Structural and histochemical characterization of the cotyledon storage organelles of jojoba (Simmondsia chinensis)

Summary Jojoba cotyledon cells are isodiametric and 44 m in diameter. They contain two prominent storage organelles—wax bodies and protein bodies. Isolated and intact wax bodies react positively with several lipid histochemical stains; they are spherical and 1.5 m in diameter. Protein bodies are irregular in shape, but usually appear spherical. They range in diameter from 7–15 m, are unit membrane bound, have an irregular grainy matrix and do not contain a globoid inclusion. Protein bodies stain positively for both protein and lipid. The possible composition and role of this protein/lipid body complex is discussed.     

Cell division patterns of the protoderm and root cap in the “closed” root apical meristem ofArabidopsis thaliana

Summary The peripheral root cap and protoderm inArabidopsis thaliana are organized into modular packets of cells derived from formative T-divisions of the root cap/protoderm (RCP) initials and subsequent proliferative divisions of their daughter cells. Each module consists of protoderm and peripheral root cap packets derived from the same periclinal T-division event of an RCP initial. Anatomical analyses are used to interpret the history of extensively coordinated cell divisions producing this modular construction. Within a given layer of root cap, the columella and RCP initials divided in a centrifugal sequence from the innermost columella initials toward the RCP initials. All RCP initials in the lineages around the circumference of the root divided nearly simultaneously in waves to form one module prior to the next wave of initial divisions forming a younger module. The peripheral root cap and protoderm packets within each module completed four rounds of proliferative divisions in the axial plane to produce, on average, 16 cells per packet in the basalmost modules in axial view. Peripheral root cap and protoderm cells predominantly in the T-type (trichoblast) lineages also underwent radial divisions as they were displaced basipetally. The regularity in the cellular pattern within the modules suggests a timing mechanism controlling highly coordinated cell division in the initials and their daughter cells.Abbreviations RAM root apical meristem - RCP root cap protoderm - prc peripheral root cap     

Modular construction of the protoderm and peripheral root cap in the “open” root apical meristem ofTrifolium repens cv. Ladino

Summary Roots with open apical organization are defined by not having specific tiers of initial cells in the root apical meristem; those with closed apical organization have specific initial tiers to which all cell files can be traced. An example of the clear organization of closed roots is the development protocol of the root cap and protoderm. The key event in differentiating these tissues is the T-division, a periclinal division of the root cap/protoderm (RCP) initial that establishes a module. Each module comprises two packets, the protoderm and peripheral root cap. Consecutive T-divisions of the same RCP initial produce up to five modules on average in a lineage of cells in white clover (Trifolium repens cv. Ladino), with all lineages around the circumference of the root dividing in waves to form one module prior to the next. On average, clover has approximately 32 axial protoderm and peripheral root cap cells in each module, and 32 RCP lineages. The occurrence of RCP T-divisions in white clover, a root with open apical organization, and the subsequent modular construction of the root cap and protoderm, provides a link between open and closed roots and suggests a common developmental feature that most roots of seed plants may share independent of their root meristem organization type. The open apical organization of the white clover root varies from roots with closed apical organization in that the RCP initials occur in staggered positions instead of connected to discrete tiers, and the peripheral root cap and columella daughter cells form additional layers of cells. White clover also forms root hairs on all protoderm cells irrespective of their position relative to the underlying cortical cells.Abbreviations RAM root apical meristem - RCP root cap protoderm - prc peripheral root cap     

Structure of Protein Bodies and Elemental Composition of Phytin from Dry Germ of Maize (Zea mays L.)

Protein bodies (PBs) from the epidermis and cortex of the radicle, as well as from coleorhizal and scutellar parenchyma of dry maize seeds were studied with the emphasis on presence and elemental composition of globoid crystals. PBs with variable structure were found in investigated tissues. Radicular epidermis was the only investigated tissue containing structurally uniform populations of PBs. They were filled by a homogeneous matrix without globoid crystals or their remnants. PBs structure and amount of proteinaceous matrix varied in the same cell of coleorhiza and scutellum. In the case of radicular cortex, the structure of PBs differed between analyzed individuals. Globoid crystals of various sizes were found in PBs from scutellum, coleorhiza, and from inner layers of radicular cortex. The largest globoid crystals (up to 2.0 μ in diameter) were seen in the scutellum. Energy-dispersive X-ray microanalysis revealed the presence of P,K. Mg, and some traces of Fe and Zn in the majority of globoid crystals from the scutellum. Globoid crystals from coleorhiza and radicular cortex were rich in Zn and Ca. The presence of considerable Zn was usually accompanied by high Ca, at the expense of K and Mg. As EDX analyses revealed significant differences in Zn and Zn/P values between analyzed tissues, it is probable that the majority of Zn is preferably accumulated in globoid crystals of some tissues of maize germ.     

X-ray Analysis Studies of Elements Stored in Protein Body Globoid Crystals of Triticum Grains

Energy-dispersive x-ray analysis was used to investigate the elemental storage within protein bodies, specifically the globoid crystals, in grains of wheat. Areas of the grain investigated included various parts of the embryo, the aleurone layer plus starchy endosperm near the embryo and the aleurone layer plus starchy endosperm farthest from the embryo. Variations did occur grain-to-grain, cell-to-cell and, in certain regions, intracellularly. No protein bodies with electron-dense globoid crystals were found in the starchy endosperm. Generally globoid crystals contained P, K, and Mg in all areas investigated. Globoid crystals from the aleurone layer farthest from the embryo on occasion contained Ca, whereas aleurone globoid crystals near the embryo sometimes contained Fe. In most of the embryo regions examined, a few globoid crystals contained Ca along with P, K, and Mg. No specific pattern to the Ca distribution could be found. Welldefined elemental distribution occurred with Mn. Manganese was found only in globoid crystals located in the base and midregions of the stele in the radicle. Thus, in wheat there is some specific distribution of minerals dependent upon cell type and/or position in the grain.     

Trois nouveaux Nadejdolepis Spasskii & Sasskaya, 1954 (Cestoda: Hymenolepididae) parasites de Charadrii (Aves) de Tasmanie

Three species of Nadejdolepis from Tasmania, Australia, are described and illustrated. N. burgessi n. sp., a parasite of Charadrius ruficapillus, is 4-6 mm long, with rostellar nitiduloid hooks 63-66 m long, a short evaginated cirrus 13-16 m long with a short collar of thin spines 1 m long, a narrow and tubular sclerotinoid vagina 40-50 long and 3-4 m in diameter with a little ampulla 3-5 m in diameter at the proximal end, and a membranous atrial segment with smooth, short (1 m) and compact spines which are sometimes difficult to observe. N. smithi n. sp., a parasite of 40-50 long and 3-4 m in diameter with a little ampulla 3-5 m in diameter at the proximal end, and a membranous atrial segment with smooth, short (1 m) and compact spines which are     

Mineral reserves in castor beans: the dry seed

Elemental composition and distribution of the mineral reserves in the endosperm and embryo tissues of Ricinus communis cultivars Hale and Zanzibarensis were investigated. Energy dispersive x-ray analysis was used to determine the elemental composition of the globoid crystals, while atomic absorption spectrometry allowed quantification of the elements, particularly Ca, in various seed regions. No major differences were found between the two cultivars with regard to the elemental distribution in globoid crystals. While the majority of globoid crystals contained P, K, and Mg, the occasional one also contained Ca. In extremely rare instances, Fe was detected in globoid crystals. Ca-containing globoid crystals were more common in provascular cell protein bodies in the stem and radicle. Polarized light microscopy, micro-incineration, and acid solubility tests demonstrated the presence of calcium oxalate crystals in the innermost testa which adheres to the endosperm and is often mistakenly identified as endosperm. Atomic absorption spectrometry revealed that most of the calcium present in castor bean seeds is localized in the testa. On a perseed-region basis, the much larger endosperm contains more Ca than does the embryo. However, on a unit-weight basis, the radicle-plus-stem regions contain considerably more Ca than does the cotyledon or endosperm, an observation that is consistent with the observed distribution pattern for Ca-containing globoid crystals.     

Energy-dispersive x-Ray Analysis of Phosphorus, Potassium, Magnesium, and Calcium in Globoid Crystals in Protein Bodies from Different Regions of Cucurbita maxima Embryos

The seeds of Cucurbita maxima contain protein bodies with electrondense globoid crystals. Because of their density globoid crystals are ideal material for energy-dispersive x-ray (EDX) analysis studies of elemental composition. Fixation trials were carried out to test globoid crystal extraction during glutaraldehyde fixation, water washing, and ethanol dehydration. Glutaraldehyde fixation without subsequent washing or dehydration alone produced no significant changes in elemental composition of cotyledon globoid crystals. If glutaraldehyde fixation was followed by water washes or ethanol dehydration there was some loss of the major globoid crystal elements but the relative percentages of the elements P, K, Ca, and Mg remained relatively unchanged. In this paper results of a study of the P, K, Mg, and Ca content of globoid crystals in different tissues of squash embryos are presented. The globoid crystals in the radicle were found to be the least dense in the embryo. Globoid crystals from all embryo regions contained P, K, and Mg. In the various embryo regions P and Mg maintained relatively constant proportions of the globoid crystal composition while K and Ca varied. Of particular significance is the distribution of Ca which is generally an immobile element. Calcium was found in highest amounts in the globoid crystals of the radicle and stem regions while globoid crystals in much of the cotyledon contained little, if any, Ca. The Ca storage thus seems to be spatially arranged in a manner that would aid early growth of the root-shoot axis.     

Root apical organization inArabidopsis thaliana 1. Root cap and protoderm

Summary We investigated the development of the root cap and protoderm inArabidopsis thaliana root tips.A. Thaliana roots have closed apical organization with the peripheral root cap, columella root cap and protoderm developing from the dermatogen/calyptrogen histogen. The columella root cap arises from columella initials. The initials for the peripheral root cap and protoderm are arranged in a collar and the initiation event for these cells occurs in a sequential pattern that is coordinated with the columella initials. The resulting root cap appears as a series of interconnected spiraling cones. The protoderm, in three-dimensions, is a cylinder composed of cell files made up of packets of cells. The number of cell files within the protoderm cylinder increases as the root ages from one to two weeks. The coordinated division sequence of the dermatogen/calyptrogen and the increase in the number of protoderm cell files are both features of post-embryonic development within the primary root meristem.Abbreviations RCP root cap/protoderm - CI columella initial - PI protoderm initial     

Replicon size and mean rate of DNA synthesis in rye (Secale cereale L. cv. Petkus Spring)

Chromosomal DNA replication was investigated in root meristem cells of Secale cereale L. cv. Petkus Spring using DNA fibre auto-radiography. At 23 ° the mean rate of replication, per single replicon fork, was 12.1 m/h. Replicon size was between 20–25 m. These results are compared with corresponding measurements for other angiosperm species.     

Indole butyric acid induces regeneration of phenotypically normal apricot (Prunus armeniaca L.) plants from immature embryos

A prerequisite for most transformation systems is an efficient and reliable method to regenerate phenotypically normal plants. Immature embryos or cotyledons were cultured at three developmental stages (stage 1, 2 and 3, PF=3, 30–60, and 100, respectively) from two unrelated apricot genotypes, Zard and NJA82. Explants were cultured on MS media supplemented with either BA or TDZ at four concentrations (0, 0.5, 5.0 or 20 M) and 2,4-D at 0 or 1 M. Stage 1 embryos cultured on MS medium without growth regulators formed embryoid-like structures. Shoot primordia induction was greatest with stage 2 cotyledons on media containing 5–20 M TDZ and 1 M 2,4-D, although shoot morphology was abnormal, especially with the highest level of TDZ. In another factorial experiment, stage 2 cotyledons were cultured on media containing TDZ (0, 5, 7.5, 10, 15 or 20 M) in combination with either no auxin, 1 M 2,4-D, 1 M IBA, or 5 MIBA. Regeneration percentages of 80% or more were observed on media containing 1–5 M IBA and 5–10 M TDZ. The medium containing 5 M IBA and no TDZ exhibited the highest frequency of phenotypically normal plantlet regeneration.Abbreviations BA 6-benzylaminopurine - IBA indole-3-butyric acid - 2,4-D 2,4 dichlorophenoxyacetic acid - 2iP 2-isopentenyladenine - MS Murashige and Skoog basal medium - NAA 1-naphthaleneacetic acid - PF percent fill [(embryo length/seed length) × 100] - TDZ thidiazuron [N-phenyl-N(1,2,3,-thidiazol-5-yl)-urea] - WPM McCown's woody plant medium     

Protein bodies in ray cells of Populus x canadensis Moench ‘robusta’

Light- and electron-microscopical investigations revealed distinct intravacuolar protein aggregates of 0.3–0.8 m in diameter in ray cells of poplar during the dormant season. In semi-thin sections, these bodies showed positive protein staining and enzymatic digestibility with pepsin, indicating their proteinaceous nature. Morphometric measurements showed such protein bodies in 7–13% of the area of the ray-cell lumen. This amount corresponded with the protein content of the wood determined biochemically, e.g. 2.0–5.0 g·mg^-1 dry weight. Polyacrylamide gel electrophoresis of the total protein fraction extracted from wood showed prominent polypeptide species with an apparent molecular weight of 30–32 kilodaltons. The results indicate considerable protein storage in ray cells, especially in the form of protein-storage vacuoles.Abbreviation DW dry weight     

Protein bodies in seeds

Membrane bound protein bodies (aleurone grains) are thought to be the main subcellular location of protein and mineral storage in seeds. In addition to structurally homogeneous proteinaceous matrix, protein bodies may contain protein crystalloids, electron–dense globoid crystals, electron–transparent soft globoids, and crystals of calcium oxalate. Protein crystalloids vary in shape, size and number. For example, cotyledon mesophyll cell protein bodies in the Cucurbitaceae generally contain protein crystalloids whereas those of Compositae and Cruciferae do not. Globoid crystals, which are rich in phytin, vary greatly in size and number per protein body. Some species have numerous small globoid crystals per protein body whereas others have one or two large globoid crystals per protein body. Phosphorus and various cations (K, Mg, Ca, Fe, Ba, Mn) located in globoid crystals can be studied with an energy dispersive X–ray (EDX) analysis system mounted on a transmission electron microscope. In some cases, cations such as Ca, Mn and Fe are specifically localized in globoid crystals of certain tissues or embryo regions. Further investigations may allow elemental composition of globoid crystals to be used in studies of systematics. Biref–ringent crystals, sometimes in the form of single large crystals but frequently in the form of druses, are present in protein bodies of some species. At least some endosperm protein bodies of all Umbelliferous species examined contain druse crystals. While seed protein bodies of relatively few species have been studied with electron microscopy, there are indications that protein bodies could be a useful character for studies in plant systematics.     

S-100 protein stimulates cellular proliferation

Summary S-100 protein (S-100p) is a small, acidic, calcium-binding protein that is present (predominantly) in the cytoplasm of many types of cells including those of neuroectodermal origin, such as glial cells, schwann cells and melanocytes. In human melanoma cells S-100p is abundant relative to the small quantities expressed by normal melanocytes. We investigated the possibility that this protein may be a growth factor. Purified S-100p from bovine brain or human melanoma cells was added exogenously to human melanoma cells and peripheral blood lymphocytes (PBL) and their growth in the presence of different concentrations of S-100p was determined using a [³H]dT-uptake proliferation assay. The growth of melanoma cells was stimulated by S-100p at concentrations of 1.95–31.25 g/ml. Slight inhibition of cell proliferation occurred at high concentrations (125 g/ml). Maximum stimulation of PBL was at 31.25 g/ml. PBL were not inhibited even at high concentrations of S-100p (125 g/ml). PBL stimulation by S-100p did not require the presence of monocytes/macrophages. Though stimulation by S-100p is not restricted to a specific cell type, when released by melanoma cells it may function as an autocrine tumor growth factor. Other cells, such as PBL, coming in contact with S-100p are also stimulated to proliferate.     

Amaranthus hypochondriacus: Seed Structure and Localization of Seed Reserves

The mature seed of Amaranthus hypochondriacus L. consists ofa peripheric embryo surrounding the nutritive tissue which isthe perisperm. Endosperm remnants are close to the root tip.Cytochemical analysis revealed that the embryo and endospermcells had a quite homogenous internal organization, with proteinbodies embedded in a lipid matrix. The embryo, however, appearsvariable in tissue organisation, due to the differentiationof the three primary meristematic tissues: the procambium appearsas a single bundle in the embryonic axis or as small bundlesthroughout the cotyledons length, these provascular cells aresmall and elongated and with fewer reserves and more cellularorganelles than the large protoderm and ground meristem cells.These latter cells have more protein bodies, and they show ahigher number of larger globoid crystal inclusions than theothers. The perisperm is a starchy tissue, and its cells havethin walls and are full of angular starch grains.Copyright 1994,1999 Academic Press Amaranth, Amaranthus hypochondriacus, seed structure, seed reserves     

Endo-β-mannanase isoforms are present in the endosperm and embryo of tomato seeds, but are not essentially linked to the completion of germination

A current hypothesis is that endo--mannanase activity in the endosperm cap of tomato (Lycopersicon esculentum Mill. cv. Moneymaker) seeds is induced by gibberellin (GA) and weakens the endosperm cap thus permitting radicle protrusion. We have tested this hypothesis. In isolated parts, the expression of endo--mannanase in the endosperm after germination is induced by GAs, but the expression of endo--mannanase in the endosperm cap prior to radicle protrusion is not induced by GAs. Also, abscisic acid (ABA) is incapable of inhibiting endo--mannanase activity in the endosperm cap, even though it strongly inhibits germination. However, ABA does inhibit enzyme activity in the endosperm and embryo after germination. There are several isoforms in the endosperm cap and embryo prior to radicle protrusion that are tissue-specific. Tissue prints showed that enzyme activity in the embryo spreads from the radicle tip to the cotyledons with time after the start of imbibition. The isoform and developmental patterns of enzyme activity on tissueprints are unaffected when seeds are incubated in ABA, even though germination is inhibited. We conclude that the presence of endo--mannanase activity in the endosperm cap is not in itself sufficient to permit tomato seeds to complete germination.Abbreviations ABA cis/trans-abscisic acid - GA(s) gibberellin(s) - IEF isoelectric focussing - pI(s) isoelectric point(s) We thank Dr. Bruce Downie for the seemingly endless but inspiring discussions.     

The effects of aluminium on nodulation and symbiotic nitrogen fixation in Casuarina cunninghamiana Miq.

In order to investigate the effects of Al on nodule formation and function in the Casuarina-Frankia symbiosis, inoculated plants were grown in sand culture at five nominal Al concentrations (0-880 M Al) at pH 4.0. There was an Al-free control at pH 6.0 to assess the effects of pH 4.0 treatments. Mean N concentration of nodules was significantly less at pH 4.0 (1.83%) than at pH 6.0 (2.01%). There were nodulated plants at all Al levels, though there were fewer nodulated plants at 440 and 880 M Al. Dry weights of nodules, shoots and roots were not reduced by Al concentrations at or below 220 M Al, but were decreased by Al concentrations at or above 440 M Al. Nodule weight expressed as a percentage of total weight did not differ significantly with respect to an Al-free control at pH 4. N concentrations of shoots and whole plants were significantly reduced at 440 M Al. Nodular specific acetylene reduction activity (ARA) did not differ significantly among Al treatments. However, N₂-fixation efficiency was decreased from 0.20 to 0.10 mg N fixed mg nodule dry weight^–1 at 880 M Al.     

ORIGIN AND DEVELOPMENT OF LATERAL ROOTS IN TYPHA GLAUCA

Lateral roots of Typha glauca arose from the pericycle of the parent adventitious root. Periclinal divisions of the pericycle gave rise to two layers; the outermost initially produced the ground meristem and protoderm, and the innermost produced the procambium. The immature endodermis of the parent root contributed to the early stages of the root tip as an endodermal covering. Prior to emergence, the ground meristem/protoderm produced cells into the endodermal covering. After emergence, the endodermal covering was replaced by a calyptrogen, which was derived from the ground meristem/protoderm and which, in turn, formed the rootcap. A typical monocotyledonous three-tiered meristem was then produced. An outer ground meristem also arose before emergence to form a hypodermis in many lateral roots; in these, crystalliferous cell production began in midcortex cells before emergence, and a small aerenchyma developed in their cortices. The rootcap columella stored small amounts of starch shortly after emergence. Lateral roots of T. glauca were smaller than their parental adventitious roots; they normally had only two to six poles of xylem and phloem, and the cortex was less than six cells across. During 1–3-cm elongation, the lateral root apical meristem and mature regions narrowed, stored starch disappeared, fewer crystals formed, aerenchyma production ceased, and the roots stopped elongation.     

Composition of globoid crystals from embryo protein bodies in five species of cucurbita

Previous energy-dispersive x-ray analysis studies of globoid crystal composition in seed protein bodies gave an indication that there might be a correlation between seed size and the type of elements stored in globoid crystals. This possibility was tested by conducting energy-dispersive x-ray analysis studies of P, K, Mg, and Ca levels in globoid crystals of four embryo regions (radicle, stem, cotyledon center palisade mesophyll, cotyledon center spongy mesophyII) in each of five different Cucurbita species (C. mixta, C. moschata, C. foetidissima, C. pepo, and C. andreana). The species were chosen to provide a range of seed size and weight. Globoid crystals from all embryo regions in all five species contained P, K, and Mg. Some variations in the levels of these elements did occur but there was no consistent pattern with regard to area of the seed or with regard to seed size. Calcium distribution showed significant variations. In species with large seeds (C. mixta, C. moschata) Ca was mainly found in globoid crystals in the radicle. Globoid crystals in species with small seeds (C. foetidissima, C. pepo, C. andreana) contained Ca in all embryo regions tested. The results of this study support the concept that Ca distribution in globoid crystals can be correlated with seed weight.     

The nutritional status of the apical meristem of Lactuca sativa as affected by NaCl salinization: An electron-probe microanalytic study

A volume of tissue of lettuce (Lactuca sativa L.) plants extending 2 mm basipetally from the apical meristem and including leaf primordia and young expanding leaves was surveyed using electron-probe microanalysis (EPMA) on both frozen-hydrated and freeze-dried samples. This analysis was carried out either 2 or 5 d following NaCl salinization of the medium from the 10 mol · m^–-3 control level up to 80 mol · m^–-3. The objective was the investigation of possible changes in the nutritional status of the apical meristem that might account for some aspects of salt-induced growth inhibition. Sodium and chloride increased significantly in tissues basal to the apical meristem, while both phosphorus and potassium decreased in the same region. These changes were evident in specimens collected just 2 d after the commencement of salinization (20 h after completion of the salinization) and were not exacerbated by an additional 3 d of treatment; they were present in tissue as close as 100 m to the meristem and extending down to 500 m. The apical 10–50 m were relatively protected from both the increase in sodium and chloride and the decrease in phosphorus and potassium that occurred in more basal regions. Young leaves (up to 1.5 mm in length) appear to control their own mineral nutrient levels when challenged by salinization of the medium, presumably because of altered growth. A decrease in the concentration of total Ca as a result of salinization was significant in cells 500 m basal to the meristem, but was evident as a tendency in the data even within the first 50 m. Using an improved automatic method for the analysis of calcium by EPMA, it was found that total Ca was reduced by salinization, especially in basal regions (500 m below the apex) and also in young leaves (1–1.5 mm in length). We suggest that the nutrition of the shoot apical meristem may be disturbed soon after salinization and that the shoot meristem might be the source of a signal to expanding leaves, as well as exerting its own direct influence over leaf emergence.Abbreviation EPMA electron-probe microanalysis This work was supported by U.S. Department of Agriculture grant 87-CRCR-1-2462.