TRANSLOCATION OF 14C METABOLITES IN CARROT ROOT

Four-month-old carrot plants exposed to ¹⁴CO₂ for 1 hr in light were harvested successively at 1, 5, 10, 26, and 78 hr after initial exposure. Half-mm thick transverse slices from 3 and 10 cm below the crown were frozen quickly, freeze-dried, and autoradiographed on film. Radioactivity was first localized in a ring surrounding the cambium. The radioactive region extended centrifugally along radii as discrete loci to half the phloem thickness in 10 hr, in a pattern similar to radial rows of callose-stained sieve elements. Median longitudinal sections stained for callose demonstrated the presence of anastomosing sieve tube strands between the more vertical sieve tubes of differing age. Radioactive materials did not move across the cambium for 5–10 hr. These data fit with the decreased growth, in earlier studies, of uniform phloem explants removed from increasing distances from the cambium and of the lesser growth than phloem of similar xylem explants.     

Role of hormones in controlling vascular differentiation and the mechanism of lateral root initiation

The vascular system in plants is induced and controlled by streams of inductive hormonal signals. Auxin produced in young leaves is the primary controlling signal in vascular differentiation. Its polar and non-polar transport pathways and major controlling mechanisms are clarified. Ethylene produced in differentiating protoxylem vessels is the signal that triggers lateral root initiation, while tumor-induced ethylene is a limiting and controlling factor of crown gall development and its vascular differentiation. Gibberellin produced in mature leaves moves non-polarly and promotes elongation, regulates cambium activity and induces long fibers. Cytokinin from the root cap moves upward to promote cambial activity and stimulate shoot growth and branching, while strigolactone from the root inhibits branching. Furthermore, the role of the hormonal signals in controlling the type of differentiating vascular elements and gradients of conduit size and density, and how they regulate plant adaptation and have shaped wood evolution are elucidated.     

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.     

Overexpression of the maize Teosinte Branched1 gene in wheat suppresses tiller development

The number of viable shoots influences the overall architecture and productivity of wheat (Triticum aestivum L.). The development of lateral branches, or tillers, largely determines the resultant canopy. Tillers develop from the outgrowth of axillary buds, which form in leaf axils at the crown of the plant. Tiller number can be reduced if axillary buds are not formed or if the outgrowth of these buds is restricted. The teosinte branched1 (tb1) gene in maize, and homologs in rice and Arabidopsis, genetically regulate vegetative branching. In maize, increased expression of the tb1 gene restricts the outgrowth of axillary buds into lateral branches. In this study, the maize tb1 gene was introduced through transformation into the wheat cultivar "Bobwhite" to determine the effect of tb1 overexpression on wheat shoot architecture. Examination of multiple generations of plants reveals that tb1 overexpression in wheat results in reduced tiller and spike number. In addition, the number of spikelets on the spike and leaf number were significantly greater in tb1-expressing plants, and the height of these plants was also reduced. These data reveal that the function of the tb1 gene and genetic regulation of lateral branching via the tb1 mode of action is conserved between wheat, rice, maize and Arabidopsis. Thus, the tb1 gene can be used to alter plant architecture in agriculturally important crops like wheat.     

Between Xylem and Phloem: The Genetic Control of Cambial Activity in Plants

Abstract: Post-embryonic development is controlled by two types of meristems: apical and lateral. There has been considerable progress recently in understanding the function of root and shoot apical meristems at the molecular level. Knowledge of analogous processes in the lateral, or secondary, meristems, i.e. the vascular cambium or cork cambium, is, however, rudimentary. This is despite the fact that much of the diversity in the plant kingdom is based on the differential functions of these meristems, emphasizing the importance of lateral meristems in the development of different plant forms. The vascular cambium is particularly important for woody plants, but it also plays an important role during the development of various herbaceous species, such as Arabidopsis thaliana. In this review, we focus on the two basic functions of cambial activity: cell proliferation and pattern formation.     

What genes make a tree a tree?

Woody growth is evolutionarily ancient, yet has been gained and lost multiple times in plant evolution and is readily enhanced or minimized in eudicot speciation. New molecular genetic and genomic studies in Populus and Arabidopsis that are defining the genes responsible for cambium function and woody growth suggest that the genes regulating woody growth are not unique to woody plants. Surprisingly, key genetic mechanisms originally characterized as regulating the meristematic cells of the shoot apical meristem are also expressed in the vascular cambium during woody growth. This has important implications for the development of Populus as a model species and illustrates why forest trees constitute a contrived group of plants that have more in common with herbaceous relatives than we foresters like to admit.     

Nauclea diderrichii: rooting of stem cuttings,clonal variation in shoot dominance,and branch plagiotropism

Summary Nauclea diderrichii (De Wild, and Th. Dur.) Merill (Rubiaceae), an indigenous hardwood of West Africa, is increasingly being grown commercially. This study investigates the potential for vegetative propagation and clonal selection, and raises some fundamental questions about the physiology of apical dominance and of plagiotropism. Rooting ability was high, with up to 100% rooting in 2–4 weeks, when different Indole-3-butyric acid (IBA) concentrations and leaf areas were tested. Auxin applications greatly increased the numbers of roots per cutting. The decapitation of unbranched plants revealed clonal variation in apical dominance and also in the establishment of outright dominance by the two shoots formed from the outgrowth of the axillary buds of the opposite leaves at the top node. Regression analysis of the Dominance Ratio (length of dominant: length of the sub-dominant shoot at the time of achieving dominance) against overall lateral bud activity (r = 0.82), showed that when the two top shoots co-dominate they provide a more powerful source of Correlative Inhibition than when one of the top shoots dominates the other. The imposition of plagiotropism in the axillary bud occurred over a period of a few days as the terminal and axillary buds emerged from the stipule. Growth of accessory buds on intact plants and debranched cuttings was orthotropic. These results are discussed with regard to the role of the leaf in root formation and the understanding of dominance relationships, branching and crown development in trees.     

AXR1 acts after lateral bud formation to inhibit lateral bud growth in Arabidopsis

The AXR1 gene of Arabidopsis is required for many auxin responses. The highly branched shoot phenotype of mature axr1 mutant plants has been taken as genetic evidence for a role of auxin in the control of shoot branching. We compared the development of lateral shoots in wild-type Columbia and axr1-12 plants. In the wild type, the pattern of lateral shoot development depends on the developmental stage of the plant. During prolonged vegetative growth, axillary shoots arise and develop in a basal-apical sequence. After floral transition, axillary shoots arise rapidly along the primary shoot axis and grow out to form lateral inflorescences in an apical-basal sequence. For both patterns, the axr1 mutation does not affect the timing of axillary meristem formation; however, subsequent lateral shoot development proceeds more rapidly in axr1 plants. The outgrowth of lateral inflorescences from excised cauline nodes of wild-type plants is inhibited by apical auxin. axr1-12 nodes are resistant to this inhibition. These results provide evidence for common control of axillary growth in both patterns, and suggest a role for auxin during the late stages of axillary shoot development following the formation of the axillary bud and several axillary leaf primordia.     

Continuity of Procambium and Anomalous Cambium During Formation of Successive Cambia in Celosia argentea

The development of woody plants is related to the continuity of the procambium and cambium. Whether such a continuity is present in plants with successive cambia, especially in those, where the first cambium is formed outside the primary vascular bundles, has not been analyzed so far. Therefore, we studied the development of vascular meristem in Celosia argentea, in which the first and successive cambial cylinders arise outside the primary bundles and, intriguingly, in the literature are interpreted as developmentally independent structures. Our results showed that in C. argentea, the outermost procambial cells maintain their meristematic characteristics during differentiation of vascular bundles and divide periclinally, forming the zone of procambium-derived cells outside the primary bundles. This zone comprises parenchyma cells bordering the bundles, and a continuous ring of the incipient cambial cells neighboring the primary cortex. Later in the development, the ability to preserve the outermost cells in the cambium undifferentiated is repeated during the formation of successive cylinders of cambia. Together, our results clearly point to the developmental continuity of the procambium and successive cambia in C. argentea, despite their seemingly spatial distinctiveness. We postulate that the mechanism demonstrated in C. argentea is universal and orchestrates the development of successive cambia in other plant species.

     

Influence of summer sowing dates, N fertilization and irrigation on autumn VSP accumulation and dynamics of spring regrowth in alfalfa (Medicago sativa L.).

Herbage yield of alfalfa (Medicago sativa L.) depends on forage management or environmental conditions that change C and N resource acquisition, and endogenous plants factors such as root organic reserves and number of active meristems. The aim of this work is to study the influence of two sowing dates in summer (12 July or 9 August), N fertilization (0 or 100 kg ha(-1)) and/or irrigation applied during the first year of alfalfa establishment on (i) the accumulation of N organic reserves (soluble proteins and more specifically vegetative storage protein) in taproots during autumn, (ii) the number of crown axillary meristems present at the end of winter and (iii) the dynamics of spring shoot growth. Delaying the sowing date for one month reduced root growth and root N storage, especially vegetative storage proteins (VSP) during autumn. Irrespective of sowing dates, N fertilization did not affect root biomass, number of crown buds, total root N, root soluble protein or VSP concentrations. By contrast, water deficiency during alfalfa establishment in the early summer reduced both root growth and N reserve accumulation. When spring growth resumed, there is a significant linear relationship between leaf area development and soluble protein and VSP concentrations in taproots, and also the number of crown buds. The results showed that an early sowing date and adequate water status during the summer allowed alfalfa plants to accumulate N reserves by increasing taproot mass and soluble protein concentrations, especially VSPs. This resulted in rapid shoot regrowth rates the following spring.     

Alcohol dehydrogenase and ethanol in the stems of trees : evidence for anaerobic metabolism in the vascular cambium

Anaerobic fermentation in plants is usually thought to be a transient phenomenon, brought about by environmental limitations to oxygen availability, or by structural constraints to oxygen transport. The vascular cambium of trees is separated from the air by the outer bark and secondary phloem, and we hypothesized that the cambium may experience sufficient hypoxia to induce anaerobic fermentation. We found high alcohol dehydrogenase activity in the cambium of several tree species. Mean activity of alcohol dehydrogenase in Populus deltoides was 165 micromoles NADH oxidized per minute per gram fresh weight in May. Pyruvate decarboxylase activity was also present in the cambium of P. deltoides, with mean activity of 26 micromoles NADH oxidized per minute per gram fresh weight in May. Lactate dehydrogenase activity was not present in any tree species we examined. Contrary to our expectation, alcohol dehydrogenase activity was inversely related to bark thickness in Acer saccharum and unrelated to bark thickness in two Populus species. Bark thickness may be less important in limiting oxygen availability to the cambium than is oxygen consumption by rapidly respiring phloem and cambium in actively growing trees. Ethanol was present in the vascular cambium of all species examined, with mean concentrations of 35 to 143 nanomoles per gram fresh weight, depending on species. Ethanol was also present in xylem sap and may have been released from the cambium into the transpiration stream. The presence in the cambium of the enzymes necessary for fermentation as well as the products of fermentation is evidence that respiration in the vascular cambium of trees may be oxygen-limited, but other biosynthetic origins of ethanol have not been ruled out.     

New approaches to the study of developing wood

Two recent papers illustrate contrasting approaches to studying gene expression during development of the xylem, the tissue that transports water and solutes around higher plants. The two methods used, studying single cells differentiating in vitro and collecting samples from across the region around the cambium of poplar trees, have both revealed genes that have altered expression during xylem development.     

Determination for inflorescence development is a stable state,separable from determination for flower development in Pisum sativum L. buds

Terminal meristems of Pisum sativum (garden pea) transit from vegetative to inflorescence development, and begin producing floral axillary meristems. Determination for inflorescence development was assessed by culturing excised buds and meristems. The first node of floral initiation (NFI) for bud expiants developing in culture and for adventitious shoots forming on cultured meristems was compared with the NFI of intact control buds. When terminal buds having eight leaf primordia were excised from plants of different ages (i.e., number of unfolded leaves) and cultured on 6-benzylaminopurine and kinetin-supplemented medium, the NFI was a function of the age of the source plant. By age 3, all terminal buds were determined for inflorescence development. Determination occurred at least eight nodes before the first axillary flower was initiated. Thus, the axillary meristems contributing to the inflorescence had not formed at the time the bud was explanted. Similar results were obtained for cultured axillary buds. In addition, meristems excised without leaf primordia from axillary buds three nodes above the cotyledons of age-3 plants gave rise to adventitious buds with an NFI of 8.3 ±0.3 nodes. In contrast seed-derived plants had an NFI of 16.5 ±0.2. Thus cells within the meristem were determined for inflorescence development. These findings indicate that determination for inflorescence development in P. sativum is a stable developmental state, separable from determination for flower development, and occurring prior to initiation of the inflorescence at the level of meristems.     

Water Deficit and Inflorescence Development in Zea mays L.

A water deficit imposed during the period of terminal male inflorescenceinitiation and early development reduced both the growth rateand the mature size of that organ in Zea mays (cv. Iochief).Growth and development of the axillary shoots, the potentialfemale inflorescences, was inhibited during the episode of waterdeficit but promoted thereafter. As a result, plants which hadbeen subjected to a water deficit at that period produced 2–3mature cobs and relatively large axillary shoots at the lowernodes, whereas plants supplied with water throughout produceda single mature cob and relatively small axillary shoots. A water deficit imposed during other growth phases did not producethis response and, moreover, a further period of deficit imposedlater in development, following a deficit at the sensitive stage,inhibited the enlargement of the axillary shoots invoked bythe earlier deficit. It did not, however, inhibit the enhancedfloral development of those axillary shoots nor reverse theinhibition of tassel growth. The data are discussed in relation to correlative inhibitionin Zea mays.     

银州柴胡根的发育解剖学研究

本研究采用常规石蜡切片结合荧光显微镜技术对银州柴胡根的发育解剖学进行了研究。结果表明:（1）银州柴胡根顶端分生组织由原分生组织及其衍生的初生分生组织组成。原生分生组织细胞体积小、排列紧密、细胞质浓厚、细胞核大而明显,具有典型的分生组织的特点;（2）初生分生组织由根冠原、表皮原、皮层原和中柱原组成。在根发育过程中,表皮、皮层和维管柱共同组成其初生结构。银州柴胡根初生木质部为二原型或三原型,外始式;同时在根表皮细胞的径向壁观察到径向壁的细胞壁加厚;（3）在根次生生长过程中,位于初生木质部和初生韧皮部之间的原形成层恢复分裂能力产生维管形成层,维管形成层不断地向外产生次生韧皮部,向内产生次生木质部;同时位于根内皮层内方的中柱鞘细胞恢复分裂能力产生木栓形成层,木栓形成层向外形成木栓层,向内形成栓内层。在维管形成层和木栓形成层分裂的过程中,在次生韧皮部和中柱鞘组织中产生形态大小不同的分泌道,均为次生的裂生型分泌道。研究认为,银州柴胡根的结构类似于药典收录的北柴胡和红柴胡根的结构特点,但其根表皮细胞径向壁加厚、木纤维的分布、分泌道的大小和数量等有别于柴胡属其它植物,可作为柴胡属植物重要的分类鉴定依据。     

A novel function of TDIF-related peptides: promotion of axillary bud formation

Small peptides derived from the CLAVATA3/EMBRYO SURROUNDING REGION-related (CLE) gene family play a key role in various cell-cell communications in land plants. Among them, tracheary element differentiation inhibition factor (TDIF; CLE41/CLE44 peptide) and CLE42 peptide of Arabidopsis have almost identical amino acid sequences and act as inhibitors of tracheary element differentiation. In this study, we report a novel function of TDIF and CLE42. We found by the GUS (β-glucuronidase) reporter gene assay that while CLE41 and CLE44 are expressed preferentially in vascular bundles, CLE42 is expressed strongly in the shoot apical meristem (SAM) and axillary meristems. Overexpression of CLE42 and CLE41 enhanced axillary bud formation in the leaf and cotyledon axils. Before floral transition, the emergence of axillary buds in these plants occurred in an acropetal order. Exogenous supply of either TDIF or CLE42 peptide to the wild type induced similar excess bud emergence. In vascular bundles, the TDIF RECEPTOR (TDR) acts as the main receptor for TDIF. The axillary bud emergence of tdr mutants was little affected by either of the peptides. It was confirmed by scanning electron microscopy that peptide-treated wild-type plants form an axillary meristem-like structure earlier than non-treated plants. SHOOT MERISTEMLESS (STM), a marker gene for meristems, was up-regulated in peptide-treated plants before the axillary meristem becomes morphologically distinguishable. These results indicate that CLE42 peptide and TDIF have an activity to enhance axillary bud formation via the TDR. Judging from its expression pattern, CLE42 may play an important role in the regulation of secondary shoot development.