The arabidopsis ATHB-8 HD-zip protein acts as a differentiation-promoting transcription factor of the vascular meristems

ATHB-8, -9, -14, -15, and IFL1/REV are members of a small homeodomain-leucine zipper family whose genes are characterized by expression in the vascular tissue. ATHB-8, a gene positively regulated by auxin (Baima et al., 1995), is considered an early marker of the procambial cells and of the cambium during vascular regeneration after wounding. Here, we demonstrate that although the formation of the vascular system is not affected in athb8 mutants, ectopic expression of ATHB-8 in Arabidopsis plants increased the production of xylem tissue. In particular, a careful anatomical analysis of the transgenic plants indicated that the overexpression of ATHB-8 promotes vascular cell differentiation. First, the procambial cells differentiated precociously into primary xylem. In addition, interfascicular cells also differentiated precociously into fibers. Finally, the transition to secondary growth, mainly producing xylem, was anticipated in transgenic inflorescence stems compared with controls. The stimulation of primary and secondary vascular cell differentiation resulted in complex modifications of the growth and development of the ATHB-8 transgenic plants. Taken together, these results are consistent with the hypothesis that ATHB-8 is a positive regulator of proliferation and differentiation, and participates in a positive feedback loop in which auxin signaling induces the expression of ATHB-8, which in turn positively modulates the activity of procambial and cambial cells to differentiate.     

ONTOGENY OF MAJOR VEINS IN THE LAMINA OF POPULUS DELTOIDES BARTR

The ontogeny of the major venation in the lamina of Populus deltoides Bartr. leaves was investigated in relation to the development of original procambial bundles, subsidiary bundles, and their derivatives. Serial sections and clearings were used to show that the midrib region is a composite structure consisting of several independent vascular bundles, each of which eventually diverges into the lamina to become a secondary vein. The sequence of events in the ontogeny of major secondary veins is: (1) an original procambial strand develops acropetally and becomes the precursor of the first vascular bundle of the midrib region of the lamina, (2) ground tissue at the forefront of acropetally developing subsidiary procambial bundles differentiates in a wavelike continuum; meristematic regions precede the acropetally developing procambial bundles, (3) discrete subsidiary bundles differentiate in the meristematic regions as they advance acropetally, (4) subsidiary bundles diverge obliquely in the lamina margin giving rise to the secondary veins in a basipetal fashion, and (5) subsequent differentiation and maturation of the secondary veins occurs within the lamina. The original procambial bundles and first-formed subsidiary bundles become the secondary veins of the uppermost portions of the lamina, the next-formed subsidiary bundles become the secondary veins of the middle portions of the lamina, and the last-formed subsidiary bundles become the secondary veins of the lowermost portion of the lamina.     

Regulation of Vascular Development by CLE Peptide-receptor Systems

Cell division and differentiation of stem cells are controlled by non-cell-autonomous signals in higher organisms. The plant vascular meristem is a stem-cell tissue comprising procambial cells that produce xylem cells on one side and phloem cells on the other side. Recent studies have revealed that TDIF (tracheary element differentiation inhibitory factor)/CLE41/CLE44 peptide signal controls the procambial cell fate in a non-cell-autonomous manner. TDIF produced in and secreted from phloem cells is perceived by TDR/PXY, a leucine-rich repeat receptor kinase located in the plasma membrane of procambial cells. This signal suppresses xylem cell differentiation of procambial cells and promotes their proliferation. In addition to TDIF, some other CLE peptides play roles in vascular development. Here, we summarize recent advances in CLE signaling governing vascular development.     

A series of novel mutants of Arabidopsis thaliana that are defective in the formation of continuous vascular network: calling the auxin signal flow canalization hypothesis into question

For the genetic analysis of molecular mechanisms underlying temporal and spatial regulation of vascular pattern formation, we isolated mutants of Arabidopsis thaliana that are impaired in vascular patterning. Microscopic examination of the cotyledonary venation of 3,400 M(3) lines led to the identification of 12 mutant lines. Genetic analysis of 8 of these mutant lines indicated that vein pattern formation in these lines resulted from monogenic recessive mutations in 7 different genes, designated VAN1 through VAN7. Mutations in VAN1 through VAN6 genes caused fragmentation (disconnection or partial loss) of lateral veins of the cotyledon and tertiary veins of the rosette leaf whereas they were less injurious to the formation of major veins. Detailed characterization of the van3 mutant using pAthb8::GUS and pTED3::GUS, as molecular markers for the early stage of vascular tissue formation showed that the provascular tissue of the cotyledonary lateral veins was differentiated in fragments during late embryogenesis. These phenotypes of the van mutants are discussed in relation to the auxin signal flow canalization hypothesis and the diffusion-reaction prepattern hypothesis, with the fragility of the continuity in the minor vein formation favoring the latter hypothesis.     

Time-lapse imaging of Arabidopsis leaf development shows dynamic patterns of procambium formation

The principles underlying the formation of leaf veins have long intrigued developmental biologists. In leaves, networks of vascular precursor procambial cells emerge from seemingly homogeneous subepidermal tissue through the selection of anatomically inconspicuous preprocambial cells. Understanding dynamics of procambium formation has been hampered by the difficulty of observing the process in vivo. Here we present a live-imaging technique that allows visual access to complex events occurring in developing leaves. We combined this method with stage-specific fluorescent markers in Arabidopsis (Arabidopsis thaliana) to visualize preprocambial strand formation and procambium differentiation during the undisturbed course of development and upon defined perturbations of vein ontogeny. Under all experimental conditions, we observed extension, termination and fusion of preprocambial strands and simultaneous initiation of procambium differentiation along entire individual veins. Our findings strongly suggest that progressiveness of preprocambial strand formation and simultaneity of procambium differentiation represent inherent properties of the mechanism underlying vein formation.     

Modification of cell proliferation patterns alters leaf vein architecture in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

Formation of leaf vascular pattern requires regulation of a number of cellular processes, including cell proliferation. To assess the role of cell proliferation during vein order formation, leaf development in genetic lines exhibiting aberrant cell proliferation patterns due to altered expression patterns of ANT and ICK1 genes was analyzed. Modification of cell proliferation patterns alters the number of higher order veins and the number of minor tertiary veins remodeled as intersecondary veins in Arabidopsis rosette leaves. Minor vein complexity, as indicated by branch point and freely ending veinlet number, is highly correlated with a decrease or increase in cell proliferation. Observations of procambial strand formation in modified cell proliferation pattern lines showed that vein pattern is specified early in leaf development and that formation of freely ending veinlets is temporally correlated with the expansion of ground meristem when cell proliferation is terminated prematurely. Taken together, our observations indicate that: (1) genes that modulate cell proliferation play a key role in regulating the meristematic competence of ground meristem cells to form procambium and vein pattern during leaf development, and (2) ANT is a crucial part of this regulation.     

ONTOGENY OF FOLIAR VENATION IN EUPHORBIA FORBESII

Six species of Euphorbia endemic to the Hawaiian Islands have disjunct veins as a normal component of their foliar anatomy. An ontogenic study of the foliar venation of one of these species, E. forbesii, showed a normal development of the foliar procambium as determined by previous studies of dicotyledonous leaves. The disjunct veinlets are isolated early in the histogenesis of the intersecondary veins when certain procambial cells fail to differentiate into vascular tissue. It appears that these cells develop into normal parenchymatous cells of the ground tissue. It is suggested that these cells are physiologically distinct from the rest of the procambial cells. In no instance was a tracheary element seen which appeared to have arisen independently of the normal procambial reticulum.     

Regulation of Vascular Development by CLE Peptide-receptor Systems

Cell division and differentiation of stem cells are controlled by non-cell-autonomous signals in higher organisms. The plant vascular meristem is a stem-cell tissue comprising procambial cells that produce xylem cells on one side and phloem cells on the other side. Recent studies have revealed that TDIF (tracheary element differentiation inhibitory factor)/CLE41/CLE44 peptide signal controls the procambial cell fate in a non-cell-autonomous manner. TDIF produced in and secreted from phloem cells is perceive...     

Cell Lineage of Vein Formation in Variegated Leaves of the C4Grass Stenotaphrum secundatum

Clonal analysis of variegated leaves of the C₄grass, Stenotaphrumsecundatum, indicates that invasions among meristematic layersoccur during the organogenetic stage of leaf development, resultingin long, broad white and green stripes. These layer invasionscease prior to the second phase of leaf development when delimitationof leaf regions occurs. Vein precursors mostly arise duringthe second phase, so that procambial strand formation is superimposedon the lineage makeup of earlier-formed tissue. Anatomical evidenceindicates that procambium arises through formative divisionswithin ground tissue of leaf primordia and that each strandis derived from a variable number (one–four) of groundmeristem precursors. If a developing vein straddles the boundarybetween previously-formed green and white sectors, then themature vein is half green and half white, reflecting its mixedcell lineage. In Stenotaphrum, 24.8% of the sectors observedwere bounded by such ‘half veins’. The temporalrelationship of layer invasion and tissue system delimitationin this species supports the view that positional signals aremore important than lineage history in the determination oftissue type. However, analysis of planes of cell division indeveloping veins indicates, that, once formed, procambial strandsare discrete lineage units that extend longitudinally by proliferativedivisions. Thus, lineage restrictions may play an importantrole in the third stage of leaf development, differentiationof tissues and cells, which also includes the maintenance ofcell identity.Copyright 2000 Annals of Botany Company C₄photosynthesis, cell lineage, clonal analysis, leaf development, St. Augustine’s grass,Stenotaphrum secundatum , variegation, vein formation     

Enhancement of secondary xylem cell proliferation by Arabidopsis cyclin D overexpression in tobacco plants

Secondary xylem is composed of daughter cells produced by the vascular cambium in the stem. Cell proliferation of the secondary xylem is the result of long-range cell division in the vascular cambium. Most xylem cells have a thickened secondary cell wall, representing a large amount of biomass storage. Therefore, regulation of cell division in the vascular cambium and differentiation into secondary xylem is important for biomass production. Cell division is regulated by cell cycle regulators. In this study, we confirm that cell cycle regulators influence cell division in the vascular cambium in tobacco. We produced transgenic tobacco that expresses Arabidopsis thaliana cyclin D2;1 (AtcycD2;1) and AtE2Fa-DPa under the control of the CaMV35S promoter. Each gene is a positive regulator of the cell cycle, and is known to influence the transition from G1 phase to S phase. AtcycD2;1-overexpressing tobacco had more secondary xylem cells when compared with control plants. In order to evaluate cell division activity in the vascular cambium, we prepared a Populus trichocarpa cycB1;1 (PtcycB1;1) promoter containing a destruction box motif for ubiquitination and a β-glucuronidase-encoding gene (PtcycB1;1pro:GUS). In transgenic tobacco containing PtcycB1;1pro:GUS, GUS staining was specifically observed in meristem tissues, such as the root apical meristem and vascular cambium. In addition, mitosis-monitoring plants containing AtcycD2;1 had stronger GUS staining in the cambium when compared with control plants. Our results indicated that overexpression of AtcycD enhances cell division in the vascular cambium and increases secondary xylem differentiation in tobacco. Key message We succeeded in inducing cell proliferation of cambium and enlargement of secondary xylem region by AtcycD overexpression. We also evaluated mitotic activity in cambium using cyclin-GUS fusion protein from poplar.     

ONTOGENY OF THE CLOSED DICHOTOMOUS VENATION OF REGNELLIDIUM

Pray , Thomas R. (U. South. California, Los Angeles.) Ontogeny of the closed dichotomous venation of Regnellidium . Amer. Jour. Bot. 49(5): 464–472. Illus. 1962.—The venation of the pinna of Regnellidium consists of a flabellate series of dichotomizing vascular strands, branches of a single pinna trace. At the laminal margin, the entire venation is closed by a marginal vein. The development of the pinna was investigated primarily by means of paradermal sections. During early development, the organization of the marginal meristem and its derivatives is very similar to that previously described for Nephrolepis. The arrangement of cells in the embryonic pinna is predisposed for the differentiation of dichotomizing procambial strands. During the final phases of pinna development, the marginal meristem is altered in such a manner as to result in a submarginal band of elongated cells which differentiates a marginal procambial strand connecting the tips of the dichotomizing veins. Relatively late in pinna ontogeny and after the entire procambial venation pattern has been delimited, the marginal meristem becomes inactive. The possible correlation between extended marginal growth and dichotomizing veins is discussed.     

Asymmetric auxin response precedes asymmetric growth and differentiation of asymmetric leaf1 and asymmetric leaf2 Arabidopsis leaves

We have analyzed the development of leaf shape and vascular pattern in leaves mutant for ASYMMETRIC LEAVES1 (AS1) or AS2 and compared the timing of developmental landmarks to cellular response to auxin, as measured by expression of the DR5:beta-glucuronidase (GUS) transgene and to cell division, as measured by expression of the cycB1:GUS transgene. We found that the earliest visible defect in both as1 and as2 first leaves is the asymmetric placement of auxin response at the distal leaf tip. This precedes visible changes in leaf morphology, asymmetric placement of the distal margin gap, formation of margin gaps along the leaf border, asymmetric distribution of marginal auxin, and asymmetry in cell division patterns. Moreover, treatment of developing leaves with either exogenous auxin or an auxin transport inhibitor eliminates asymmetric auxin response and subsequent asymmetric leaf development. We propose that the initial asymmetric placement of auxin at the leaf tip gives rise to later asymmetries in the internal auxin sources, which subsequently result in asymmetrical cell differentiation and division patterns.     

VH1, a provascular cell-specific receptor kinase that influences leaf cell patterns in Arabidopsis

The formation of the venation pattern in leaves is ideal for examining signaling pathways that recognize and respond to spatial and temporal information, because the pattern is two-dimensional and heritable and the resulting veins influence the three-dimensional spatial organization of the surrounding differentiating leaf cell types. We identified a provascular/procambial cell-specific gene that encodes a Leu-rich repeat receptor kinase, which we named VASCULAR HIGHWAY1 (VH1). A change in the expression domain and level of VH1 marks the transition from an uncommitted provascular state to a committed procambial state in early vascular development. The coding sequence, expression pattern, and transgenic phenotypes together suggest that VH1 transduces extracellular spatial and temporal signals into downstream cell differentiation responses in provascular/procambial cells.     

The Morphology and Development of Cross Veins in the Leaves of Bread Wheat (Triticum aestivum L.)

In the leaves of bread wheat Triticum aestivum L. the longitudinalvascular bundles are linked by small transverse bundles Pairsof similar small vascular bundles also link the upper ends ofminor longitudinal bundles to their neighbours in a Y-shapedarrangement The cross-vein procambial strands arise from unexpanded cellsof one layer of the mesophyll tissue. Lines of these cells connectone longitudinal procambial strand to the next The procambialcells subsequently undergo two tangential divisions to producecells which differentiate to form the conducting and parenchymatouselements of the mature cross veins. Anomalous cross veins are sometimes found. possible modes oforigin of these anomalous cross veins are considered.     

Stage-specific markers define early steps of procambium development in Arabidopsis leaves and correlate termination of vein formation with mesophyll differentiation

During leaf development, ground meristem cells along continuous lines undergo coordinated oriented cell divisions and differentiate to form procambial cells, the precursors of all vascular cells. The molecular genetic dissection of early procambial development suffers from the lack of easily identifiable markers, especially of cell states preceding procambium formation. In this study, we have identified and characterized three reporter gene expression markers that reflect three distinct preprocambial stages, as well as one marker whose expression seems to be perfectly congruent with the appearance of procambial cells. All four markers are invariably expressed in continuous domains connected to pre-existing vasculature and their expression profiles reveal a common spatiotemporal pattern of early vein formation. We observed progressive extension of vascular strands at the preprocambial stage, suggesting that veins are initiated as freely ending preprocambial domains and that network formation occurs through subsequent fusion of these domains. Consistent with this interpretation, we demonstrate that veins are generally not programmed to become freely ending or interconnected network elements. Instead, we found that the progressive extension of preprocambial domains can be interrupted experimentally and that this leads to less complex vein patterns consisting of fewer vein orders, in which even lower-order veins become freely ending. Mesophyll differentiation turned out to be strictly correlated with the termination of preprocambial domain extension. These findings suggest that Arabidopsis vein pattern is not inherently determinate, but arises through reiterative initiation of new preprocambial branches until this process becomes terminated by the differentiation of mesophyll.     

木立芦荟叶的发育解剖学研究

应用植物解剖学方法研究了木立芦荟（Aloe arborescens Mill.)叶的发育过程。研究结果表明,叶原基在发育早期其形态是不对称的,内部为同形细胞组成,但很快分化成原表皮,原形成层束和基本分生组织。以后,原表皮发育成表皮,位于原表皮下的2－5层基本分生组织细胞发民同化薄壁组织,而位于中央的基本分生组织细胞则发育成储水薄壁组织,原形成层束发育成维管束。维管束由维管束鞘、木质部、韧皮部和大型薄壁细胞组成。大型薄壁细胞起源于原形成层束,位于韧皮部内,其发育迟于筛管、伴胞,为芦荟属植物叶的结构特征。