Molecular and phylogenetic characterization of the sieve element occlusion gene family in <Emphasis Type="Italic">Fabaceae</Emphasis> and non-<Emphasis Type="Italic">Fabaceae</Emphasis>plants

Background  

The phloem of dicotyledonous plants contains specialized P-proteins (phloem proteins) that accumulate during sieve element differentiation and remain parietally associated with the cisternae of the endoplasmic reticulum in mature sieve elements. Wounding causes P-protein filaments to accumulate at the sieve plates and block the translocation of photosynthate. Specialized, spindle-shaped P-proteins known as forisomes that undergo reversible calcium-dependent conformational changes have evolved exclusively in the Fabaceae. Recently, the molecular characterization of three genes encoding forisome components in the model legume Medicago truncatula (MtSEO1, MtSEO2 and MtSEO3; SEO = sieve element occlusion) was reported, but little is known about the molecular characteristics of P-proteins in non-Fabaceae.     

Sieve element occlusion provides resistance against Aphis gossypii in TGR-1551 melons

Feeding behavior and plant response to feeding were studied for the aphid Aphis gossypii Glover on susceptible and resistant melons(cv.Iroquois and TGR-1551,respectively).Average phloem phase bout duration on TGR-1551 was<7% of the duration on Iroquois.Sixty-seven percent of aphids on TGR-1551 never produced a phloem phase that attained ingestion(EPG waveform E2)in contrast to only 7% of aphids on Iroquois.Average bout duration of waveform E2(scored as zero if phloem phase did not attain E2)on TGR-1551 was<3% of the duration on Iroquois.Conversely,average bout duration of EPG waveform El(sieve element salivation)was 2.8 times greater on TGR-1551 than on Iroquois.In a second experiment,liquid nitrogen was used to rapidly cryofix leaves and aphids within a few minutes after the aphids penetrated a sieve element.Phloem near the penetration site was then examined by confocal laser scanning microscopy.Ninety-six percent of penetrated sieve elements were occluded by protein in TGR-1551 in contrast to only 28% in Iroquois.Usually in TGR-1551,occlusion was also observed in nearby nonpenetrated sieve elements.Next,a calcium channel blocker,trivalent lanthanum,was used to prevent phloem occlusion in TGR-1551,and A.gossypii feeding behavior and the plants phloem response were compared between lanthanum-treated and control TGR-1551.Lanthanum treatment eliminated the sieve element protein occlusion response and the aphids readily ingested phloem sap from treated plants.This study provides strong evidence that phloem occlusion is a mechanism for resistance against A.gossypii in TGR-1551.     

The sieve element occlusion gene family in dicotyledonous plants

Sieve element occlusion (SEO) genes encoding forisome subunits have been identified in Medicago truncatula and other legumes. Forisomes are structural phloem proteins uniquely found in Fabaceae sieve elements. They undergo a reversible conformational change after wounding, from a condensed to a dispersed state, thereby blocking sieve tube translocation and preventing the loss of photoassimilates. Recently, we identified SEO genes in several non-Fabaceae plants (lacking forisomes) and concluded that they most probably encode conventional non-forisome P-proteins. Molecular and phylogenetic analysis of the SEO gene family has identified domains that are characteristic for SEO proteins. Here, we extended our phylogenetic analysis by including additional SEO genes from several diverse species based on recently published genomic data. Our results strengthen the original assumption that SEO genes seem to be widespread in dicotyledonous angiosperms, and further underline the divergent evolution of SEO genes within the Fabaceae.Key words: forisome, P-protein, sieve element occlusion, phloem, wound sealing, gene family, Fabacea     

Immunolocalization of plasma-membrane H+-ATPase and tonoplast-type pyrophosphatase in the plasma membrane of the sieve element-companion cell complex in the stem of Ricinus communis L

Plasma-membrane-located primary pumps were investigated in the sieve element (SE)-companion cell complex in the transport phloem of 2-week-old stems of Ricinus communis L. and, for comparison, in stems of Cucurbita pepo L. and in the secondary phloem of Agrobacterium tumefaciens-induced crown galls as a typical sink tissue. The plasma-membrane (PM) H⁺-ATPase and the tonoplast-type pyrophosphatase (PPase) were immunolocalized by epifluorescence and confocal laser scanning microscopy (CLSM) upon single or double labeling with specific monoclonal and polyclonal antibodies. Quantitative fluorescence evaluation by CLSM revealed both pumps in one membrane, the sieve-element PM. Different PM H⁺-ATPase antibody clones, raised against the PM H⁺-ATPase of Zea mays coleoptiles, induced in mouse and produced in mouse hybridoma cells, discriminated between different phloem cell types. Clones 30D5C4 and 44B8A1 labeled sieve elements and clone 46E5B11D5 labeled companion cells, indicating the existence of different phloem PM H⁺-ATPase isoforms. The results are discussed in terms of energization of SE transporters for retrieval of leaking sucrose, K⁺ and amino acids, as one of the unknown roles of ATP found in SEs. The function of the PPase could be related to phloem sucrose metabolism in support of ATP-requiring processes. Received: 3 July 2000 / Accepted: 12 October 2000     

Spatial and temporal regulation of the forisome gene <Emphasis Type="Italic">for1</Emphasis> in the phloem during plant development

Forisomes are protein aggregates found uniquely in the sieve elements of Fabaceaen plants. Upon wounding they undergo a reversible, calcium-dependent conformational switch which enables them to act as cellular stopcocks. Forisomes begin to form in young sieve elements at an early stage of metaphloem differentiation. Genes encoding forisome components could therefore be useful as markers of early sieve element development. Here we present a comprehensive analysis of the developmental expression profile of for1, which encodes such a forisome component. The for1 gene is highly conserved among Fabaceaen species and appears to be unique to this phylogenetic lineage since no orthologous genes have been found in other plants, including Arabidopsis and rice. Even so, transgenic tobacco plants expressing reporter genes under the control of the for1 promoter display reporter activity exclusively in immature sieve elements. This suggests that the regulation of sieve element development is highly conserved even in plants where mature forisomes have not been detected. The promoter system could therefore provide a powerful tool for the detailed analysis of differentiation in metaphloem sieve elements in an unexpectedly broad range of plant species. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Ultrastructure of compatible and incompatible interactions in phloem sieve elements during the stylet penetration by cotton aphids in melon

Resistance of the melon line TGR‐1551 to the aphid Aphis gossypii is based on preventing aphids from ingesting phloem sap. In electrical penetration graphs (EPGs), this resistance has been characterized with A. gossypii showing unusually long phloem salivation periods (waveform E1) mostly followed by pathway activities (waveform C) or if followed by phloem ingestion (waveform E2), ingestion was not sustained for more than 10 min. Stylectomy with aphids on susceptible and resistant plants was performed during EPG recording while the stylet tips were phloem inserted. This was followed by dissection of the penetrated leaf section, plant tissue fixation, resin embedding, and ultrathin sectioning for transmission electron microscopic observation in order to study the resistance mechanism in the TGR. The most obvious aspect appeared to be the coagulation of phloem proteins inside the stylet canals and the punctured sieve elements. Stylets of 5 aphids per genotype were amputated during sieve element (SE) salivation (E1) and SE ingestion (E2). Cross‐sections of stylet bundles in susceptible melon plants showed that the contents of the stylet canals were totally clear and also, no coagulated phloem proteins occurred in their punctured sieve elements. In contrast, electron‐dense coagulations were found in both locations in the resistant plants. Due to calcium binding, aphid saliva has been hypothesized to play an essential role in preventing/suppressing such coagulations that cause occlusion of sieves plate and in the food canal of the aphid's stylets. Doubts about this role of E1 salivation are discussed on the basis of our results.     

Ultrastructural features of well-preserved and injured sieve elements: Minute clamps keep the phloem transport conduits free for mass flow

Summary After chemical fixation following two different preparation procedures, the ultrastructure of mature sieve elements (SEs) was systematically compared in the transport phloem ofVicia faba leaves andLycopersicon esculentum internodes. The SEs in samples obtained by gentle preparation were well preserved, while those in conventionally prepared samples were generally injured. (1) In well-preserved SEs, parietal P-proteins were associated with cisternae of the SE endoplasmic reticulum (ER). Additionally, theV. faba SEs had crystalline P-proteins, and a homogeneous network of filamentous P-proteins occurred in the lumen of theL. esculentum SEs. In injured SEs, all P-proteins were dispersed. (2) In well-preserved SEs, stacked ER cisternae associated with P-proteins lay also on the sieve-plate walls, but passages were kept free in front of the sieve pores. Injured SEs lacked these orderly arranged deposits. Instead, irregular filamentous and membranous materials occluded the sieve pores. (3) In well-preserved SEs, the sieve-pore lumen was free of obstructions, apart from small, lateral coatings of P-proteins. Sieve pores in injured SEs were always occluded. (4) The SE organelles and, in tomato SEs, also the parietal ER located at the longitudinal walls were firmly attached in the SE periphery and stayed in place after injury. The stable parietal attachment is likely exerted by minute, clamplike structures which link the outer membranes of the SE components with one another or to the SE plasma membrane. Single, straight clamps with a length of about 7 nm anchored the SE components directly to the SE plasma membrane. The connections between adjacent SE organelles and/or parietal ER cisternae were mostly twice as long (about 15 nm) and often were branched. Presumably, the long, branched clamps were constituted by the interaction of opposite short clamps. The ultrastructural results are discussed with respect to SE functioning.     

The SIE,SRE, CRE,and FAP‐1 four intracellular signal pathways between stimulus and the expression of c‐fos promoter

c‐fos gene has a close relationship with the osteoblasts. Mechanical signal effect on osteoblasts would change the expression level of c‐fos. Authors introduce the signal pathways of four cis‐response elements on the promoter of c‐fos, that is, CRE (cAMP responsive element), FAP‐1 (Fbs‐AP‐1 site), SRE (serum response element), and SIE (sis‐inducible element), as the regulatory mechanism for c‐fos gene expression following various stimuli. J. Cell. Biochem. 106: 764–768, 2009. © 2009 Wiley‐Liss, Inc.     

Rapid cooling triggers forisome dispersion just before phloem transport stops

Phloem transport stops transiently within dicot stems that are cooled rapidly, but the cause remains unknown. Now it is known that (1) rapid cooling depolarizes cell membranes giving a transient increase in cytoplasmic Ca²⁺, and (2) a rise of free calcium triggers dispersion of forisomes, which then occlude sieve elements (SEs) of fabacean plants. Therefore, we compared the effects of rapid chilling on SE electrophysiology, phloem transport and forisomes in Vicia faba. Forisomes dispersed after rapid cooling with a delay that was longer for slower cooling rates. Phloem transport stopped about 20 s after forisome dispersion, and then transport resumed and forisomes re‐condensed within similar time frames. Transport interruption and forisome dispersion showed parallel behaviour – a cooling rate‐dependent response, transience and desensitization. Chilling induced both a fast and a slow depolarization of SE membranes, the electrical signature suggesting strongly that the cause of forisome dispersion was the transient promotion of SE free calcium. This apparent block of SEs by dispersed forisomes may be assisted by other Ca²⁺‐dependent sealing proteins that are present in all dicots.     

RPW8 promoter is involved in pathogen‐And stress‐inducible expression from Vitis pseudoreticulata

Based on previous cloning of VpRPW8‐e, we obtained a 1,126 bp VpRPW8‐e promoter sequence in this study. A large number of TATA‐boxes, CAAT‐boxes, and other cis‐acting elements were predicted including light‐responsive elements, hormone‐responsive elements, stress‐responsive elements, and growth‐ and development‐associated elements within the promoter sequence. To further investigate the function of this promoter, we examined its activity in response to biotic and abiotic stress. The VpRPW8‐e promoter was strongly activated by Plasmopara viticola infection, and activation also occurred when the orientation of the promoter was reversed, although to a lesser extent. Deletion analysis showed that the ?1,126 to ?475 bp region of VpRPW8‐e promoter had high activity. A promoter fragment 5′ deleted to ?475 bp (P_?475) was activated in response to heat and cold stress, and even more strongly in response to Phytophthora capsici and salicylic acid (SA). Furthermore, Transgenic Nicotiana benthamiana were generated, VpRPW8‐e driven by P_?475 enhanced resistance to Ph. capsici in N. benthamiana. Based on these results, the ?475 bp region was deduced to be an indispensable part of the VpRPW8‐e promoter. VpRPW8‐e promoter is involved in pathogen‐ and stress‐inducible expression.     

Sieve elements rapidly develop ‘nacreous walls’ following injury − a common wounding response?

Thick glistening cell walls occur in sieve tubes of all major land plant taxa. Historically, these ‘nacreous walls’ have been considered a diagnostic feature of sieve elements; they represent a conundrum, though, in the context of the widely accepted pressure–flow theory as they severely constrict sieve tubes. We employed the cucurbit Gerrardanthus macrorhizus as a model to study nacreous walls in sieve elements by standard and in situ confocal microscopy and electron microscopy, focusing on changes in functional sieve tubes that occur when prepared for microscopic observation. Over 90% of sieve elements in tissue sections processed for microscopy by standard methods exhibit nacreous walls. Sieve elements in whole, live plants that were actively transporting as shown by phloem‐mobile tracers, lacked nacreous walls and exhibited open lumina of circular cross‐sections instead, an appropriate structure for Münch‐type mass flow of the cell contents. Puncturing of transporting sieve elements with micropipettes triggered the rapid (<1 min) development of nacreous walls that occluded the cell lumen almost completely. We conclude that nacreous walls are preparation artefacts rather than structural features of transporting sieve elements. Nacreous walls in land plants resemble the reversibly swellable walls found in various algae, suggesting that they may function in turgor buffering, the amelioration of osmotic stress, wounding‐induced sieve tube occlusion, and possibly local defence responses of the phloem.     

Phloem transdifferentiation from immature xylem cells during bark regeneration after girdling in Eucommia ulmoides Oliv

Eucommia ulmoides Oliv. (Eucommiaceae), a traditional Chinesemedicinal plant, was used to study phloem cell differentiationduring bark regeneration after girdling on a large scale. Hereit is shown that new sieve elements (SEs) appeared in the regeneratedtissues before the formation of wound cambium during bark regenerationafter girdling, and they could originate from the transdifferentiationof immature/differentiating axial xylem cells left on the trunk.Assays of water-cultured twigs revealed that girdling blockedsucrose transport until the formation of new SEs, and the regenerationof the functional SEs was not dependent on the substance providedby the axis system outside the girdled areas, while exogenousindole acetic acid (IAA) applied on the wound surface acceleratedSE differentiation. The experiments suggest that the immaturexylem cells can transdifferentiate into phloem cells under certainconditions, which means xylem and phloem cells might share someidentical features at the beginning of their differentiationpathway. This study also showed that the bark regeneration systemcould provide a novel method for studying xylem and phloem celldifferentiation. Key words: Bark regeneration, Eucommia ulmoides Oliv., immature xylem cells, sieve elements, transdifferentiation Received 19 November 2007; Revised 23 January 2008 Accepted 24 January 2008