THE ONTOGENY OF THE PRIMARY THICKENING MERISTEM OF ATRIPLEX HORTENSIS L. (CHENOPODIACEAE)

Seedlings of Atriplex hortensis were studied to ascertain; 1) in which organ the primary thickening meristem (PTM) first differentiates; 2) the direction of differentiation of the PTM, and 3) the pattern of differentiation of conjunctive tissue. The PTM initially differentiates in pericycle of the primary root base 11 days after emergence of the primary root. It then differentiates in the transition region of the hypocotyl, mostly in cells of pericycle between pairs of vascular bundles. In the upper hypocotyl, PTM differentiates by day 20 in the inner layer of cortical parenchyma. In the epicotyl, PTM apparently differentiates in the inner layer of cortex, by day 24. Desmogic xylem differentiates from radial files of internal conjunctive tissue cells and desmogic phloem differentiates opposite desmogic xylem strands from newly formed cells of external conjunctive tissue. No interfascicular cambium differentiates in the root, hypocotyl, or epicotyl.     

THE SHOOT APEX OF BOUGAINVILLEA SPECTABILIS

The shoot apex of Bougainvillea spectabilis consists of five zones: A two- or occasionally three-layered tunica, a central mother cell zone, a cambium-like zone, a rib meristem (central meristem), and a peripheral meristem. The presence of a cambium-like zone is somewhat unusual in the apex of vascular plants, having only been reported for a few taxa. In B. spectabilis the cambium-like zone is consistently present throughout the plastochron and all yearly seasonal periods.     

THE PRIMARY THICKENING MERISTEM: DEFINITION AND FUNCTION IN MONOCOTYLEDONS

The PTM should be defined as a diffuse primary meristem which decreases in cross-sectional extent (i.e., becomes a thinner-walled cylinder) in a basipetal direction. It is associated with extensive anticlinal cell files and consists of cell initials that divide predominantly in periclinal planes. This meristem occurs typically in monocotyledons, especially those with thick, compact stems in species with rosette shoot axes. The PTM is also associated with a wide crown, so that the apical meristem is either slightly above the level of youngest leaf primordia, at approximately the same level as the leaf primordia, or distinctly sunken below surrounding stem tissue and the youngest leaf primordia. The location is dependent on the extent of primary thickening growth occurring in a particular species. A meristem associated with primary thickening of other plant groups should not be called a primary thickening meristem unless all of the above characteristics are shown to be associated with the meristem being examined. The primary thickening meristem is responsible for primary thickening of a stem axis. Its ontogenetic relationship with the STM needs further investigation. Extensive primary stem thickening has been observed in non-monocotyledons (ferns, lycopods, cycads, and dictyledons). Some of these organisms appear to undergo primary thickening from a PTM in a similar process as that which occurs in monocotyledons. Further research is necessary to establish the mechanisms of primary thickening in these cases.     

LOCALIZATION OF CELL DIVISION ACTIVITY IN THE PRIMARY THICKENING MERISTEM IN ALLIUM CEPA L

Stems 1, 2, 3 months old of Allium cepa L. were labelled with tritiated thymidine, fixed in FAA, sectioned, stained with the Feulgen reaction, and prepared for autoradiography. The serial transverse sections were outlined with a camera lucida, recording labelled nuclei as dots. These drawings were used for 3-dimensional reconstructions of the locations of labelled nuclei. Near the top of the stem, labelled nuclei occur in a broad band, whereas they occur in narrower bands at successively lower levels in the stem, and finally labelled nuclei disappear. The locations of the labelled nuclei correspond to the location of the primary thickening meristem (PTM) in the stem of onion as determined by previous histological and histochemical observations. Microspectrophotometry was used to measure the relative amounts of DNA in Feulgen-stained nuclei of the PTM in serial transverse sections of 1- and 2-month-old onion stems. A bimodal distribution was obtained which can be explained by changes in DNA levels during the cell cycle. No evidence of polyploid nuclei was observed. One can conclude, therefore, that the PTM is the site of cell division activity during the primary stem thickening process in onion.     

HISTOCHEMISTRY OF THE PRIMARY THICKENING MERISTEM IN THE VEGETATIVE STEM OF ALLIUM CEPA L.

Stems of Allium cepa L., 1, 2, 5, and 6 months old respond similarly when stained for protein and RNA. The primary thickening meristem (PTM) stains more intensely than surrounding stem tissues. The acropetal region of the PTM is a broadly staining band which narrows basipetally to the level of the initiation of shoot-borne roots in the stem and disappears more basipetally. These staining patterns are consistent with the hypothesis that the PTM functions in stem thickening and root production, and also indicate that the meristem functions before histological evidence of the cambial-like zone exists in the onion stem. Histochemical staining may be an accurate method of locating the PTM.     

ONTOGENY AND CORRELATIVE RELATIONSHIPS OF THE PRIMARY THICKENING MERISTEM IN FOUR-O'CLOCK PLANTS (NYCTAGINACEAE) MAINTAINED UNDER LONG AND SHORT PHOTOPERIODS

The developmental anatomy of Mirabilis jalapa was investigated during the first 90 days of growth. The primary thickening meristem (PTM) initially differentiates in the pericycle at the top of the cotyledonary node 18 days after germination, then basipetally in the pericycle through the hypocotyl. The PTM differentiates acropetally into the stem and in the pericycle of the primaiy root, commencing 22 days after germination. Endodermis is easily identifiable in hypocotyls as well as in primary roots because of Casparian thickenings in its cells. It has not been definitely identified in stems. There are three rings of primary vascular bundles in the stem. The PTM differentiates as segments of cambium in a layer of cells (probably in the pericycle) on an arc between vascular bundles of the outer bundle ring. Later, arcs of PTM differentiate externally to the phloem of each bundle. Each arc forms a connection between original segments of PTM lying on either side of each vascular bundle. Thus, the PTM becomes a continuous cylinder. The PTM differentiates in the pericycle outside vascular tissue in the hypocotyl and root. Differentiation of the PTM and the mode of secondary thickening is similar in plants exposed to short (8-hr) and to long (18-hr) photoperiods, but some differences were observed. The PTM differentiates closer to the stem apex in all plants over 18 clays of age growing vegetatively under long photoperiods. That is, the diffuse lateral meristem, in whose cells the PTM differentiates in young intemodes, is shorter in nearly all investigated plants growing in long photoperiods. The hypocotyl and base of the primary root of 40-day-old plants in short photoperiods were more enlarged than those of the same age plants in long photoperiods; but, at the end of 64 days, the hypocotyl and primaiy root base were larger in plants growing under short photoperiods. Thirty-four days after seed germination, flower initiation occurs in plants exposed to short photoperiods. One hundred fifty days after seed germination, flowers differentiate on plants exposed to long photoperiods.     

THE RELATIONSHIP BETWEEN THE PRIMARY THICKENING MERISTEM AND THE SECONDARY THICKENING MERISTEM IN YUCCA WHIPPLEI TORR. I. HISTOLOGY OF THE MATURE VEGETATIVE STEM

Anatomical observations were made on 1-, 2-, and 3-yr-old plants of Yucca whipplei Torr, ssp. percursa Haines grown from seed collected from a single parent in Refugio Canyon, Santa Barbara, California. The primary body of the vegetative stem consists of cortex and central cylinder with a central pith. Parenchyma cells in the ground tissue are arranged in anticlinal cell files continuous from beneath the leaf bases, through the cortex and central cylinder to the pith. Individual vascular bundles in the primary body have a collateral arrangement of xylem and phloem. The parenchyma cells of the ground tissue of the secondary body are also arranged in files continuous with those of the primary parenchyma. Secondary vascular bundles have an amphivasal arrangement and an undulating path with frequent anastomoses. Primary and secondary vascular bundles are longitudinally continuous. The primary thickening meristem (PTM) is longitudinally continuous with the secondary thickening meristem (STM). Axillary buds initiated during primary growth were observed in the leaf axils. The STM becomes more active prior to and during root initiation. Layers of secondary vascular bundles are associated with root formation.     

THE RELATIONSHIP BETWEEN THE PRIMARY THICKENING MERISTEM AND THE SECONDARY THICKENING MERISTEM IN YUCCA WHIPPLEI TORR. III. OBSERVATIONS FROM HISTOCHEMISTRY AND AUTORADIOGRAPHY

Observations were made of stem sections stained for RNA and protein of Yucca whipplei ranging from germinated seedlings to 6-month-old plants. One-, two-, and three-month-old plants were labeled with tritiated thymidine, fixed in FAA, sectioned, stained with the Feulgen reaction, and prepared for autoradiography. The serial transverse sections were outlined with a drawing tube recording all labeled nuclei on a computer graphics tablet. Computer-assisted three-dimensional reconstructions were made to observe the locations of labeled nuclei. The two techniques are in agreement: the thickening meristem is broad near the top of the stem, occupies a narrower band at more basipetal levels, and disappears below the level of recent root initiation. There are no gaps in staining or labeling, and there are no changes in staining or labeling that would distinguish between the activities of the primary thickening meristem and the secondary thickening meristem in those plants which possess both. The meristems are continuous at all stages of development in the young vegetative stem. The STM is interpreted to be a developmental continuation of the PTM.     

ON THE CORRELATION OF PRIMARY ROOT LENGTH,MERISTEM SIZE AND PROTOXYLEM TRACHEARY ELEMENT POSITION IN PEA SEEDLINGS

Pea seedlings (Pisum sativum L. cv. Alaska) were darkgrown in vermiculite. Roots of various lengths were cleared, stained and measured to determine the relative meristem height (MH), width and volume and the distance to the most proximal protoxylem tracheary element (PTE). A correlation was found between root length, MH and PTE position as follows: in roots from 4–40 mm as the root elongated the MH lengthened and PTE position increased its distance from the body/cap juncture; in roots 40–80 mm MH and PTE position remained approximately constant; in longer roots (80–120 mm) MH became shorter, and PTE position closer to the tip as the root elongated. The relationship, using our measurement procedure was that for every 0.19 mm change in MH, the PTE position changed by 1 mm. This response was partially growth rate dependent since short roots (4–80 mm) grew at a constant rate and longer roots (80–140 mm) grew slower. Root manipulations and trifluralin treatment, to inhibit cell division, caused tip swelling and modulated the position of the PTE toward the root tip. The control of the spatial relationship between meristem size and maturation position is discussed.     

ONTOGENY OF THE SHOOT APEX OF SEEDLINGS OF PINUS PONDEROSA

Dormant seeds of ponderosa pine (Pinus ponderosa) were stratified and then planted in the greenhouse. Changes occurring in the shoot apex during germination and growth of the seedlings were observed and are described. Cell divisions in germinating embryos are first noted on the flanks of the apex near the cotyledons. From these loci, mitotic reactivation proceeds up the flanks of the apex and inward toward cells of the rib meristem. Cells are dividing actively in all regions of the shoot apex of seedlings 12 days after planting, but no cytohistological zonation is evident due to differences in staining intensity and in cell and nuclear size. In 64-day-old seedlings the mitotic rate is reduced and the characteristic zonation of pine apices begins to appear. Zonation is even more evident in older seedlings. These observations are discussed in relation to the concept of initials and to theories concerning factors which regulate growth in the shoot apex.     

ACTION OF GIBBERELLIC ACID ON CELL PROLIFERATION IN THE SUBAPICAL SHOOT MERISTEM OF WATERMELON SEEDLINGS

Rates of cell proliferation were about 2.5 fold greater in gibberellic acid-treated seedlings of dwarf watermelon than in untreated dwarf seedlings as determined by direct counts of pith cells in elongating hypocotyls of watermelon. The higher rates of cell proliferation observed in normal and GA-treated dwarf seedlings were due both to shorter cell cycle times and increased growth fractions of cells than in dwarf seedlings. The shorter duration of the cell cycle in GA-treated seedlings was primarily due to a reduced S period.     

EXINE PATTERN FORMATION BY PLASMA MEMBRANE IN BOUGAINVILLEA SPECTABILIS WILLD. (NYCTAGINACEAE)

Transmission and scanning electron microscopy of exine development in Bougainvillea spectabilis (Nyctaginaceae) confirmed that the exine pattern is initiated by invagination of the microspore plasma membrane at the early tetrad stage. Invaginated plasma membranes take the form of a reticulate pattern that corresponds to the mature exine tectum. Protectum is the first exine layer to be deposited on the reticulate-patterned plasma membrane. Subsequently, probacules elongate basally on protruding sites of the plasma membrane under the protectum and in the lumina. These sites retreat as the probacules elongate. After the dissolution of the callose wall, a foot layer forms through the accumulation of lamellated structures. Clearly, the plasma membrane serves a determinative role in the initial pattern formation of exine.     

玉米幼苗冷袭敏感性的初步研究

对玉米种子萌发过程中低温冷袭(3.0℃)下幼苗电导率、硝酸还原酶活性、可溶性蛋白质含量、可溶性糖、蔗糖含量、植株浸出液中K⁺、Mg²⁺和Ca²⁺含量以及株高、干重、鲜重和残留种子干物质重量的研究结果表明,冷袭处理植株较对照植株的高度、干重和鲜重的生长率均随叶龄和天龄的增加而降低,可溶性蛋白质含量、可溶性糖含量均随叶龄和天龄的增加而呈下降趋势;而相对电导率和植株浸出液中的K⁺、Mg²⁺和Ca²⁺含量则呈上升趋势,从而说明玉米幼苗从异养向自养转变的过程中,抵御冷袭的能力是逐渐降低的,也就是说对冷袭的敏感性是逐渐增大的。从冷袭处理植株与对照植株之间各项指标的差值来看,均在15天龄或17天龄最大,说明此时期既离乳期,玉米幼苗对冷袭的敏感性最大。     

ONTOGENETIC REORGANIZATION OF THE ROOT MERISTEM IN THE COMPOSITAE

The organization of the root meristem in selected Compositae was investigated to determine whether changes in the pattern of cell arrangement occurred during root growth in species other than Helianthus annuus. Embryonic, short, and long primary roots of one species of each of twelve genera were prepared for microscopic examination. Additional intermediate growth stages were prepared for Echinacea pallida. The meristem of embryonic roots showed layers of initials typical for dicotyledons. The meristem in many of the short roots of eight species was reorganized by the development of a secondary columella. The long roots showed patterns similar to the embryonic roots. In three species which maintained closed meristems, two layers of cortical initials were common in the embryonic root, and as a general trend, a single layer of cortical initials became more common during root elongation. The cellular changes that resulted in the initiation of a secondary columella are characterized by the conversion of cortical initials to secondary columella initials by a shift in their plane of cell division. It is proposed that the size and shape of the quiescent center changes as the conversion takes place. No intermediate stages were observed which could account for the reduction of two layers of cortical initials to one layer.     

肾叶唐松草幼苗初生维管系统的个体发育研究

肾叶唐松草(Thalictrum petaloideum L.)幼苗初生维管系统的个体发育研究证明,正如谷安根等在"Studies on Cotyledon Node Zone"的研究中所发现的那样,它也存在一个子叶节区和以该区为中心的两个过渡区,即子叶节区向下的子叶节-根过渡区(下胚轴)与子叶节-茎过渡区(即子叶节区的中部和上部)。在它的子叶节区下部存在中始式二原型具双钩状后生木质部的单中柱。