Specific arrangements of cortical microtubules are correlated with the architecture ofmeristems in shoot apices of angiosperms and gymnosperms

Arrangements of corticalmicrotubules (MTs) as seen in median longitudinal cryosections of shoot apices of several angiosperms and gymnosperms were studied by indirect immunofluorescence microscopy.Bryophyllum, Clethra, Helianthus, Houttuynia, Vinca (angiosperms), andPinus, Cedrus, Cedrus andGinkgo (gymnosperms) were examined. In all angiosperm apices collected during the growing season, MTs were mainly arranged anticlinally in the tunica, randomly in the corpus, and transversely in the rib meristem. This pattern of arrangements of MTs was further confirmed by electron microscopy inBryophyllum apices. In the apices of winter shoots MTs in the rib meristem were arranged randomly, indicating a seasonal change with respect to their arrangment. In all examined gymnosperm apices, populations of superficial cells showed both random and anticlinal arrangements of MTs, in contrast to those of angiosperm apices that consistently show anticlinally arranged MTs. In the shoot apices of both angiosperms and gymnosperms, cortical MTs were arranged perpendicularly to the directions of cell expansion. The significance of MTs in the maintrnance of the different architectures of shoot apices in angiosperms and gymnosperms is discussed.     

Arrangement of cortical microtubules at the surface of the shoot apex inVinca major L.: Observations by immunofluorescence microscopy

Arrangements of cortical microtubules (MTs) and of cellulose microfibrils at the surface of the vegetative shoot apex ofVinca major L. were examined by immunofluorescence microscopy and polarizing microscopy, respectively. Cortical MTs adjacent to the outermost walls of the apex were arranged more or less randomly in individual cells: especially in cells in the central region of the apex the arrangement was almost completely random. However, in the peripheral region MTs tended to show parallel alignment in individual cells, and an overall pattern that was roughly concentric around the apical dome was discerned. Observations of birefringence of cell walls indicated that cellulose microfibrils in the peripheral region of the apex were also arranged in a pattern which was roughly concentric around the apical dome. These patterns of arrangements of MTs and microfibrils are understood to be perpendicular to the radial cell files observed in the peripheral region of the apex, and can be related to the radial expansion of the surface of the apex.     

THE SHOOT APEX AND EARLY LEAF DEVELOPMENT IN CLEMATIS

Tepfer , Sanford S. (U. Oregon, Eugene.) The shoot apex and early leaf development in Clematis . Amer. Jour. Bot. 47 (8): 655–664. Illus. 1960.—The high-domed shoot apex comprises a 2-layered tunica and shallow corpus. The rib meristem at times extends to within 5 cells of the summit. The cells of tunica and corpus are uniform cytologically, distinguishable only by the orientation of division planes. No zonation is visible within the corpus. No evidence was found of the existence of a méristème d'attente; mitotic figures appear frequently in the central region of the tunica and corpus. Decussately arranged leaf primordia arise high on the flanks of the apex. Periclinal divisions in the inner tunica and outermost corpus layers mark the site of initiation. Details of the growth and early differentiation of the leaf primordia follow the usual pattern of buttress formation, growth through apical and subapical initials. Apical growth continues beyond the early stages of leaf ontogeny; the blade-forming marginal meristems do not appear until after leaflet primordia are formed. There are 5 primary leaflets, pinnately arranged. Each leaflet is 3- to 5-lobed. In primordium P₃ expansion of the adaxial-lateral margins occurs at the base, but not above. This marks the upper limits of the basal pair of lateral leaflets. In P₄ the upper limits of the upper lateral leaflets become demarcated in similar fashion.     

A SEASONAL STUDY OF THE VEGETATIVE SHOOT APEX OF MYRIOPHYLLUM HETEROPHYLLUM

The seasonal study of the vegetative shoot apex and its direct derivatives in the dicotyledonous angiosperm Myriophyllum heterophyllum during the production of its 3 leaf types revealed a great similarity in the anatomy of the apex which produced them. The apex consisted of 2 tunica layers and a corpus that varied slightly. The corpus consisted of the corpus initials, the central rib meristem, and the inner layers of the flanking meristem. The work was compared with several works, but in particular with that of Vochting (1872). Vochting worked with another species, M. spicatum, using the terminology of the histogen concept. This work has verified many of Vochting's observations in the light of today's terminology and extends the range of seasonal shoot-apical studies.     

Reorganization of cortical microtubules and cellulose deposition during leaf formation in Graptopetalum paraguayense

In the regeneration of a shoot from a leaf of the succulent, Graptopetalum paraguayense E. Walther the first new organs are leaf primordia. The original arrangement of cellulose microfibrils and of microtubules (MTs) in the epidermis of the leaf-forming site is one of parallel, straight lines. In the new primordium both structures still have a congruent arrangement but it is roughly in the form of concentric circles that surround the new cylindrical organ. The regions which undergo the greatest shift in orientation (90°) were studied in detail. Departures from the original cellulose alignment are detected in changes in the polarized-light image. Departures from the original cortical MT arrangement are detected using electron microscopy. The over-all reorganization of the MT pattern is followed by the tally of MT profiles, the various regions being studied in two perpendicular planes of section. This corrects for the difference in efficiency in counting transverse versus longitudinal profiles of MTs. Reorientation takes place sporadically, cell by cell, for both the cellulose microfibrils and the MTs, indicating a coordinated reorientation of the two structures. That MTs and cellulose microfibrils reorient jointly in individual cells was shown by reconstruction of the arrays of cortical MTs in paradermal sections of individual cells whose recent change in the orientation of cellulose deposition had been detected with polarized light. Closeness of the two alignments was also indicated by images where the MT and microfibril alignments co-varied within a single cell. The change-over in alignment of the MTs appears to involve stages where arrays of contrasting orientation co-exist to give a criss-cross image. During this critical reorganization, the frequency of the MTs is high. It falls during subsequent enlargement of the organ. It was found that the rearrangement of the cortical MTs to approximate a series of concentric circles on the residual meristem occurred before the emergence of leaf primordia. Through their apparent influence on microfibril alignments, the changes in MT disposition, described here, have the potential to generate major biophysical changes that accompany organogenesis.Abbreviation MT(s) microtubule(s)     

Structure and Cytogenesis of the Shoot Apex of Syringa oblata var. affinis Lingelsh

The structure, growth and mitotic activity of 211 shoot apices of developing sprouts of Syringa oblata var. affinis Lingelsh. in longitudinal sections and 67 in transverse sections have been studied with the view to understanding the nature of zonation patterns and cytogenesis of the apical meristems during a double plastochron. The external morphology and the anatomical structure of the apices in 4 plastochronic stage-early, middle, late Ⅰ and late Ⅱ stages are described. In the shoot apices examined, especially those at late plastochronic stage, the following zones may be delimited: Zone of tunica initials, zone of corpus initials, peripheral zone and zone of rib meristem. The location and orientation of mitotic figures observed in longisections of the apices in 4 plastochronic stages are plotted in diagrams and the mitotic frequency has been calculated. Information obtained from these investigations reveals that the tunica and corpus inititals constitute an active region of the apex, but their mitotic activity changes periodically within the double plastochron. In the middle plastochronic stage when the apex is at its minimal area and the cells of peripheral zone and rib meristem zone have been completely transformed into constituent parts of foliar primordia and the subjacent tissues of the stem and the pith mother cells respectively, the mitotic frequency of the initials is at its maximium and its intensity of mitotic activity is not much lower than that of any other meristematic zone at any stage. When the apical dome is reformed by the activity of these initials in late plastochronic stages, the mitotic frequency of the initials gradually drops and the region of high mitotic frequency shifts to the flank of the apex, the peripheral zone. Anticlinal divisions are predominant in this zone. On the other hand, those cells directly left behind by the corpus initials, which constitute the rib meristem, are vacuolated and marked by the pre- dominance of transverse divisions. Thus the entire zonation pattern reappears. In the next early plastochronic stage, the mitotic frequency of the tunica and corpus initials drops to its mimimium, but other regions of the apex still maintain a high mitotic frequency. It may be concluded that the tunica and corpus initials form a cytogenerative center of the shoot, and the cytohistological zonation is actually a result of the fact that different regions of apical meristems are different in mitotic activety, different in state of cell differentiation and different in their function in morphogenesis.     

Arrangement of microtubules during spore formation in Equisetum arvense (Equisetaceae)

The arrangement of cortical microtubules (MTs) during spore formation in Equisetum arvense was examined by immunofluorescence microscopy. The arrangement of MTs was observed to change during sporoderm formation. During exospore formation, the cortical MTs of the tapetum appeared along the tapetal plasma membrane that enclosed each developing spore cell. After exospore formation, the arrangement of the cortical MTs changed into one of separate bands of MTs arranged spirally (spiral bands of MTs). The spiral bands of MTs were superimposed on the developing elaters. This new pattern corresponded to the pattern of cellulose microfibrils deposited in the inner layer of the elater, suggesting that these spiral bands are involved in the deposition of the cellulose microfibrils in the elater. We conclude that the spiral bands of MTs are functionally equivalent to cortical MTs in secondary wall formation.     

甘蔗茎尖原生分生组织区域化

甘蔗茎尖原生分生组织是甘蔗地上部分一切形态组织的发源中心,通过对6个不同茎径甘蔗品种4个不同营养发育时期的茎尖原生分生组织显微和超微结构观察研究发现:甘蔗茎尖原生分生组织呈半卵型结构,明显分为原套原始细胞区、原体原始细胞区、周缘分生细胞区、髓分生区,其区域化符合原套-原体学说。原套原始细胞区为最外一层细胞,原套细胞之间胞间连丝丰富,而原套与原体细胞之间胞间连丝极少,细胞以垂周分裂为主,扩大原生分生组织表面积;原体位于原套下的分生组织的中央区域,细胞可以进行各个方向的分裂,不断增加体积,原体原始细胞区呈一个球体;周缘分生区位于原套、原体下方两侧,细胞活跃产生叶原基和原形成层细胞;髓分生区细胞位于原体下方周缘分生区内侧,细胞横向分裂纵向排列,使甘蔗茎伸长。     

Ontogeny of Axillary and Accessory Buds in Clerodendrum phlomidis L.

Plastochronic changes in the vegetative shoot apex and originand development of axillary and accessory buds are studied. The flat shoot apex shows structural and dimensional changesin a plastochron. They are described in three phases, the pre-leafinitiation, the leaf initiation, and the post-leaf initiation.The youngest axillary bud meristem is identified near the axilat the second node when the subtending leaf primordium is 200–12µ long. The corpus of the bud meristem has a more activerole in bud development than has the tunica layers. The shellzone associated with a young bud meristem persists until thebud has attained the structural and functional attributes ofthe main shoot apex. It loses its histological identity by producingderivatives which merge with the ground tissue and procambialcells of bud traces. In a developing bud the provascular systemof the bud appears as an arc, a loop, or as a ring in transversesections at different levels. These configurations are composedof anastomosing procambial strands of bud trace and residualmeristem, both being differentiated from developing bud meristem.     

TENDRILS OF PASSIFLORA FOETIDA: HISTOGENESIS AND MORPHOLOGY

Passiflora foetida bears an unbranched tendril, one or two laterally situated flowers, and one accessory vegetative bud in the axil of each leaf. The vegetative shoot apex has a single-layered tunica and an inner corpus. The degree of stratification in the peripheral meristem, the discreteness of the central meristem, and its centric and acentric position in the shoot apex are important plastochronic features. The procambium of the lateral leaf trace is close to the site of stipule initiation. The main axillary bud differentiates at the second node below the shoot apex. Adaxial to the bud 1–3 layers of cells form a shell-zone delimiting the bud meristem from the surrounding cells. A group of cells of the bud meristem adjacent to the axis later differentiates as an accessory bud. A second accessory bud also develops from the main bud opposite the previous one. A bud complex then consists of two laterally placed accessory bud primordia and a centrally-situated tendril bud primordium. The two accessory bud primordia differentiate into floral branches. During this development the initiation of a third vegetative accessory bud occurs on the axis just above the insertion of the tendril. This accessory bud develops into a vegetative branch and does not arise from the tissue of the tendril and adjacent two floral buds. The trace of the tendril bud consists of two procambial strands. There is a single strand for the floral branch trace. The tendril primordium grows by marked meristematic activity of its apical region and general intercalary growth.     

Changes in the anatomical structure of the shoot apex ofSenecio vulgaris L. during ontogenis in relation to the formation of leaves and inflorescence

An investigation was made of the anatomical structure of the shoot apex ofSenecio vulgaris L. a photoperiodically neutral plant, and compared with the formation of successive leaf primordia along the axis up to the initiation of the terminal inflorescence. In the shoot apex of a germinating plant a central zone can first be distinguished from the peripheral zone which is composed of small and intensely stained cells. Later, a rib meristem appears. At the time of the initiation of the middle (the largest) leaves, the shoot apex has a distinct small central zone and a well developed peripheral zone and rib meristem. Between these zones there is a group of cells dividing in all directions, the subcentral zone. At the time of initiation of the last leaves, the central zone extends to the flanks and gradually ceases to be distinguishable. At the same time, the subcentral zone increases in size. This is caused first by cell division and later, with the initiation of the last, most reduced leaves, by enlargement of the cells. Vacuolization in the inner part of the apex and the arrangement of the superficial cells in rows parallel to the surface of the apex, is a preparatory step to the initiation of the inflorescence.     

Growth and Development of the Banana Plant: II. The Transition from the Vegetative to the Floral Shoot in Musa acuminata cv. Gros Michel

The changes that occur in the shoot apex of the banana, as itpasses from the vegetative to the flowering stage, are described.The crucial events occur well before floral primordia are evident,and they require a redistribution of activity in the variousgrowing regions. The vegetative shoot apex is in a central depressionin the rhizome; there is virtually no internodal growth in theaxis, the most active growth is in the leaf bases; vegetativebuds do not form in the leaf axils but only appear adventitiouslyfar from the tip of the shoot. With the onset of flowering thisis changed; growth in the axis itself, previously suppressed,occurs and flower buds arise as primordia in the axils of subtendingbracts. The bracts do not show the market growth in their baseswhich is so characteristic of leaves. Thus, the shoot apex risesto the level of the rhizome and then above it; as it does so,its tip changes in shape from a broad flattened some to a pointedcone. At the transitional stage, more activity occurs in thecells of the mantle, or tunica, which now consists of 3 to 4layers over the central dome. Below, in the central or mothercell zone of the corpus, which was quiescent in the vegetativeshoot, the cells spring into greater activity, becoming moreprotoplasmic and stain more deeply. Directly below this regionin the rib meristem, cells show transverse divisions. Bractprimordia occur high on the flanks of the apex, and, thoughthey originate in the manner of leaves, their subsequent growthis different. Flower primordia occur even in the axils of bractsclose to the shoot tip. Thus, the problem now is to designatethe source, nature, and mode of action of the stimuli whichinitiate and control this quite different distribution of growthin the floral, as contrasted with the vegetative, shoot. Thesignificance of the previously more quiescent central, or mothercell zone, of the apex as the source of such stimuli, is stressed.Thus, flowering first requires that the limiting controls whichapply to the vegetative shoot be released, and, secondly, thatthe apex of the shoot, rather than the leaf base, becomes themain centre of growth and development.     

Structure and seasonal study of the shoot apex of two species ofAraucaria

Summary and Conclusions The shoot apices ofAraucaria columnaris andA. bidwillii exhibit a tunica-corpus organization. In the former the tunica is one-layered during spring and summer months and becomes more stratified during winter months. InA. bidwillii it is usually two-layered, with a tendency to further stratification.The corpus is divisible into three zones, the corpus initial zone, the flanking zone and the rib meristem zone. The corpus initial zone is the seat of formation of the rest two. The flanking zone is concerned with the production of leaf primordia, in which the covering tunica layer has no part.The rib meristem zone varies in depth according to the season of the year and the pith cells mature gradually in these species.InA. columnaris, where a seasonal study was undertaken, no period of complete dormancy was observed.     

The anatomy of the shoot apex ofHyoscyamus niger L. reversed from the generative to the vegetative state

A study was made of the anatomical structure of the shoot apices ofHyoscyamus niger L. in plants which were transferred from a long-day to a short-day regime after the initiation of the inflorescence. After a certain time these plants are reverted to the vegetative stage with the inhibition of the development of further flower buds and the renewed production of rosette leaves. The inflorescence apex consisted of a few superficial layers of cells and a corpus composed of slightly elongated cells. The anatomical structure of the apices which were reverted into the vegetative state resembled that of shoot apices in the intermediate stage. The apex had several layers of small cells, under which there was a group of small but irregularly arranged cells which passed into the rib meristem. The shoot apices of plants transferred from a long to a short-day regime at different time intervals after fulfilling the requirements of minimal photoperiodic induction thus, on the short day, display morphological and anatomical characteristics of various degrees of transition from generative to vegetative stage.     

AN INVESTIGATION OF THE MORPHOGENETIC MECHANISMS WHICH CONTROL THE DEVELOPMENT OF ZONATION IN SEEDLING SHOOT APICAL MERISTEMS

The development of zonation in the shoot apical meristems of 28 species of cacti was examined. At germination the embryonic apex may have one of three types of organization: 1) tunica/corpus; 2) tunica/central mother cells/corpus; 3) tunica/central mother cells/peripheral zone/pith-rib meristem. Apices of the third type have complete zonation and undergo little or no further structural development. Both of the other types develop the missing zones. First, the apices become mitotically active, and peripheral zone characters develop in the outer corpus. Simultaneously, or slightly later, the central mother cells differentiate if they are not yet present. The final step is the formation of the pith-rib meristem. The sequence of appearance of the zones was constant throughout all species examined, but the time of appearance of only one zone could be correlated with any other morphogenetic process: the development of peripheral zone characteristics in the outer corpus occurs with or before the beginning of leaf production. The development of zonation appears to be independent of apical size, shape, or age, either real age or plastochron age. This has been interpreted to indicate that the metabolic mechanism controlling the development of zonation in shoot apical meristems is largely autonomous and independent of other aspects of morphogenesis occurring in the seedling. Also, the fact that leaf initiation and shoot axis production can both occur before the development of either the central mother cells or the pith-rib meristem indicates that neither of these zones is essential for these two apical morphogenetic activities.     

Ulfrastructure of the histological zones in growing vegetative buds of Salix spp.

Ultrastructural differentiation in the shoot apex of growing vegetative buds of Salix was studied, and some micrographs analysed morphometrically. The distribution of inorganic phospahte (P;) was analysed cytochemically. A distinct histological zona–tion was observed in the apex. The relative volumes of nuclei and plastids were significantly higher in the central tunica zone than in the peripheral one. The corpus differed from the central tunica zone by significantly lower volume density of nuclei and higher of vacuoles and mitochondria. During differentiation of the rib meristem vacuole volume increased significantly, while the relative volumes of nuclei, mitochondria, nucleoli, and heterochromatin decreased. It was not possible to decide whether the vacuoles originate from ER or GERL. Morphogenesis of chloroplasts with large starch grains and grana from proplastids was evident in the rib meristem; dedifferentiation to S–plastids was found in the protophloem. Prolamellar bodies were observed in the procambium plastids. The protophloem was characterized by P–protein and spiny vesicles. P_i was found in the nucleoli of most epidermis cells, several procambium cells, and a few chlorencyma cells, but never in the tunica of the growing apical and developing lateral buds. P_i also occurred in some plasmalemma–somes and occasionally in the walls in connection with plasmodesmata.     

The Structure of the Plumule of Nelumbo Nucifera Gaertn. and the Nature of its Scale

The structure of the plumule of Nelumbo nucifera Gaertn. and its feature covered with scale are seldom seen in dicotyledon. The fact that the plumule possesses scale is even more uncommon. This particular phenomenon is investigated by observing the differentiation of the plumule apex and the development of the leaf organs. After the seed is formed, the embryo has two young leaves and a terminal bud covered with scale. In the bud it has already differentiated the 3rd and the 4th leaf primordium and a shoot apex, the differentiation of which is very complex. So the structure of the plumule passes through 4 plastochrons altogether. It is made clear through observation and analysis that, before the 4th leaf primordium is formed, the transforma- tions of the shoot apex of the embryo in each plastochron are fundamentally alike. After the 4th leaf primordium is developed, the shoot apex becomes complex and there appear 3 different active cell regions which become the bases of vegetative bud of the seeding apex. The development of these 3 active cell regions will be stated in “The Structure of the Vegetative Bud of Nelumbo nucifera Gaertn. and the Nature of its Scales.” The apices of the plumule are almost slightly domed in structure. As a rule, their width is from 95 to 107 μ. Their height is from 17 to 20 μ during one plastochron. Before the 3rd leaf initiation, the anatomical structure of apices is examined and the fol- lowing zones may be delimited: zone of tunica initials, zone of corpus initials, peripheral zone, and zone of rib meristems. It is frequently observed that the cell of corpus in subapical peripheral zone develops periclinal division, which is the initial cell of leaf primordium; Procambium will appear before the stage of the appearance of leaf buttress. The apex of the plumule is in an apical position, but when the seedling is formed, as the developing leaves are alternate, the directions of the shoot apex are changed, simultaneously the base part of the leaf encloses the axis, and the adaxial meristem also differentiates the scale which encloses the terminal bud, thus placing the bud in axillary of the leaf and forming a zigzag phenomenon of the axis of the seedling. Above the basal adaxial side of the leaf primordium develops the scale of the plumule with meristem periclinal division of closely attached protoderm as its base. So the scale of the plumule of Nelumbo nucifera Gaertn. and the axillary stipule are of the same origin. To sum up, the scale of the embryo of Nelumbo nucifera Gaertn. is differentiated from the adaxial meristem of the basal part of the leaf primordium, and is the derivative part of the leaf. It has the same function as the coleoptile of the monocotyledon. Whether they are homologous organs or not is still to be investigated.     

THE GROWTH OF THE STEM TIP OF KALANCHOËU CV. ‘BRILLIANT STAR’

Stein , Diana B. and o . L. Stein . (Montana State U., Missoula.) The growth of the stem tip of Kalanchoë cv. ‘Brilliant Star.‘ Amer. Jour. Bot. 47 (2) : 132—140. Illus. I960.–The purposes of this investigation were (1) to define as clearly as possible the events in the shoot apex and its immediate derivatives during the ontogeny of the shoot; and (2) to determine the changes which occur during the transition from a vegetative to a reproductive meristem. Rate of leaf production in Kalanchoë is basically constant. The rate of leaf growth subsequent to the early primordial state is, however, dependent on the age of the plant and on the environment in which the plant is grown. By keeping these factors constant a correlation can be demonstrated between the size of the youngest visible leaf and the microscopic primordia. Throughout its ontogeny the general architecture of the shoot apex remains essentially the same. Two tunica layers cover the corpus in the vegetative shoot apex, and even in the flowering meristem these 2 layers can be detected. The apex is essentially flat and blends into the adjacent leaf primordia early in the plastochron. About 10 days after flower induction has been started the apex changes its form to a dome, primarily by increased cell division. At the same time the rate of elongation of the youngest internodes increases thus placing the flowering stem tip atop an elongated stem. Axillary development is ultimately responsible for the development of a dichasium.     

Some Aspects of Floral Histogenesis in Bajra (Pennisetum typhoides S. & H.)

The young reproductive apex in Bajra (Pennisetum typhoides S.& H.) possesses a biseriate tunica and a massive corpus.The cells of three or four peripheral layers and six to eightlayers at the summit of the apex are eumeristematic. The centralregion consists of elongated, highly vacuolated, and lightlystained cells arranged in files. The initiation of the spikeletbud is by periclinal divisions first in the corpus and laterin T₂ cells. Similarly the longer bristle or the extension ofthe fascicular axis develops from the corpus and T₂ cells. Theother bristles develop from the tunica layers. The chaff membersare initiated and develop like a leaf. The development of thestamen resembles that of a spikelet or an axillary bud. Thedevelopment of the carpel is similar to that of the leaf primordium.The origin and development of the male flower is like that ofan axillary bud.