The Cytological Studies on Albuminous Cells in Secondary Phloem of Pinus bungeana

This paper emphatically deals with the ultrastructure of albuminous cells in different stages of development in the secondary phloem of Pinus bungeana. The secondary phloem of Pinus bungeana is composed of sieve cells, axial parenchyma cells, radial plates and rays. Among the constituents, most of upright ray cells and radial plate parenchyma cells are albuminous cells. Although the shape and distribution of this kind of albuminous cells may be different, they possess the following common cytological characteristics. These cells have dense cytoplasm with abundant mitochondria, ribosomes, rough endoplasmic reticula and a large nucleus, the nuclei of some albuminous cells are lobed in shape which increases the outer surface of the nuclei. Usually the albuminous cell contains some starch granules, the quantity of the starch granules in albuminous cells is less than the other parenchyma cells of the secondary phloem. All these cytological characteristics suggest that albuminous cells are active physiologically. The distinguishing characteristics of albuminous cells from other parenchyma ceils are that the albuminous cells are associated with sieve cells through unilateral sieve area and they died together with the sieve cells.     

PEARL MILLET (PENNISETUM AMERICANUM (L.) LEEKE) AND GRAIN SORGHUM (SORGHUM BICOLOR (L.) MOENCH) ULTRASTRUCTURE

Ultrastructural features of pearl millet (Pennisetum americanum (L.) Leeke) and grain sorghum (Sorghum bicolor (L.) Moench) caryospses were investigated with thin sections of the dry, mature grain in the transmission electron microscope, and fractured kernels in the scanning electron microscope. The pericarp of those grains is comprised of three distinct layers: epicarp, mesocarp of parenchyma cells, and endocarp of compressed cross and tube cells. Mesocarp cells of grain sorghum contain starch granules embedded in a cytoplasmic matrix. The major constituent of sorghum and millet aleurone cells are aleurone grains (protein bodies) and lipid bodies. Subaleurone cells contain a much higher proportion of protein bodies than starch granules, and the protein bodies are structurally distinct from those in the aleurone. The germ scutellar ultrastructures of the two grains were similar; protein bodies, lipid bodies, epidermal cells and parenchyma cells of the germ are described.     

Effects of Light and Dark on the Ultrastructure of Lichen Algae

Quantitative ultrastructural observations have been made onthe algal cells (Trebouxia) in two lichens, Parmelia sulcataand P. laevigata, stored for 48 h in the dark or under a light/darkregime. The response of the alga was found to differ in theselichens. In P. sulcata the dark treatment caused a decreasein starch grains, lipid-rich pyrenoglobuli and peripheral cytoplasmicstorage bodies and an increase in pyrenoid and chloroplast proteinbodies. The algae in P. laevigata contained little starch andno chloroplast protein bodies. However, after dark treatment,starch, cytoplasmic storage bodies and pyrenoid dimensions sometimesdeclined, while pyrenoglobuli numbers increased. Some of theseapparent changes depended upon the units used for calculatingthe cross-sectional areas of structures, e.g. absolute units,percentage of cell wall, protoplast or chloroplast cross-sectionalarea. Chloroplast area increased in the dark (as a % of cellwall area) in both species while mitochondria were larger inthe dark in P. sulcata but not in P. laevigata. Ultrastructuralchanges were not clearly correlated with changes in photosyntheticand respiratory rates. These results directly support the suggestionthat some intra-cellular structures are energy-generating reservesthe dimensions of which can rapidly change. Parmelia sulcata, Parmelia laevigata, lichen algae, light and dark storage, starvation, reserve substances, organdie dimensions     

ONTOGENY AND STRUCTURE OF THE SECONDARY PHLOEM IN EPHEDRA

The secondary phloem in Ephedra is atypical of the gymnosperms in general and exhibits several angiosperm-like characteristics. The ray system of the conducting phloem consists of parenchymatous, multiseriate rays. The axial system contains parenchyma cells, sieve cells, and unusual albuminous cells reminiscent of the specialized parenchyma cells found in some angiosperms. These cell types may intergrade with each other. P-protein in the developing sieve element appears early in the form of a single, ovoid slime body. Later, smaller slime bodies appear and quickly disperse. In the mature sieve element the single, ovoid slime body is lost, and P-protein is then evident in the form of a parietal cylinder, thread-like strands, amorphose globules, or a slime plug. Necrotic-appearing nuclei are commonly found in mature sieve cells.     

WIDESPREAD PHAGOCYTOSIS OF CILIATES AND OTHER PROTISTS BY MARINE MIXOTROPHIC AND HETEROTROPHIC THECATE DINOFLAGELLATES1

An electron microscopic examination of large amorphous inclusions located in a variety of photosynthetic thecate dinoflagellates (Alexandrium ostenfeldii (Paulsen) Balech et Tangen, Gonyaulax diegensis Kofoid, Scrippsiella sp., Ceratium longipes (Bailey) Gran, and Prorocentrum micans Ehrenberg) and a nonphotosynthetic thecate species (Amylax sp.) revealed each inclusion to be a food vacuole, the majority of which were ingested ciliate prey. Recognizable features of these ciliates included linear arrays of basal bodies and cilia consistent with oligotrich polykinetid structure, characteristic macronuclei, chloroplasts (evidently kleptoplastids), cup-shaped starch plates, and cylindrical extrusomes. Three species contained (apparent) nonciliate prey: Scrippsiella sp., whose food vacuoles consistently contained unusual and complex extrusome-like cylindrical bodies having a distinctive six-lobed, multilayered structure; P. micans, which contained an unidentified encysted cell; and a single A. ostenfeldii cell, containing a Dinophysis sp. dinoflagellate cell. Several food vacuoles of ciliate origin had a red hue. This, together with the resemblance of A. ostenfeldii cells to planozygotes, suggests that similar structures previously identified as accumulation bodies may in fact be food vacuoles and that feeding may in some cases be associated with sexual processes.     

The fine structure of ependymal cells part II: An electron microscopic study of the soft-shelled turtle paraventricular organ,with special reference to the fine structure of ependymal cells and so-called albuminous substance

Summary The present study deals with the electron microscopic observations on the softshelled turtle paraventricular organ, with special reference to the relationship of the ependymal cells and the so-called albuminous substances. It is shown that the so-called albuminous substances consist of the tips of neuronal processes extending into the ventricular lumen. They probably arise from the nerve cells lying within the hypendymal or the underlying tissue. The ependymal cells of the PVO themselves are basically similar in structure to those of any other animal.The processes observed contain two types of vesicles, namely: the clear vesicle, 500 to 1600 Å in diameter, and the cored vesicle, measuring 600 to 1500 Å in diameter, which has a distinct membrane enclosing an extremely dense core of variable sizes. The functional significance of these vesicles is discussed in relation to that of inclusions in the neurosecretory and the autonomic nerve fibers in the hypothalamus.The findings indicate that in the terminal endings of the processes a production or formation of vesicles might occur and that these vesicles might be discharged into the cerebrospinal fluid by microapocrine secretion.The author's grateful thanks are due to Prof. E. Yamada for his continuously kind guidances and due to Prof. T. Sakurai for his constant encouragement.     

STARCH GRANULE FORMATION IN DEVELOPING SEEDS OF PISUM SATIVUM L.: EFFECT OF GENOTYPE

Cell development and starch granule formation in seeds of three pea (Pisum sativum L.) genotypes, R/R Rb/Rb, r/r Rb/Rb, and R/R rb/rb, affecting cotyledon starch were compared. Cotyledon cells at 10 days after flowering were highly vacuolated and contained small protein bodies in the vacuoles and small oval starch granules in the cytoplasm in all three genotypes. Gradients of cell development from the center to the periphery of the cotyledon and toward the cotyledon-hypocotyl axis persisted through the cell enlargement, reserve synthesis, and into the maturation stages of cotyledon development. By 14 days after flowering, many small vacuoles lined with protein deposits had been formed. Vacuoles were only observed in peripheral and basal cells by 18 days after flowering. Starch granules were oval and birefringent in all three genotypes at 10 days. Starch granules in R/R Rb/Rb and R/R rb/rb cotyledons expanded regularly remaining nearly oval and birefringent throughout development. In contrast, starch granules from r/r Rb/Rb cotyledons began to fragment by 14 days after flowering. This process began as a single fissure, followed by a second fissure usually at or near right angles. Finally, because of the fragmentation, the granules appeared compound, and only a portion of the granule was birefringent. All genotypes contained nearly equal volumes of liquid endosperm and embryo at 10 days after flowering. In addition, a layer of parenchyma tissue (ovular and/or endospermic) inside the seed coat was observed. Although, thin walled and poorly defined cytologically, the parenchyma cells contained large numbers of starch granules. These granules were a mixture of simple and compound types in all genotypes. By 18 days after flowering, the parenchyma tissue was reduced to a small layer of cell walls and all starch granules had been mobilized.     

A light and electron microscopy study of the epidermis of Paphiopedilum spp. with emphasis on stomatal ultrastructure

Abstract Light and fluorescence microscopy studies indicated that chlorophyll was absent from the guard cells of the lady slipper orchids, Paphiopedilum insigne (Wall.) Pfitz, P. insigne (hybrid), P. venustum (Wall.) Pfitz and P. harrisseanum Hort. In the guard cells of P. aureum hyeanum Hort., however, very slight red fluorescence suggested that chlorophyll and hence chloroplasts were present. Ultrastructural studies of the lower epidermis of P. insigne (hybrid) confirmed the absence of chloroplasts in guard and epidermal cells although plastids of an unusual structure were found in these cells. In fully developed epidermal cells the plastids contained large amounts of a fibrous, possibly proteinaceous substance, spherical, lightly staining vesicles and an electron-dense material located in reticulate and non-reticulate regions. Additionally, latticed crystalline inclusions and plasto-globuli were occasionally observed in the epidermal cell plastids. In plastids of fully developed guard cells the fibrous material, starch and plastoglobuli were present. From the earliest stages of development of the epidermal tissue starch was present in both epidermal cell and guard cell plastids. At maturity, however, starch had accumulated to greater levels in the guard cell plastids and had entirely disappeared in the epidermal cell plastids. In differentiating epidermal tissue, plasmodesmata were found between neighbouring epidermal cells and between guard and epidermal cells. At maturity, plasmodesmata between guard and epidermal cells were not observed. Mitochondria were particularly abundant in guard cells. Large oil drops developed in guard and epidermal cells, being especially abundant in the former at maturity. Our results confirm the observations of Nelson & Mayo (1975) that certain lady slipper orchids possess functional stomata the guard cells of which do not contain chloroplasts.     

ULTRASTRUCTURAL CHANGES ASSOCIATED WITH UTILIZATION OF METABOLITE RESERVES AND TRICHOME DIFFERENTIATION IN THE PROTOCORM OF VANDA

Certain aspects of protocorm development in Vanda were examined ultrastructurally. The parenchymal cells of the protocorm accumulate substantial quantities of lipid, protein, and carbohydrate reserves which disappear gradually with the senescence of the parenchymatous region. The proteinaceous reserves appear initially as discrete bodies which become intimately associated with clusters of small tubules. The tubules eventually disperse throughout the cytoplasm and disappear following depletion of the protein bodies. The lipid reserves also appear as discrete bodies and are associated with an electron dense, laminated inclusion which appears to increase in size with the disappearance of the lipid bodies. While plastids in the meristematic cells differentiate a well-developed thylakoid system and contain little starch, those of the parenchymal cells contain large starch grains and numerous osmiophilic droplets and develop meager thylakoid systems. Membrane-bound crystalline structures of hexagonal and rhomboid cross section occur frequently in the cytoplasm of senescent parenchyma cells. Trichome initials, which differentiate from the epidermis, contain few conventional organelles and exhibit numerous membrane-bound structures containing many small crystalline inclusions. Numerous vesicles accumulate at the tips of the trichomes in spaces between the cell wall and the plasmalemma.     

ULTRASTRUCTURE OF THE CARPOSPOROPHYTE AND CARPOSPOROGENESIS IN THE PARASITIC RED ALGA PLOCAMIOCOLAX PULVINATA SETCH, (GIGARTINALES,PLOCAMIACEAE) 1

The ultrastructure of the carposporophyte and carposporogenesis is described for the parasitic red alga Plocamiocolax pulvinata Setch. After presumed fertilization the zygote nucleus is apparently transferred to the auxiliary cell which initiates gonimoblast cell production. These gonimoblast cells differentiate into storage or generative cells. Storage gonimoblast cells (SGC) are large and multinucleate, contain large quantities of starch and are located nearest the auxiliary cell, when compared to the smaller uninucleate, devoid of starch, generative gonimoblast cells (GGC) that form terminal lobes of carpospores. In addition, compressed membrane bodies and annulate lamellae are common in these cells. During carposporophyte maturation the amount of starch in the SGC's decreases and eventually the auxiliary cell, as well as SGC's, degenerate. Generative gonimoblast cells (GGC's) cleave repeatedly to form carpospores which are interconnected by small pit connections. Stage one-carpospores are recognized by their elongated shape, the formation of small     

Ultrastructure of the epidermis of adult and embryonic Paravortex species (Turbellaria,Eulecithophora)

The epidermis and associated structures of adult and embryonic Paravortex cardii and Paravortex karlingi, internal parasites of Cerastoderma edule, have been examined using scanning and transmission electron microscopy. The cellular epidermis of adult Paravortex bears cilia and microvilli which differ in number and distribution between P. karlingi and P. cardii. Cellular organelles include mitochondria, lipid bodies, Golgi bodies, and ultrarhabdites. Epidermal nuclei are located in the proximal portion of the cells. The development of the tegument of embryo Paravortex has been described and a possible origin for the embryo capsule is suggested. These findings are discussed in relation to the phylogenetic status of the Turbellaria in relation to other Platyhelminthes and in the functional adaptation of the epidermis for a parasitic mode of life.Abbreviations bb- basal bodies - bl- basal lamella - c- cilia - cp- capsule - dc- dark cells - e- embryos - ep- epidermis - g- Golgi bodies - int- interdigitation (of cells) - l- lipid - lf- lamellar fold - mc- migrating cell - mf- membranous folds - mt- mitochondria - mv- microvilli - n- nucleus - nb- neoblasts - p- projections of epidermis - par- parenchyma of mother - pr- primary rootlet - rc- rhabditogen cells - sr- secondary rootlet - ur- ultrarhabdites - vt- vitelline material     

PSEUDULVELLA AMERICANA BELONGS TO THE ORDER CHAETOPELTIDALES (CLASS CHLOROPHYCEAE), EVIDENCE FROM ULTRASTRUCTURE AND SSU RDNA SEQUENCE DATA1

The genus Pseudulvella Wille 1909 includes epiphytic, freshwater, or marine disk‐shaped green microalgae that form quadriflagellate zoospores. No ultrastructural or molecular studies have been conducted on the genus, and its evolutionary relationships remain unclear. The purpose of the present study is to describe the life history, ultrastructural features, and phylogenetic affiliations of Pseudulvella americana (Snow) Wille, the type species of the genus. Thalli of this microalga were prostrate and composed of radiating branched filaments that coalesced to form a disk. Vegetative cells had a pyrenoid encircled by starch plates and traversed by one or two convoluted cytoplasmic channels. They had well‐defined cell walls without plasmodesmata. Asexual reproduction was by means of tetraflagellate zoospores formed in numbers of two to eight from central cells of the thallus. The flagellar apparatus of zoospores was cruciate, with four basal bodies and four microtubular roots. The paired basal bodies lay directly opposite (DO) one another. The microtubular root system had a 5‐2‐5‐2 alternation pattern, where the “s” roots contained five microtubules in a four‐over‐one configuration. A tetralobate nonstriated distal fiber connected all four basal bodies. A wedge‐shaped proximal sheath subtended each of the basal bodies. The ultrastructural features of the zoospores were those of members of the order Chaetopeltidales. Phylogenetic analyses based on SSU rDNA placed P. americana sister to Chaetopeltis orbicularis in a well‐supported Chaetopeltidales clade. Such a combination of features confirmed that this alga is a member of the order Chaetopeltidales.     

DEVELOPMENTAL ANATOMY AND ULTRASTRUCTURE OF THE ANT-FOOD BODIES (BECCARIIAN BODIES) OF MACARANGA TRILOBA AND M. HYPOLEUCA (EUPHORBIACEAE)

Macaranga is a common secondary growth tree of S.E. Asia. Nine species possess hollow stems which harbor an ant colony, and also produce food bodies which are eaten by the ants. In return, the ants protect the plant from herbivore damage. The multicellular food bodies of M. triloba (Bl.) Muell. Arg. are developed on the underside of down-turned clasping stipules, while in M. hypoleuca (Reichb. f. and Zoll.) Muell. Arg. they are produced on the abaxial surface of young leaves. Food body cells of both species are very rich in lipid, contain large starch grains, and possess an electron-dense hyaloplasm. It is proposed to name the Macaranga ant-food bodies Beccariian bodies in honor of the Italian botanist Odoardo Beccari who explored S.E. Asia in the late 1800s.     

Raw starch–degrading α‐amylase from Bacillus aquimaris MKSC 6.2: isolation and expression of the gene,bioinformatics and biochemical characterization of the recombinant enzyme

Aims

The aims were to isolate a raw starch–degrading α‐amylase gene baqA from Bacillus aquimaris MKSC 6.2, and to characterize the gene product through in silico study and its expression in Escherichia coli.

Methods and Results

A 1539 complete open reading frame of a starch–degrading α‐amylase gene baqA from B. aquimaris MKSC 6·2 has been determined by employing PCR and inverse PCR techniques. Bioinformatics analysis revealed that B. aquimaris MKSC 6.2 α‐amylase (BaqA) has no starch‐binding domain, and together with a few putative α‐amylases from bacilli may establish a novel GH13 subfamily most closely related to GH13_1. Two consecutive tryptophans (Trp201 and Trp202, BaqA numbering) were identified as a sequence fingerprint of this novel GH13 subfamily. Escherichia coli cells produced the recombinant BaqA protein as inclusion bodies. The refolded recombinant BaqA protein degraded raw cassava and corn starches, but exhibited no activity with soluble starch.

Conclusions

A novel raw starch–degrading B. aquimaris MKSC 6.2 α‐amylase BaqA is proposed to be a member of new GH13 subfamily.

Significance and Impact of the Study

This study has contributed to the overall knowledge and understanding of amylolytic enzymes that are able to bind and digest raw starch directly.     

Effects of initial inoculation density of Paenibacillus polymyxa on colony formation and starch‐hydrolytic activity in relation to root rot in ginseng

Aims: To examine the relationships between population growth and biological characters of the plant‐growth‐promoting rhizobacterium Paenibacillus polymyxa GBR‐1. Methods and Results: Population growth, colony formation, starch‐hydrolytic activity, and ginseng root rot caused by P. polymyxa GBR‐1 isolated from a rotten ginseng root were examined in vitro and in vivo at high [1 × 10⁸ colony‐forming units (CFU) ml^?1] and low (1 × 10⁶ CFU ml^?1) initial inoculum densities. Paenibacillus polymyxa GBR‐1 showed strong starch‐hydrolytic activity on modified starch agar with relatively low starch content, but only at certain incubation temperatures (18 and 23°C); the high‐density inoculum produced bacterial colonies about nine times thicker than those formed from the lower inoculum density. Light, scanning electron, and transmission electron microscopy showed that the thick colonies from the high‐density inoculum were filled with extracellular polymeric substances (EPS), in which a relatively small number of ovoid‐rod‐shaped bacterial cells (mostly endospore‐bearing cells) were distributed. In contrast, the thin colonies from the low‐density inoculum were composed of massive vegetative cells with a rectangular rod shape and minimum EPS. Fluorescent in situ hybridization (FISH) revealed that the β‐amylase gene was expressed only in bacterial cells from the thick colonies formed from the high‐density inoculum, but not in those from the low‐density inoculum. The culture filtrate from the thick colonies produced a hydrolytic clear zone on modified starch agar, degraded starch granules in various manners, and produced rot symptoms on ginseng root tissues. Conclusions: The biological properties of colony formation, starch hydrolysis, and ginseng tissue rotting by P. polymyxa GBR‐1 are interrelated; they are influenced by the initial bacterial population density but not by the in situ and the final population densities. Significance and Impact of the Study: Knowledge of disease‐inducing characters of P. polymyxa GBR‐1 can be used in the development of biocontrol strategies.     

U bodies respond to nutrient stress in Drosophila

The neurodegenerative disease spinal muscular atrophy (SMA) is caused by mutation of the survival motor neuron 1 (SMN1) gene. Cytoplasmic SMN protein-containing granules, known as U snRNP bodies (U bodies), are thought to be responsible for the assembly and storage of small nuclear ribonucleoproteins (snRNPs) which are essential for pre-mRNA splicing. U bodies exhibit close association with cytoplasmic processing bodies (P bodies), which are involved in mRNA decay and translational repression. The close association of the U body and P body in Drosophila resemble that of the stress granule and P body in yeast and mammalian cells. However, it is unknown whether the U body is responsive to any stress. Using Drosophila oogenesis as a model, here we show that U bodies increase in size following nutritional deprivation. Despite nutritional stress, U bodies maintain their close association with P bodies. Our results show that U bodies are responsive to nutrition changes, presumably through the U body–P body pathway.     

Histocytological changes and reserve accumulation during somatic embryogenesis in Eucalyptus globulus

We recently described a protocol for Eucalyptus globulus somatic embryogenesis (SE). For its immediate use at industrial levels, some stages of the process require better control. In particular, SE germination rates are variable, decreasing SE efficacy. As reserves may play a central role in embryogenic processes, we followed histocytological changes and reserve fluctuations, during SE. For SE induction, explants of mature zygotic embryos were grown on Murashige and Skoog (MS) medium with 3 mg l⁻¹ α-naphthalene acetic acid and later transferred to MS without growth regulators (MS_WH). Samples of zygotic embryo cotyledons (explants), of globular and dicotyledonar somatic embryos, and of embling leaves were analysed for reserve accumulation and histocytological profiles. Cotyledon cells of zygotic embryos were rich in lipid and protein bodies, having almost no starch. After 3 weeks of induction, starch grain density increased in differentiated mesophyll regions, while in meristematic regions their occurrence was diffuse. In globular somatic embryos, starch accumulation increased with time (in amyloplasts), but protein bodies were absent. Cotyledonary somatic embryos had lower density of starch grains and absence of lipid and protein bodies. Embling leaves showed typical histological organisation. This is the first comprehensive study on histological and cytological changes during Eucalyptus SE with emphasis in reserve accumulation. With this work we demonstrate that the presently available SE protocol for E. globulus leads to reserve fluctuations during the process. Moreover, the reserves of somatic embryo cotyledons differ from those of their zygotic embryo counterparts, which reinforce the importance of reserves in the embryogenic process and suggests that manipulating external conditions, SE may be optimised giving suitable emblings production for industrial purposes.     

EVIDENCE FOR DIVERSE CELL TYPES IN THE APICAL REGION OF THE ROOT EPIDERMIS OF PANICUM VIRGATUM

All epidermal cells in root tips of panicoid grasses have been considered to be capable of hair formation. Observations made in this investigation suggested that cells of two maturation potentials may be present in the root-tip epidermis of Panicum virgatum. Protein bodies which swell and fuse in the region of elongation were revealed in the meristem of this grass by different staining procedures. In many roots not all cells seemed to receive the same amount of these bodies or of the protein-positive material which appeared to arise from them. Only deeply stained cells with large nucleoli were seen to form hairs. Epidermal cells of very hairy roots contained uniform nucleoli and exhibited similar distributions of protein material. The protein positive inclusions were never found in the cortex, a region of cells with one maturation potential. Following chloramphenicol treatment, root tips were found to contain epidermal cells with nucleoli of similar size, a reduced amount of protein bodies, and a reduction in the number of root hairs. RNase treatment did not appear to affect the integrity of the inclusions. The significance of such protein bodies is discussed in relation to differentiation of epidermal cells in P. virgatum.     

RESPONSES OF FRESHWATER ALGAE TO INHIBITORY VANADIUM CONCENTRATIONS: THE ROLE OF PHOSPHORUS1

We found that species-specific differences exist among a variety of freshwater algae and cyanobacteria in the extent to which growth and photosynthesis are inhibited by vanadium. A major factor controlling the degree of inhibition by vanadium was the phosphorus state (P-sufficient vs. P-deficient) of the organisms. In P-sufficient cultures, vanadium was inhibitory when the vanadium concentration exceeded the phosphate concentration. In P-deficient cultures, the depression of photosynthesis by vanadium increased with increasing phosphorus deficiency. Our conclusion that vanadium competed with phosphate for uptake sites was supported by the following three observations: 1) the decreased influx of ³²P-PO ₄ into P-deficient cells in the presence of vanadium, 2) the amelioration of vanadium inhibition of photosynthesis by the addition of phosphate, and 3) the accumulation of vanadium by cells. At vanadium concentrations that severely inhibited growth, the cells of Scenedesmus obliquus (Turp.) Kruger were larger than normal and contained more vacuoles, lipid, and starch bodies than normal cells. Four-celled coenobia were replaced by unicells. Scenedesmus acutusf: alternans Hortobagyi cells from vanadium-inhibited cultures had 7.5 times more vanadium per cell than control cultures and contained numerous granules that did not stain for polyphosphate and may be composed of condensed vanadate molecules. The cellular P quota and turnover time of PO₄in the medium are important regulators of the extent of inhibition by vanadium.     

Immunolocalization of alkaloids and X-ray microanalysis of elements in lupin seeds

Summary Immunolocalization of alkaloids in lupin seeds (Lupinus spp.) has been performed by cryofixation and conventional methods. Alkaloids were localized in the protein bodies of the cotyledon cells. Some immunogold particles in the walls of these cells were also observed. There were no differences in the sites of localization between the two mentioned methods. X-ray microanalysis of elements showed the presence of P, Mg, S, and K in the protein bodies of cotyledon cells in lupin seeds. The role of K⁺ in alkaloids transport is discussed.