Effect of mutations in the PINHEAD gene of Arabidopsis on the formation of shoot apical meristems

The primary shoot apical meristem of angiosperm plants is formed during embryogenesis. Lateral shoot apical meristems arise postembryonically in the axils of leaves. Recessive mutations at the PINHEAD locus of Arabidopsis interfere with the ability of both the primary shoot apical meristem as well as lateral shoot apical meristems to form. However, adventitious shoot apical meristems can form in pinhead mutant seedlings from the axils of the cotyledons and also from cultred root explants. In this report, the phenotype of pinhead mutants is described, and a hypothesis for the role of the wild-type PINHEAD gene product in shoot meristem initiation is presented. © 1995 Wiley-Liss, Inc.     

Independence of Organogenesis and Cell Pattern in Developing Angle Shoots of Selaginella martensii

Angle meristems are mounds of meristematic tissue located atdorsal and/or ventral branch points of the dichotomising stemaxes of many species of Selaginella (Lycophyta). The presentstudy examined the development of ventral angle shoots of S.martensii in response to removal of distal shoot apices (decapitation).Scanning electron microscopy of sequential replicas of developingangle meristems and angle shoots revealed that for the firsttwo pseudowhorls of leaf primordia, particular leaves are notattributable to particular merophytes of the angle meristemapical cell. Individual leaf primordia of the first (outer)pseudowhorl often form from more than one merophyte. Neitherthe shape of the angle meristem apical cell nor the directionof segmentation has any effect on the development of the angleshoot. Additionally, the apical cell of the angle meristem doesnot necessarily contribute directly to either of the new shootapices of the developing angle shoot. The first bifurcationof the angle shoot shows a remarkably consistent relationshipto the branching pattern of the parent shoot. The strong branchof the first angle shoot bifurcation typically occurs towardthe weak side branch of the parent shoot. Anatomical studiesshowed that bifurcation of the young angle shoot involved theformation of two new growth centres some distance away fromthe original angle meristem apical cell; new apical cells subsequentlyformed within these. These results provide additional supportfor the view that cell lineage has little or no effect on finalform or structure in plants.Copyright 1994, 1999 Academic Press Selaginella martensii Spring, Lycophyta, angle meristem, apical cell, shoot apical meristem, leaf primordium, branching, dichotomy, morphogenesis, determination, competence, development, mould and cast technique, replica technique, scanning electron microscopy     

Survival and growth of eastern white pine shoot apical meristemsin vitro

Shoot apical meristems of seedling and mature eastern white pine trees were excised and grownin vitro. Placing the meristems on filters instead of directly on agarose-solidified nutrient medium enhanced survival of both juvenile and mature meristems. Applying forcing treatments to mature branches improved survival and growth of dissected meristems compared with meristems from non-forced branches in experiments conducted over two years. No consistent differences were observed among 2-, 4-, and 6-week forcing treatments. Including 5.37 nM (0.001 mg l^-1) l-naphthaleneacetic acid in the culture medium did not affect meristem survival or growth. Some meristems from seedlings grew rapidly, produced primary leaves, underwent internode elongation, and in three cases, produced adventitious roots. Meristems from mature trees did not grow as rapidly as seedling meristems. The leaves produced by mature meristems appeared to be scale leaves and a few of these had brachyblast primordia in the axils. The shoots derived from mature meristems did not produce adventitious roots.     

Development of maize plants from cultured shoot apices

Excised shoot apices of maize (Zea mays L.), comprising the apical meristem and one or two leaf primordia, have been cultured and can form rooted plantlets. The plantlets, derived from meristems that had previously formed 7–10 nodes, develop into mature, morphologically normal plants with as many nodes as seed-grown plants. These culture-derived plants exhibited the normal pattern of development, with regard to the progression of leaf lengths along the plant and position of axillary buds and aar shoots. Isolation of the meristem from previously formed nodes reinitiates the pattern and number of nodes formed in the new plant. Thus, cells of the meristem of a maize plant at the seedling stage are not determined to form a limited number of nodes.     

Shoot organization genes regulate shoot apical meristem organization and the pattern of leaf primordium initiation in rice

The mechanism regulating the pattern of leaf initiation was analyzed by using shoot organization (sho) mutants derived from three loci (SHO1, SHO2, and SHO3). In the early vegetative phase, sho mutants show an increased rate of leaf production with random phyllotaxy. The resulting leaves are malformed, threadlike, or short and narrow. Their shoot apical meristems are relatively low and wide, that is, flat shaped, although their shape and size are highly variable among plants of the same genotype. Statistical analysis reveals that the shape of the shoot meristem rather than its size is closely correlated with the variations of plastochron and phyllotaxy. Rapid and random leaf production in sho mutants is correlated with the frequent and disorganized cell divisions in the shoot meristem and with a reduction of expression domain of a rice homeobox gene, OSH1. These changes in the organization and behavior of the shoot apical meristems suggest that sho mutants have fewer indeterminate cells and more determinate cells than wild type, with many cells acting as leaf founder cells. Thus, the SHO genes have an important role in maintaining the proper organization of the shoot apical meristem, which is essential for the normal initiation pattern of leaf primordia.     

Cells within the nodal region of carnation shoots exhibit a high potential for adventitious shoot formation

Adventitious shoot formation was studied with leaf, stem and axillary bud explants of carnation (Dianthus caryophyllus L.). The shoot regeneration procedures were applicable for a wide range of cultivars and shoot regeneration percentages were high for all explant types. Using axillary bud explants, shoot regeneration efficiency was independent of the size of the bud and of its original position in the plant. In contrast, shoot regeneration from stem and leaf explants was strongly dependent on their original position on the plant. The most distal explants (just below the apex) showed the highest level of shoot regeneration. The adventitious shoot primordia developed at the periphery of the stem segment and at the base of leaf explants. In axillary bud, stem and leaf explants, shoot regeneration originated from node cells, located at the transition area between leaf and stem tissue. Moreover, a gradient in shoot regeneration response was observed, increasing towards the apical meristem.Abbreviations BA benzyladenine - NAA naphthaleneacetic acid     

The SHOOT MERISTEMLESS gene is required for maintenance of undifferentiated cells in Arabidopsis shoot and floral meristems and acts at a different regulatory level than the meristem genes WUSCHEL and ZWILLE

The function of the SHOOT MERISTEMLESS (STM) gene in shoot and floral meristems throughout Arabidopsis development has been analyzed. The results show that STM plays a major role in maintaining shoot and floral meristems. In an allelic series of stm mutants the shoot meristem was either reduced or completely absent in mature embryos and mutant seedling cotyledons showed partial fusion, indicating that the STM gene affects embryonic shoot meristem development and spacing of cotyledons. Postembryonically, stm mutants initiated adventitious shoot development at a position corresponding to the shoot meristem in wild-type. Repetitively initiated defective mutant shoot and floral meristems were consumed during primordia formation and typically terminated prematurely in fused ectopic primordia, indicating that STM is required for continuous shoot and floral meristem function. Analogous defects were observed in stm embryonic and postembryonic development suggesting that similar mechanisms are employed in embryonic and postembryonic organ primordia initiation. Allelic combinations suggest different thresholds for STM requirement during plant development. STM requirement could not be bypassed by standard growth factor regimes or by shoot regeneration from calli. The results suggest that STM functions by preventing incorporation of cells in the meristem center into differentiating organ primordia and that this role can completely account for all defects observed in stm mutants. Mutations in the WUSCHEL (WUS) and ZWILLE (ZLL) genes result in defective organization and premature termination of shoot meristems. Genetic interactions between STM, WUS and ZLL were analyzed and the results indicate that STM acts upstream of WUS and ZLL. Therefore, while STM appears to function in keeping central meristem cells undifferentiated, WUS and ZLL seem to be subsequently required for proper function of these cells.     

Hormonal and cell division analyses in Watsonia lepida seedlings

The regeneration ability, cell division activity, auxin and cytokinin content of seedling regions and hypocotyl subsections of Watsonia lepida were studied. A total of 21 different cytokinins or conjugates were found in seedlings, with the highest cytokinin content in meristematic regions (root and shoot apical meristems). The greatest contribution to the cytokinin pool came from the biologically inactive cZRMP, suggesting that significant de novo synthesis was occurring. Five different auxins or conjugates were detected, being concentrated largely in the shoot apical meristem and leaves, IAA being the most abundant. Analysis of hypocotyl subsections (C1–C4) revealed that cell division was highest in subsection C2, although regeneration in vitro was significantly lower than in subsection C1. Anatomically, subsection C1 contains the apical meristem, and hence has meristematic cells that are developmentally plastic. In contrast, subsection C2 has cells that have recently exited the meristem and are differentiating. Despite high rates of cell division, cells in subsection C2 appear no longer able to respond to cues that promote proliferation in vitro. Auxin and cytokinin analyses of these subsections were conducted. Possibly, a lower overall cytokinin content, and in particular the free-base cytokinins, could account for this observed difference.     

DEVELOPMENTAL ANATOMY OF DIRECT SHOOT ORGANOGENESIS FROM LEAF PETIOLES OF VITIS VINIFERA (VITACEAE)

The anatomy of direct shoot organogenesis from leaf petioles of Vitis vinifera cv. French Colombard cultured in vitro was studied by light microscopy. Regenerating petiole stubs were fixed at 2- or 3-day intervals and sectioned longitudinally. By day 3 on regeneration medium, new cell divisions were observed. After 6 days, three distinct regions of meristematic activity were apparent within the expanding petiole stub: the wound-response, organogenic, and vascularization regions. In the organogenic region, rapid periclinal divisions of vacuolate outer cortical cells formed nodular bumps, many of which developed vascular strands and marginal meristems and formed adventitious leaves. Promeristems with small, densely staining cells and a distinct tunica layer also originated in the organogenic region, by cell division in the epidermal and subepidermal cell layers. With vascularization and the formation of leaf primordia, many promeristems became adventitious shoot meristems. Adventitious leaves and promeristems were initiated continuously from day 10 until day 33. Promeristems were often initiated near or upon adventitious leaves but could form either before or after the adventitious leaf developed. Adventitious leaves and shoot meristems developed vascular connections with the vascular bundles of the original expiant. The implication of this pattern of regeneration for Agrobacterium-mediated transformation of Vitis is discussed.     

In vitro regeneration of commercial cultivars of subterranean clover

Regeneration of subterranean clover (Trifolium subterraneum L.) was achieved by both shoot organogenesis and somatic embryogenesis. Shoots derived via organogenesis were initiated from the hypocotyls of mature imbibed seed. The hypocotyl, including the emerging radicle, was sliced longitudinally into two halves and cultured on shoot induction medium. After 30 days, adventitious shoots were formed from the hypocotyl region while the radicle showed no development. Shoots were then subcultured onto shoot multiplication medium and finally onto a root initiation medium. Histological studies revealed that shoots arose de novo and did not originate from pre-existing meristems. In the second regeneration protocol, shoot apical meristems from young seedlings were induced to form callus. Following four to six weeks culture in the dark, somatic embryos appeared spontaneously on the calli. A majority of embryos had a well-defined root pole, two cotyledonary lobes, and were capable of germination, albeit at a low frequency. Regenerated plants obtained from both protocols appeared phenotypically normal.     

Expression of CDC2Zm and KNOTTED1 during in-vitro axillary shoot meristem proliferation and adventitious shoot meristem formation in maize (Zea mays L.) and barley (Hordeum vulgare L.)

Expression of CDC2Zm and KNOTTED1 (KN1) in maize (Zea mays L.) and their cross-reacting proteins in barley (Hordeum vulgare L.) was studied using immunolocalization during in-vitro axillary shoot meristem proliferation and adventitious shoot meristem formation. Expression of CDC2Zm, a protein involved in cell division, roughly correlated with in-vitro cell proliferation and in the meristematic domes CDC2Zm expression was triggered during in-vitro proliferation. Analysis of the expression of KN1, a protein necessary for maintenance of the shoot meristem, showed that KN1 or KN1-homologue(s) expression was retained in meristematic cells during in-vitro proliferation of axillary shoot meristems. Multiple adventitious shoot meristems appeared to form directly from the KN1- or KN1 homologue(s)-expressing meristematic cells in the in-vitro proliferating meristematic domes. However, unlike Arabidopsis (Arabidopsis thaliana) and tobacco (Nicotiana tabacum) leaves ectopically expressing KN1 (G. Chuck et al., 1996 Plant Cell 8: 1277–1289; N. Sinha et al., 1993 Genes Dev. 7: 787–797), transgenic maize leaves over-expressing KN1 were unable to initiate adventitious shoot meristems on their surfaces either in planta or in vitro. Therefore, expression of KN1 is not the sole triggering factor responsible for inducing adventitious shoot meristem formation from in-vitro proliferating axillary shoot meristems in maize. Our results show that genes critical to cell division and plant development have utility in defining in-vitro plant morphogenesis at the molecular level and, in combination with transformation technologies, will be powerful tools in identifying the fundamental molecular and-or genetic triggering factor(s) responsible for reprogramming of plant cells during plant morphogenesis in-vitro. Received: 2 June 1997 / Accepted: 21 July 1997     

Gibberellin-induced reorganization of spatial relationships of emerging leaf primordia at the shoot apical meristem in Hedera helix L.

The transition from spiral to distichous leaf arrangement during gibberellic-acid (GA₃)-induced rejuvenation in Hedera was studied in detail by scanning electron microscopy of the shoot apical meristem. The transition, which involves the initiation of about 14 new leaf primordia, is accomplished by progressive increments in the divergence angle between the leaf primordia from an initial average value of 138.9 ° until it approaches 180 °. This process is preceded, as well as accompanied, by an increased radial displacement of young leaf primordia away from the apical meristem. Although the width of the leaf primordia also increases, this is unlikely to be a causal factor since it occurs only late in the transition. The size of the primordium-free area of the apical meristem is also unlikely to be involved. Quantitative analysis shows that the divergence angle of consecutive leaf primordia commonly fluctuates between relatively large and small values. Thus the transitional stages form a spirodistichous arrangement in which the divergence angle within each pair of leaves is large relative to that between leaf pairs. The stimulation of the radial displacement of the leaf primordia and the associated phyllotactic transition may involve GA₃-induced modification in the spatial organization of cortical microtubules in the apical meristem and related changes in directional cell expansion.Abbreviations DA divergence angle - GA₃ gibberellic acid We thank Mr. Gilbert Ahlstrand for his advice regarding scanning electron microscopy. This paper is contribution of the University of Minnesota Agricultural Experimental Station No. 18,726.     

In Vitro Culture and Plant Regeneration in Vicia faba subsp. Equina (var. Spring Blaze)

Explants of stem, leaves, roots, and cotyledons from etiolatedaxenically grown Vicia faba seedlings were cultured on a rangeof media. Shoot organogenesis was only obtained with nodal stemand cotyledonary node explants when cultured on MS medium with3% sucrose, 2.0 mg 1^–1 BAP and 02 mg 1^–1 NAA. Callusproliferation accompanied shoot organogenesis from nodal stemexplants. Successive subculture of nodal stem callus resultedin proliferation of regenerative callus which contained severalshoot bud initials. The capacity for shoot regeneration fromthis callus was maintained for 9 months. Histological studiesreveal de novo formation of meristematic centres in callus andtheir further development into bud primordia. High frequencyrooting of these adventitious shoots was obtained on half-strengthMS medium with 1.5% sucrose, 0.1 mg 1^–1 NAA and 0.5 mg1^–1 kinetin. Key words: Vicia faba, adventitious shoots, axillary shoots, de novomeristem formation, organogenesis, tissue culture     

<Emphasis Type="Italic">In vitro</Emphasis> organogenesis of chestnut (<Emphasis Type="Italic">Castanea sativa</Emphasis> Mill.) cotyleodon explants: responses to growth regulators and developmental aspects

Summary Adventious root and shoot formation was obtained from cotyledon fragments of chestnut (Castanea sativa Mill.) and these processes followed two phases. In a first stage after detachment of the embryonic axis, the cotyledon fragments in culture formed a cotyledon petiole, which elongated for about 6d. Thereafter, root primordia arose at the tip of the cotyledon petioles, followed by normal root development. In some cases, the cotyledon, petioles showed adventitious shoot regeneration from a nodular structure previously formed at the end of the petioles. The presence or absence of growth regulators did not significantly influence root regeneration, whereas cytokinins stimulated shoot formtion. The processes of root and shoot differentiation were studied also at the histological level. Observation with a light microscope showed that the developing root apical meristems were connected with a vascular bundle of the cotyledon petiole. Similarly, shoot bud meristem connections were observed with vascular tissue inside the nodular structure.     

DEVELOPMENT OF FLORAL ORGANS IN THE SITES OF LEAF PRIMORDIA IN PINGUICULA VULGARIS

Plants of Pinguicula vulgaris L. have either clockwise or counterclockwise spiral phyllotaxy. The inception of floral primordia occurs in leaf sites as a normal sequence of development. Only two leaf primordia initiated late in the season develop into floral primordia in the following year. They do not represent a direct modification of the apical meristem nor of the detached meristem. The apical meristem continues to produce leaves in the vegetative phase and flowers in the reproductive phase, and thus the plants show a monopodial growth. Axillary buds are not developed in this perennial species and instead additional buds of adventitious ontogeny appear. Such buds are produced on the older leaves of larger plants, and they are extremely useful in the vegetative propagation of the species.     

The shoot apex of Podostemaceae: De novo structure or reduction of the conventional type?

The paper reviews and discusses various interpretations of the shoot apex of Podostemaceae with special reference to subfamily Podostemoideae. Main questions concern (1) the proposed absence of a shoot apical meristem (SAM) in apical “meristemless” shoot tips of Podostemoideae and, as the consequence, the endogenous inception of leaf-borne leaves and branches and (2) the predicted stem bifurcation below a “terminal” dithecous (double-sheathed) leaf positioned instead of a shoot apex, as it is reported for subfamily Podostemoideae. Does the “meristemless” shoot apex represent a true evolutionary novelty? Does the view of stem bifurcation represent a new ramification pattern with the consequence that the “classical root–shoot model” of angiosperms is not valid for Podostemaceae? Both interpretations do not conform to previous studies that are complemented here by new data on the SAM of Zeylanidium olivaceum and Thelethylax minutiflora (Podostemoideae). Although a SAM is difficult to observe in the vegetative shoots of many Podostemoideae, it becomes well visible when the shoot passes into the flowering stage approaching the conspicuous shoot apex of floriferous shoots. The arguments of the absence of a SAM in vegetative shoots are not convincing and the endogenous origin of “leaf-borne leaves” appears questionable. Consequently, the “meristemless” shoot apex cannot be considered as a structure having evolved de novo. In the less advanced subfamilies Tristichoideae and Weddellinoideae, the leaf primordia develop only from a few apical cells of the outer shoot layer. This allows the conclusion that the surface layer of the apex in these subfamilies corresponds to the horizontally spread single-layered apical meristem of subfamily Podostemoideae. Similarly, the view of shoot bifurcation does not conform to the diachsial–sympodial branching pattern occurring in the cymose inflorescences of many Podostemoideae. This fact contradicts the presence of a terminal leaf.     

A novel pathway for rapid shoot regeneration from the proximal zone of the inpocotyl of melon (Cucumis melo L.)

Summary Hypocotyl explants of melon (Cucumis melo L.) are capable of regenerating multiple shoots on Murashige and Skoog (1962) medium, augmented with 4.4 μM benzylademne. Regeneration from the hypocotyl is much more rapid than the more commonly reported regeneration from cotyledonary explants, producing shoots within 2 wk compared to more than a month required for cotyledon explants. The rapid regeneration response depends on the presence of a fragment of the cotyledon remaining attached to the hypocotyl. Controls were performed to ensure that the regeneration was not due to the presence of the shoot apical bud of the melon seedling after explant production. Scanning electron microscopy revealed that microsurgery to remove the apical bud left no excess bud material. Regeneration from the proximal part of the hypocotyl was due to production of a new shoot apical meristem, observed by histology. The apical meristem can be produced before leaf primordia in regeneration from the hypocotyl, in contrast to the regeneration process from the melon cotyledon.