloem-imported¹⁴C-photosynthates and⁸⁶rubidium. The membrane-impermeantdye, 5(6) carboxyfluorescein, loaded into leaf phloem as themembrane-permeant diacetate ester, was found not to move radiallyout of the importing sieve elements in the internode elongationregion. In contrast, the apoplasmic tracer, Calcuofluor White,rapidly moved laterally throughout all tissues of the elongationzone. Hexoses, sucrose and potassium were identified as themain osmotica in internode apoplasmic sap. Label asymmetry in[¹⁴C](fructosyl)sucrose was retained on accumulation by excisedstem segments. Uptake of [¹⁴C]sucrose and⁸⁶rubidium by stemsegments exhibited saturation kinetics. Sucrose uptake was inhibitedby the slowly penetrating sulphydryl reagent, para-chloromercuribenzenesulphonicacid.In vitrorates of sucrose uptake, at apoplasmic concentrations,corresponded to its predictedin vivorate of delivery to thestem ground tissues from mature sieve elements when respiratorylosses were assumed to be confined to the stem phloem. For potassium,the total delivery rate could be accounted for by itsin vitrorateof uptake. Overall, it was concluded that radial transport,in the elongation zone of internode 2 ofPhaseolus vulgarisL.seedlings, follows an apoplasmic route from mature sieve elementsto stem ground tissues.Copyright 1998 Annals of Botany Company PhaseoluLes vulgaris, apoplasm, elongating stem, French bean, photosynthates, potassium, radial transfer, symplasm.     

Silicification of developing internodes in the perennial scouring rush (Equisetum hyemale var. affine)

An electron microprobe (EMP) analysis of silica (SiO₂) deposition in the epidermis of developing internodes of the perennial scouring rush (Equisetum hyemale var. affine) indicates that SiO₂ is first detected in the stomatal apparatus beginning with internode 3, then the epidermal papillae (internode 8), and finally in radial cell walls of the long epidermal cells (internode 10). This process is initiated in the intercalary growth regions at the bases of the elongating internodes. The deposition of SiO₂ in long epidermal cell walls occurs after internodal extension has ceased and should therefore be considered as one of the final stages in internodal differentiation that involves strengthening the cellulosic framework of the cell wall. EMP measurements indicate that SiO₂ in stomata is equivalent to 30% of a pure SiO₂ standard and that SiO₂ in the radial walls of long epidermal cells averages twice that measured on the tangential walls of these same cells. This study supports the view that silicification plays a major role in strengthening the developing perennial scouring rush internodal system and that regulation of this process in this and other species of Equisetum, whose SiO₂ deposition patterns are markedly different, deserves further study.     

Rice DWARF AND LOW-TILLERING and the homeodomain protein OSH15 interact to regulate internode elongation via orchestrating brassinosteroid signaling and metabolism

Brassinosteroid (BR) phytohormones play crucial roles in regulating internode elongation in rice (Oryza sativa). However, the underlying mechanism remains largely unclear. The dwarf and low-tillering (dlt) mutant is a mild BR-signaling-defective mutant. Here, we identify two dlt enhancers that show more severe shortening of the lower internodes compared to the uppermost internode (IN1). Both mutants carry alleles of ORYZA SATIVA HOMEOBOX 15 (OSH15), the founding gene for dwarf6-type mutants, which have shortened lower internodes but not IN1. Consistent with the mutant phenotype, OSH15 expression is much stronger in lower internodes, particularly in IN2, than IN1. The osh15 single mutants have impaired BR sensitivity accompanied by enhanced BR synthesis in seedlings. DLT physically interacts with OSH15 to co-regulate many genes in seedlings and internodes. OSH15 targets and promotes the expression of the BR receptor gene BR INSENSITIVE1 (OsBRI1), and DLT facilitates this regulation in a dosage-dependent manner. In osh15, dlt, and osh15 dlt, BR levels are higher in seedlings and panicles, but unexpectedly lower in internodes compared with the wild-type. Taken together, our results suggest that DLT interacts with OSH15, which functions in the lower internodes, to modulate rice internode elongation via orchestrating BR signaling and metabolism.

DWARF AND LOW-TILLERING interacts with the homeodomain protein OSH15, which directly targets the brassinosteroid receptor gene OsBRI1 and is expressed in lower internodes, to regulate the internode elongation via modulating brassinosteroid signaling and metabolism.

IN A NUTSHELL Background: Rice culms consist of five to seven internodes and the length of these internodes determines plant height and resistance to wind, which is crucial for field performance. Brassinosteroid (BR) plant hormones are involved in regulating plant height because defects in BR synthesis or signaling (such as mutants in the BR receptor gene BRASSINOSTEROID INSENSITIVE 1 (OsBRI1)) usually result in dwarfism with specific shortening of the lower internodes or the second internode (IN2) compared to that of the uppermost/first internode (IN1). This pattern is known as d6 or dm-type dwarfism. Question: We wanted to know how BRs are involved in organizing the different internodes and therefore, we carried out a large-scale screen for mutants with altered internode organization pattern using the mild BR signaling-defective mutant dwarf and low-tillering (dlt). Findings: We identified two mutants showing specific shortening of the lower internodes, that is d6-type dwarfism. Both mutants have the same causal gene, namely, OSH15, which encodes a homeodomain-containing protein. OSH15 can directly interact with DLT, forming a protein complex to regulate BR contents and BR signaling. For example, DLT–OSH15 directly binds the promoter of OsBRI1 to promote gene expression. OSH15 expression is strong in the lower internodes, particularly in IN2, and DLT shows an opposite expression pattern. Therefore, the protein complex has different levels in different internodes, exerting different effects on BR levels and signaling to modulate internode organization. Next steps: Scientists aim to use BR-related genes to engineer plant height and grain size and thus produce new crops having improved grain yield and lodging resistance. The discovery of the DLT–OSH15–OsBRI1 module could help achieve this goal. Next, we will try to uncover how BRs coordinate internode elongation with panicle development.     

ELONGATED UPPERMOST INTERNODE encodes a cytochrome P450 monooxygenase that epoxidizes gibberellins in a novel deactivation reaction in rice

The recessive tall rice (Oryza sativa) mutant elongated uppermost internode (eui) is morphologically normal until its final internode elongates drastically at the heading stage. The stage-specific developmental effect of the eui mutation has been used in the breeding of hybrid rice to improve the performance of heading in male sterile cultivars. We found that the eui mutant accumulated exceptionally large amounts of biologically active gibberellins (GAs) in the uppermost internode. Map-based cloning revealed that the Eui gene encodes a previously uncharacterized cytochrome P450 monooxygenase, CYP714D1. Using heterologous expression in yeast, we found that EUI catalyzed 16α,17-epoxidation of non-13-hydroxylated GAs. Consistent with the tall and dwarfed phenotypes of the eui mutant and Eui-overexpressing transgenic plants, respectively, 16α,17-epoxidation reduced the biological activity of GA₄ in rice, demonstrating that EUI functions as a GA-deactivating enzyme. Expression of Eui appeared tightly regulated during plant development, in agreement with the stage-specific eui phenotypes. These results indicate the existence of an unrecognized pathway for GA deactivation by EUI during the growth of wild-type internodes. The identification of Eui as a GA catabolism gene provides additional evidence that the GA metabolism pathway is a useful target for increasing the agronomic value of crops.     

Electrotonic Coupling between Adjacent Internodal Cells of Chara braunii: Transmission of Action Potentials beyond the Node

Many nodal cells are interposed between two internodal cellsof Chara braunii. When an action potential conducted in an internodereached the node, no electrical activation in the nodal cellscould be found, although an area of the membrane bordering thenodal cells in this internode was partially activated (end-membraneaction potential). When the action potential approached thenode along the stimulated internode, an electrotonic potentialchange (depolarization) was produced in the other internode.This depolarization was greatly depressed by the end-membraneaction potential of the stimulated internode, so that hardlyany transmission took place. The ratio of the potential changein the surface membrane of the adjoining ("postsynaptic") internode(cell b) to that of the stimulated one (cell a), the couplingratio, e_b/e_a, can be estimated from a simple equivalent circuitof the nodal region composed of two surface-membrane resistances(R_a, R_b) and intercellular resistance (R_n). If R_n remains thesame, a higher ratio should be produced with a larger R_b, butthe ratio does not depend on any change in R_a, which could beproved experimentally. Transmission of the action potentialbeyond the node was frequent when the coupling ratio was increasedand when the threshold that elicits the action potential waslowered by immersing the node in a K or Na salt solution. ¹ Present address: Department of Physiology, Tohoku UniversitySchool of Dentistry, Sendai 980, Japan. (Received December 1, 1980; Accepted January 23, 1981)     

Sal-like 4 (SALL4) suppresses CDH1 expression and maintains cell dispersion in basal-like breast cancer

In cell cultures, the dispersed phenotype is indicative of the migratory ability. Here we characterized Sal-like 4 (SALL4) as a dispersion factor in basal-like breast cancer. Our shRNA-mediated SALL4 knockdown system and SALL4 overexpression system revealed that SALL4 suppresses the expression of adhesion gene CDH1, and positively regulates the CDH1 suppressor ZEB1. Cell behavior analyses showed that SALL4 suppresses intercellular adhesion and maintains cell motility after cell–cell interaction and cell division, which results in the dispersed phenotype. Our findings indicate that SALL4 functions to suppress CDH1 expression and to maintain cell dispersion in basal-like breast cancer.     

The Cellular Pathway of Short-distance Transfer of Photosynthates and Potassium in the Elongating Stem of Phaseolus vulgaris L. A Structural Assessment

The potential cellular pathway of radial transfer of photosynthateand potassium delivered in the phloem to the elongation zone(apical 0.5–2.5 cm) of internode 2 ofPhaseolus vulgarisL. seedlings was elucidated. This was achieved using ultrastructuralobservations of the cell types that constitute the radial pathwayand estimates of potential sucrose and potassium fluxes throughthe cross-sectional area of interconnecting plasmodesmata andacross the plasma membrane surface areas of selected cell types.The investigation relied on predicting the relative roles ofthe mature and developing sieve elements as conduits for theaxial delivery of solutes to the elongation zone. In turn, thesepredictions led to formulation of two transport models whichwere subsequently evaluated. It was found that unloading ofsucrose and potassium from the protophloem sieve elements cannotbe through the symplast due to the absence of plasmodesmata.On the other hand, mature metaphloem sieve element-companioncell complexes have the potential capacity to unload eitherthrough the stem symplast or apoplast. The potential symplasticroute is proposed to be via the companion cells to the adjacentlarge phloem parenchyma cells. Continued radial transfer couldoccur either by exchange to the stem apoplast from the largephloem parenchyma cells or continue in the symplast to the groundtissues. It was further predicted that sucrose utilized forthe development of the procambial/small phloem parenchyma cellscould be delivered axially by them and not by the mature sieveelements. Phaseolus vulgaris ; apoplast; elongating stem; photosynthates; potassium; transport; symplast     

Origin of growth-induced water potential : solute concentration is low in apoplast of enlarging tissues

We developed a new method to measure the solute concentration in the apoplast of stem tissue involving pressurizing the roots of intact seedlings (Glycine max [L.] Merr. or Pisum sativum L.), collecting a small amount of exudate from the surface of the stem under saturating humidities, and determining the osmotic potential of the solution with a micro-osmometer capable of measuring small volumes (0.5 microliter). In the elongating region, the apoplast concentrations were very low (equivalent to osmotic potentials of −0.03 to −0.04 megapascal) and negligible compared to the water potential of the apoplast (−0.15 to −0.30 megapascal) measured directly by isopiestic psychrometry in intact plants. Most of the apoplast water potential consisted of a negative pressure that could be measured with a pressure chamber (−0.15 to −0.28 megapascal). Tests showed that earlier methods involving infiltration of intercellular spaces or pressurizing cut segments caused solute to be released to the apoplast and resulted in spuriously high concentrations. These results indicate that, although a small amount of solute is present in the apoplast, the major component is a tension that is part of a growth-induced gradient in water potential in the enlarging tissue. The gradient originates from the extension of the cell walls, which prevents turgor from reaching its maximum and creates a growth-induced water potential that causes water to move from the xylem at a rate that satisfies the rate of enlargement. The magnitude of the gradient implies that growing tissue contains a large resistance to water movement.     

In vivo 1-aminocyclopropane-1-carboxylate synthase activity in internodes of deepwater rice : enhancement by submergence and low oxygen levels

Inasmuch as the activity of 1-aminocyclopropane-1-carboxylate (ACC) synthase cannot be measured in homogenates of deepwater rice internodes (Oryza sativa L.), we have employed an in vivo assay to determine the activity of this enzyme. This assay is based on the accumulation of ACC in tissue kept under N₂. Submergence of whole plants or stem sections containing the uppermost, developing internode enhances the in vivo activity of ACC synthase in the stem. This stimulation of in vivo ACC-synthase activity is especially pronounced in the region of the internode containing the intercalary meristem and the elongation zone above it. Enhancement of in vivo ACC-synthase activity is evident after 2 hours of submergence and shows a peak after 4 hours. Reduced levels of atmospheric O₂, which promote ethylene synthesis and growth in internodes of deepwater rice, also enhance the in vivo activity of ACC synthase. Our results are consistent with the hypothesis that induction of ACC-synthase activity at low partial O₂ pressures is among the first biochemical events leading to internodal growth in deepwater rice.     

鹅掌楸属种间杂种优势与内源植物激素的关系

研究了鹅掌楸属( Liriodendron )种间F1杂种(杂种马褂木 L.chinense × L.tulipifera )及其亲本种(中国马褂木 L.chinense (Hemsl.) Sarg.和北美鹅掌楸 L.tulipifera L.)在生长性状和内源GA1/3、IAA和iPA含量上的差异性.结果表明:(1)杂种马褂木高生长性状杂种优势主要是由节间的相对伸长造成的,鹅掌楸属节间伸长区位于顶芽下第1～3节间,其中第1节间伸长量最大、是产生杂种优势的主要节间; (2)中国马褂木、北美鹅掌楸和杂种马褂木内源GA1/3、IAA和iPA含量差异很大,顶芽下第1节间GA1/3和iPA含量杂种家系分别为两个亲本种中含量相对较高的中国马褂木的133.58%～284.17%和396.64%～1 264.28%.杂种马褂木顶芽下第1节间中GA1/3和iPA含量的大量增加可能与高生长性状杂种优势有关; (3)杂种家系3年生时其苗高生长量排序与顶芽下第1节间中GA1/3和iPA含量排序并不一致,不能以第1节间GA1/3和iPA含量的高低作为预测杂种家系间杂种优势大小的依据.     

STEM ELONGATION OF XANTHIUM PLANTS PRESENTED IN TERMS OF RELATIVE ELEMENTAL RATES

Vegetative Xanthium plants grown under noninductive conditions were marked along the stem with India ink and photographed during three successive days. The relative elemental rates of stem elongation [d(dX/dt)/dX] were estimated for 18 plants between 15 and 18 plastochrons. On the average, only the 8.0 cm terminal part of the stem was elongating in this group of plants. Young internodes were elongating at constant relative elemental rates ([d(dX/dt)/dX] was about 0.2 days^–1); nodal portions of the stem beteween two young internodes were not elongating. Internodes longer than 2 cm displayed an acropetal pattern of elongation in which the basal part of an internode stopped elongating and matured first and the apical portion last. The pattern of elongation of the stem could be best approximated to a set of cascading waterfalls with declining plateaus in the direction of the water flow. The acropetal pattern of individual internode elongation observed in Xanthium was similar to those reported for Helianthus and Phaseolus internode growth.     

Regulation of Cell Wall Synthesis by the Clathrin Light Chain Is Essential for Viability in Schizosaccharomyces pombe

The regulation of cell wall synthesis by the clathrin light chain has been addressed. Schizosaccharomyces pombe clc1Δ mutant was inviable in the absence of osmotic stabilization; when grown in sorbitol-supplemented medium clc1Δ cells grew slowly, formed aggregates, and had strong defects in morphology. Additionally, clc1Δ cells exhibited an altered cell wall composition. A mutant that allowed modulating the amount of Clc1p was created to analyze in more detail the dependence of cell wall synthesis on clathrin. A 40% reduction in the amount of Clc1p did not affect acid phosphatase secretion and bulk lipid internalization. Under these conditions, β(1,3)glucan synthase activity and cell wall synthesis were reduced. Also, the delivery of glucan synthases to the cell surface, and the secretion of the Eng1p glucanase were defective. These results suggest that the defects in the cell wall observed in the conditional mutant were due to a defective secretion of enzymes involved in the synthesis/remodelling of this structure, rather than to their endocytosis. Our results show that a reduction in the amount of clathrin that has minor effects on general vesicle trafficking has a strong impact on cell wall synthesis, and suggest that this is the reason for the lethality of clc1Δ cells in the absence of osmotic stabilization.     

Polarity of IAA Effect on Sieve-Tube and Xylem Regeneration in Coleus and Tomato Stems

A technique is described for the processing of regenerated xylem and sieve tubes from the same wound area for microscopic and quantitative comparison.

Regeneration was examined in internodes of 2 developmental stages in Coleus: internode 2, elongating, characteristic of primary growth; and internode 5, non-elongating, characteristic of secondary growth.

Transport of indoleacetic acid (IAA) in excised number 5 internodes of Coleus is strictly polar, in a basipetal direction, judging by a regeneration bioassay involving both sieve tube strands and xylem cells. Similar results were obtained with tomato.

If isolated number 5 Coleus internodes are not treated with hormone, they regenerate no xylem cells and a small number of sieve tube strands. With increasing concentrations of IAA added apically, the number of regenerated sieve tube strands (and, with higher concentrations, of xylem cells) increases progressively up to 1% IAA, the highest concentration applied.

Internode 2 of Coleus regenerates fewer xylem cells or sieve tube strands than internode 5, whether on the otherwise intact plant or with a given concentration of IAA added apically. The amount of regenerated xylem increases with added apical IAA, except that the highest concentration gives no further increase. The number of xylem cells regenerated in intact plants occurs at the same interpolated IAA concentration as in number 5 internodes. No concentration of IAA tried provided replacement of intact number of sieve tube strands in internode 2.

IAA can exert a regenerative stimulus on both xylem and sieve tubes in the area immediately adjacent to the site of its application.