Plastid development and floridean starch grain formation during carposporogenesis in the coralline red algaLithothrix aspergillum Gray

Summary The development of the chloroplasts and the formation of floridean starch grains during carposporegenesis in the coralline algaLithothrix aspergillum Gray, was studied by electron microscopy. Proplastids are first recognized next to the plasmalemma in the youngest cell of the carposporangial filament.The peripheral thylakoid is the first internal membrane system observed in the proplastid. As the pro-plastid increases in size an irregular branched tubular membrane system, made up of membranous tubules 30–35 nm in diameter, forms in the DNA region of the plastid. This membrane system appears to function as a pro-lamellar body as the internal thylakoids are connected to it and appear ot form from it. As thylakoid development continues, the plastids enlarge and may divide, leaving one of the daughter plastids with the pro-lamellar body. Thylakoids develop either from the pro-lamellar body, or by extension and possibly duplication of existing thylakoids. At about the time that starch grain formation commences the thylakoids have arranged themselves into parallel groups and the single DNA containing region of the plastid has separated into a number of small areas of DNA fibrils destributed throughout the plastid. The earliest signs of phycobilisomes on the outside of the thylakoids are also seen at this stage.Starch grains develop in the cytoplasm, but in intimate association with the endoplasmic reticulum (ER) which passes on both sides of the developing starch grain, and which appears to be involved in starch grain formation. This close ER-starch grain association, can persist into the mature carpospore. At no stage has any close association between the ER and the chloroplasts been observed.     

Gestörte Thylakoidbildung in Chloroplasten einer xantha-Mutante von Arabidopsis thaliana (L.) Heynh.

Zusammenfassung In den Palisadenzellen von Keim- und Rosettenblättern einer rezessiven xantha-Mutante von Arabidopsis thaliana fehlt den Plastiden die für normale, grüne Chloroplasten typische Schichtenstruktur. Licht- und elektronenmikroskopische Untersuchungen ergaben, daß sich dieser genabhängige Differenzierungsdefekt während der Plastidenentwicklung beim Übergang von den Tubuli des Prolamellarkörpers zu Thylakoiden manifestiert. Es entstehen aus dem persistierenden Prolamellarkörper nur einzelne abnorme Thylakoide, die zuweilen napfoder taschenartig verformt oder zu Magnograna vereinigt sein können. Besonders charakteristisch für die Mutante aber ist, daß solchen Thylakoiden häufig parallel laufende Züge einzelner Tubuli oder Fibrillen beidseitig dicht aufliegen. Auf Grund Dieser Anordnung wird die Möglichkeit eines Thylakoidwachstums durch laminalen Einbau von Tubuli erörtert.In den Blättern der Mutante wurden nur Carotinoide, jedoch keine Chlorophylle festgestellt. Zugleich finden sich in den entwicklungsgehemmten Plastiden, neben Phytoferritin-Partikeln, zahlreiche osmiophile Globuli sowie Matrixeinschlüsse unbekannter Natur. Daher wird die Frage diskutiert, ob die beobachteten Störungen der Thylakoid-Differenzierung in der Mutante auf den Chlorophyllmangel oder auf eine blockierte Strukturproteid-Synthese zurückgehen.Alle übrigen Zellorganelle sind in der Mutante ebenso gestaltet wie in der grünen Normalform. Besonders wird auf das Vorkommen von dense bodies hingewiesen und ihre Beziehung zu Sphärosomen erörtert.

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Disturbed thylakoid-formation in chloroplasts of a xantha-mutant of Arabidopsis thaliana (L.) Heynh.

Summary A monohybrid recessive xantha-mutant of Arabidopsis thaliana was grown aseptically on mineral agar +2% sucrose up to maturity. The cotyledons and rosette leaves were non-green during all developmental stages, their yellow colour bleaching with age.Palisade cells of various leaves of mutant plants were investigated light- and electron microscopically. All of the organelles of these cells, except the plastids, had a normal appearance. Special attention was paid to the existence of dense bodies, and their relationship to sphaerosomes and lysosomes was outlined.In the mutant plastids the typical thylakoid differentiation present in the chloroplasts of the green Arabidopsis plant is entirely lacking. Within the palisade cells the plastids are normal in number and size. Under the light microscope they appear as hyaline vesicles with usually two primary grana. Their outline is characterized by numerous invaginations and protrusions; however, it is still uncertain to what extent this amoeboidy is only an artifact.The specific gene dependent block in the plastid development is apparently effective during the conversion of tubules of the prolamellar body to thylakoids. From the persistent prolamellar bodies in the mutant only single abnormal thylakoids originate. These often have a deformed cup- or ventricle-like shape and occasionally are piled up as magnograna. In a characteristic manner tubules and fibrils are closely associated in parallel rows with the outsides of the thylakoids. The fibrils having a mean diameter of 75 Å are connected with the tubules which are derived from the prolamellar body. From this striking aggregation the possibility of a laminal fusion of tubules as a process of normal thylakoid growth is deduced.By pigment analysis of mutant leaves no chlorophyll but only carotenoids were detected. However, many osmiophilic globules as well as large bodies of unknown composition (proteinaceous?) appear in the plastid matrix. Therefore the question is discussed whether the disturbances of the thylakoid differentiation is due primarily to a blocked chlorophyll formation or to an inhibition of the synthesis of some structural membrane proteids.Phytoferritin particles which up to now have not been observed either in normal or in mutant plastids of Arabidopsis were frequently found in the plastid matrix of this xantha-mutant.

     

Transmission of plastids by pollen in Antirrhinum majus

Summary Up to now Antirrhinum was classified as a typical example for a uniparentalmaternal inheritance of the plastids. However, the findings reported here prove that also the male gametophyte of Antirrhinum may occasionally transmit plastids into the egg. This conclusion is based on genetic experiments involving a form of the plastom mutant prasinizans which is described as gelbgrüne prasinizans. In contrast to all other plastid mutations known in Antirrhinum majus this mutant originated in Sippe 50 is completely viable. In plants containing plastids of this mutant type only, the mutant character is manifested during early growth stages. Cotyledons and first foliage leaves which are initially white or white yellow, slowly turn green and become indistinguishable from normal Sippe 50. Reciprocal crosses of green Sippe 50 with gelbgrüne prasinizans gave few variegated descendants; the others were exclusively plants identical with the maternal parent as far as leaf colour is concerned (Table). The variegated individuals cannot be gene mutants since selfing and crossing experiments showed non-mendelian inheritance. Furthermore it could be ruled out that in the cross Sippe 50 x gelbgrüne prasinizans the three variegated descendants represent spontaneous new plastom mutants because the pale tissue in these plants turned green in the same way as the paternal parent. Because of the typical greening of this mutant and since plastid mutations could be ruled out we have to conclude that plastids were transmitted by the pollen parent into the egg. There these plastids multiplied together with the maternal plastids giving rise to the chimeras after sorting-out of the two plastid types. This interpretation is supported by the observation of mixed cells in tissues where the leaf variegation is finely mosaiced. The results were possible only because the plastids of the pollen parent can be unequivocally recognised.     

The ∈ subunit of the chloroplast ATP synthase of Pisum sativum

In contrast to the well-characterized spinach ( Spinacea oleracea) chloroplast ATP synthase (CF1–CFo), the properties of the chloroplast ATP synthase from pea (Pisum sativum ) have not been as intensively studied. Preliminary data suggested that the regulatory properties of the two enzymes differ. In the absence of activating treatments the ATPase activity of pea thylakoids in the dark was higher than that in spinach thylakoids. When assayed in the presence of sulfite, the MgATPase activity of pea thylakoids was inhibited to a maximum of 67% by tentoxin, indicating that the dark ATPase activity is in part catalyzed by CF1–CFo. The ATPase activity of purified pea CF1 was also higher than that of spinach CF1 in the absence of activating treatments. These differences could result from the different regulatory properties of the pea or subunit or both. The pea subunit was less effective in binding to or inhibiting the ATPase activity of pea o r spinach CF1 deficient in (CF1-). Spinach inhibited the ATPase activity of pea CF1- at lower concentrations than pea . The gene encoding the pea subunit was cloned and over-expressed. Recombinant pea did not restore low proton permeability to spinach thylakoid membranes reconstitituted with spinach CF1-, although pea was effective when tested with pea thylakoids reconstitituted with pea CF1-. These results confirm earlier suggestions that the C-terminal region of is important in -CF1 and -CFo interactions.     

Membrane differentiation in the cytoplasmic-tubule system of the intestinal absorptive cells of the lamprey,Lampetra japonica

Summary Specific membrane differentiation occurs in the cytoplasmic-tubule system of the absorptive cells lining the mucosa of the lamprey anterior intestine. The absorptive cells are characterized by the presence of abundant mitochondria and a system of well-developed cytoplasmic tubules (120 nm in diameter). The cytoplasmic tubules open on to the basolateral cell surface and contain numerous lipoprotein particles (50–100 nm diam.) in their lumina. Lipoprotein particles are also observed in the endoplasmic reticulum and the Golgi complex, and they are transfered to the lateral intercellular space and lamina propria by way of the cytoplasmic tubules. Spirally-wound parallel rows of particles are found in the luminal surface of the cytoplasmic tubules. The rows are 17 nm apart and are wound spirally at a pitch of 210 nm. Freeze-fracture images of the tubule membranes also show spiral arrays of particles (9 nm in diameter) on the P-face, and complementary shallow grooves on the E-face. From these observations, it is suggested that the cytoplasmic-tubule system of the intestinal absorptive cells serves as a channel for the transport of synthesized lipoprotein into the interstitium, and is also the site of the ion and water exchange essential for the maintenance of ionic homeostasis.     

An ultrastructural and cytochemical investigation of the colonial green algaPediastrum tetras during zoospore formation

Summary Ultrastructural changes during zoospore formation and aggregation into motile, aggregating zoospores were examined in the colonial green algaPediastrum tetras. Developing zoospores are characterized by irregularly shaped nuclei, presence of peripheral networks of rough endoplasmic reticulum, chloroplasts with tightly apposed thylakoids and dictyosome cisternae which are compressed and reduced in size. A single membrane bound organelle with a fine granular matrix of moderate electron density of diameter ranging from 0.2 m to 0.6 m and associated with chloroplasts, mitochondria and endoplasmic reticulum was found only in adult cells. Although this organelle has the morphology of a microbody, it did not stain with 3,3-diaminobenzidine (DAB) at pH 9.6 or pH 7.6, whereas mitochondrial membranes stained. No DAB staining was observed along the cell wall or the plasma membrane of zoospores, or associated with endoplasmic reticulum, plastid membranes or dictyosomes.     

Structure granaire,réduction du NADP et photophosphorylation des chloroplastes isolés de feuilles d'orge

Summary Barley chloroplasts (Hordeum vulgare L.) have been isolated in aqueous medium by previously described techniques which preserve the outer plastid membrane in numerous chloroplasts. Thus intact chloroplasts are concentrated in Class I fraction and non intact in Class II fraction. A third type, broken Class I, is obtained by the action of a very dilute buffer solution.The observation of freeze-etched preparations has shown that the main distinctive character between the two classes is not so much the presence or the absence of the outer plastid membrane, as it was assumed, as the state of the thylakoids. In Class I chloroplasts grana are shrunken, in those of Class II, grana are swollen. In both cases the outer membrane may or may not be preserved.The breakage of chloroplasts resulting from treatment with osmotic shocks is due to the dilatation of the extra-lamellar matrix. The swelling of intra-thylakoidal volumes resulting from such a treatment is much less important.It is shown that Class I chloroplasts have a very low NADP reductase activity which is strongly increased after the chloroplasts are broken by osmotic shocks. Such a treatment is without any effect on Class II chloroplasts, which always exhibit a low NADP reductase activity.The situation is rather different in regard to photophosphorylation. It is also lower in Class II than in Class I, but after breakage by osmotic shocks the increase of this activity is weak, and much less significant than the increase observed in NADP reduction. The compression and cohesion of the thylakoids is not required for high photophosphorylation activity with artificial electron acceptors such as PMS. In this case cyclic photophosphorylation is higher in Class II than in Class I.

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Abbreviations ADP, ATP adénosine di et triphosphate - EDTA éthylène diamine trétaacétate - NAD, NADP, NADPH₂ nicotinamide adénine dinucléotide, d° phosphate (formes oxydée et réduite) - PMS phénazine méthosulfate - Pi phosphate inorganique     

Chromoplasts of Tropaeolum majus L.: Structure and development

Summary The fine structure of chromoplasts in epidermal cells of flower petals of Tropaeolum has been investigated by light, polarizing, and electron microscopy at different stages of development. The pale greenish-yellow petals still enclosed in the bud contain barely differentiated chloroplasts with few, irregular grana. The chromoplasts of unfolding petals show differently oriented bundles of tubules with variable diameters (mean: 17 nm). Thylakoid membranes become reduced more and more. The tubular bundles are intermingled with numerous isodiametric bodies of ca. 50 nm diameter; these bodies are better discernible at later stages when the chromoplasts possess a less dense matrix. The chromoplasts of open flowers are in a state of disorganization at a time when the cytoplasm still appears normal. A comparison is made between chromoplast tubules and tubular structures described from other kinds of plastids. The observations are discussed in view of chromoplast typology and with regard to possible processes underlying chromoplast differentiation in flowers.Abbreviations in Figures Chr chromoplast - CT chromoplast tubules - Cy cytoplasm - D dictyosome - IB isodiametric body - M mitochondrion - MT microtubule - oG osmiophilic globule - S S-body - St starch grain - V vacuole All micrographs from glutaraldehyde-OsO₄-fixed material, unless otherwise specified. The bar designates 1 m (multiples or fractions of it indicated).     

Occurrence of unidentified bodies that resemble “plastid initials” in poplar cells after breaking of dormancy in midwinter

Summary Electron-microscopic studies of plastids in cortical cells of poplar (Populus euramericana cv. gelrica) were carried out to examine whether any structural changes were initiated after breaking of dormancy in midwinter under non-growing conditions. After the breaking of dormancy, ultrastructural changes became evident and the profiles of plastids became heterogeneous. Organelles resembling the plastid initials proposed by Mühlenthaler and Frey-Wyssling in 1965 were frequently observed concomitant with changes in the plastid envelope. The formation of plastid initials appeared to be initiated by the formation of septa in pre-existing plastids. After this stage, narrow connections appeared between the initials and the parent plastids. Approximately 50 days after the breaking of dormancy in late March, further heterogeneity in the profiles of plastids was observed. At this stage, young plastids (plastids without starch granules) were frequently observed and the formation of plastid initials was hardly ever observed. These observations suggest that the plastid initials may be present for only a limited period in the cortical cells of the poplar and may be the precursors of the proplastids. Similar ultrastructural profiles were found in cortical cells of mulberry and in leaf buds of apple trees, suggesting that such changes in the ultrastructure of plastids are a general feature of perennials.     

Über eine Periklinalchimäre aus Plastiden- und Plasmonabänderungen mit „Gewebefenstern”

Zusammenfassung Durch eine bei Epilobium entstandene Kernmutante wurde neben zahlreichen Plasma- und Plastidenabänderungen auch eine Periklinal-chimäre induziert, in der in der hypodermalen Palisadenschicht (L II) eine schwachwüchsige dunkelgrüne Plasmonabänderung über dem Kern (L III) einer chlorophyllfreien Plastidenabänderung liegt. Die Zellen der farblosen Zelldeszendenzen schieben sich in die Lücken der grünen Palisadenschicht ein und bilden weiße Gewebefenster, passen sich dabei aber völlig dem typischen Bau der Palisadenschicht an.

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About a periclinal chimera with tissue windows originated from plastom and cytoplasmon alterations

Summary Besides numerous cytoplasmic and plastid alterations, caused by a nuclear mutant of Epilobium, there was also induced a periclinal chimera which exhibited a poorly growing, dark green cytoplasmic alteration in the hypodermal palisade layer lying above the central tissue of a plastid alteration which is without chlorophyll. The cells of the colourless cell descendants shove into the gaps of the green palisade layer and form white tissue windows. They adapt themselves totally to the typical structure of the palisade layer.

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Mit 8 Textabbildungen     

Über die Feinstruktur des Zellkerns von Acetabularia nach Gefrierätzung

Summary The ultrastructure of the primary nucleus of the marine green algae Acetabularia (Polyphysa) cliftonii as revealed by the freeze-etching technique is described.The nuclear envelope is perforated by about 3×10⁶ pores which appear arranged nearly in rows. The nucleus is covered with a layer of cytoplasm which protects it in the isolated state and resists various manipulations. This cytoplasmic layer is protected by an elementary membrane. The latter appears rough on the cytoplasmic side, and smooth on the side facing the cell sap. The cytoplasmic layer and the surrounding perinuclear cytoplasm are connected by cytoplasmic ducts. The nucleus appears irregularly shaped owing to many invaginations in the nuclear envelope. Sometimes mitochondria are observed in these cavities.     

Ultrastructure of lycopene containing chromoplasts in fruits ofAglaonema commutatum schott (Araceae)

Summary The ripening process in fruits ofA. commutatum is characterized by clearly distinguishable developmental stages of their pericarp plastids. With respect to predominant pigments and ultrastructural features the following scheme is proposed: 1. The green stage with a tendency to thylakoid degeneration and plastoglobule formation leads to 2. the yellow stage. An increasing number of globules, mostly being membrane associated, are converted to tubules. In this stage, the main pigments are -carotene and cryptoxanthine. The development of membraneous invaginations from the inner plastid envelope leads to 3. the red stage. Concomitantly with lycopene synthesis and incorporation, these envelope-derived membranes expand and become electron dense (after KMnO₄ treatment), but maintain their triple-layered structure. Chromoplasts of deep red coloured fruits (1,400 g lycopene g^–1 dry wt) contain lycopene crystals within the lumina of membraneous sacs which are also derived from the inner envelope membrane. The molar ratio between the three main pigments -carotene, cryptoxanthine, and lycopene is about 1110 in this final state. GA/OsO₄ fixation is unable to stabilize the lycopenic structures (membranes as well as crystals).     

Tentoxin effects onSorghum: The role of polyphenol oxidase

Summary In an ultrastructural and cytochemical study of tentoxin-treatedSorghum bicolor (L.) Moench, both bundle sheath and mesophyll plastids were severely affected, Plastids from chlorotic leaf areas lacked most internal membranes yet had plastid ribosomes and large fibrillar areas of plastid DNA. In recovered areas (mottled yellow and green), cells were found that had plastids of near-normal ultrastructure as well as the severely affected plastid-types found in chlorotic leaf areas. Polyphenol oxidase (PPO) cytochemistry of these mottled leaf areas indicated that all recovered mesophyll plastids had PPO whereas all the abnormal mesophyll plastids showed no activity. Because bundle sheath plastids ofSorghum have no PPO activity at any developmental stage, yet are affected by tentoxin, PPO cannot be uniquely affected by this toxin. We suggest that tentoxin may affect the transport of cytosolic proteins into the plastid.     

Ultrastructural localization of photosynthetic activity in thylakoids during chloroplast development in maize

The localization of photosynthetic activity in developing maize (Zea mays L.) chloroplasts was studied in situ by two electron-microscopic-cytochemical methods. The activity of photosystem I was detected by photooxidation of 3,3-diaminobenzidine (DAB) and the activity of the photosystem II by photoreduction of thiocarbamyl nitrotetrazolium blue (TCNBT). During the transformation of proplastids into chloroplasts, at the base of the leaf blade the DAB reaction appeared before the TCNBT reaction. A positive DAB reaction was observed in the single thylakoids of plastids in cells located only about 0.5 mm above the base. Dark, osmiophilic DAB polymers accumulated in the lumina of the thylakoids. Plastid envelopes and tubules of the prolamellar bodies in immature chloroplasts were DAB-negative. In fully differentiated leaf tissue the DAB reaction was intense in the thylakoids of bundle-sheath chloroplasts, as well as in the stroma thylakoids and the peripheral grana thylakoids of mesophyll chloroplats. The photoreduction of TCNBT started in leaf tissue about 1 mm above the base. Dark granular material of reduced TCNBT appeared mostly in the partitions of grana, i.e. interthylakoidally, but some granules were also attached to the stroma thylakoids. The membranes of plastid envelopes and the tubules of prolamellar bodies showed a negative TCNBT reaction. Young bundle-sheath chloroplasts contained some reduced TCNBT in their grana; these deposits largely disappeared in the course of further differentiation. In mature leaf tissue the photoreduction of TCNBT was conspicuous in the grana of mesophyll chloroplasts, but very weak in the single thylakoids and in the granal rudiments of bundle-sheath chloroplasts.Abbreviations DAB 3,3-diaminobenzidine·4 HCl - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - PS(I,II) photosystem (I,II) - TCNBT thiocarbamyl nitrotetrazolium blue chloride     

The general occurrence of “plastid initials” and their development into plastids in cortical cells of woody plants in winter

Summary Electron microscopic studies revealed that plastid initials, presumed precursors of plastids, occur in cortical cells of the following plants studied in February and March: Betula ermanii Cham.; Prunus sargentii Rhed.; Pyrus communis L.; Ribes sinanense F. Maekawa; Salix matsudana Koidz. forma tortuosa Rhed.; and Sambucus sieboldiana var. miquelii Hara. Since plastid initials were found previously in Malus pumila Mill., Morus bombycis Koidz. and Populus euramericana cv. gelrica (Sagisaka 1991), plastid initials have been found in all woody plants examined to date. In P. euramericana cv. gelrica, at later stages of the development of the initials in March, the conglomerates of plastid initials became heterogeneous in terms of size, extent of thylakoid formation and ability to form starch granules. The formation of prolamellar structures was frequently observed in cells of Magnolia kobus var. borealis Sarg., which was sampled on April 19. These observations suggest the course of events in the development of the plastid initial and the continuity of the life of amyloplasts over a year in the life of woody plants.     

On the localization,the fine structure,and the chemical composition of crystalline inclusions in theThesium humifusum haustoria

Summary TheThesium humifusum haustoria onMedicago marina roots, fixed in October–November, frequently contain in the cytoplasm of their cells inclusions consisting of sticks 0,3 m in thickness and 8 to 10 m in lenght, alone or associated in stacks of 3 or 6 units. These sticks consist of fibres, 10 nm in thickness, oriented in the same direction and separated from the others by a gap of 8 nm; these fibres seem to be composed of helically wound filaments and a less electron-dense matrix.The chemical composition of these inclusions was studied by enzymatic digestion in ultra thin sections; pronase digested the cytoplasmic paracrystals. This demonstrates that they are composed primarily of protein.The physiological significance of the inclusions is discussed: presumably the haustorium functions as a storage organe.     

Structure de la glande nasale externe deTiliqua rugosa (Reptilia,Scincidae) et rapports avec sa fonction

Summary The scincid lizardTiliqua rugosa possesses a large external nasal gland which is located intraconchally. Highly ramified tubules, imbedded primarily in the periphery of the gland, unite to form collecting ducts which empty into a short excretory canal. The diameter of the tubules increases progressively from 30. at the distal extremity of the gland to over 200 at the level of the collecting ducts. The intraglandular portion of the excretory canal is often dilated to form an ampulla. The thickness of the epithelium increases from 12 at the level of the tubules to 25–30 in the excretory canal.The excretory canal is lined with an epidermal epithelium close to the point where it enters the vestibule. In all the rest of the gland the tubules are lined with two cell types: large, typical muco-serous cells and striated cells. At the distal end of the tubules the striated cells are narrow and poorly differentiated and alternate more-or-less regularly with the muco-serous cells. The relative proportion of these striated cells increases progressively, as does their size, as one moves proximally down the tubule. In the gland as a whole the striated cells are approximately twice as numerous as the muco-serous cells but, due to their smaller size, they occupy less than one third of the tubular volume.Electron microscopy of the striated cells ofTiliqua rugosa revealed the presence of extensive lateral interdigitations and expansions of the basal cytoplasmic membrane, anatomical specialisations which are normally indicative of active salt transport. These modifications are less marked however than in the external nasal glands of the lizardsLacerta muralis andVaranus griseus, which do not appear to function as salt glands. In addition there are few mitochondria present, although they are of large size. The combination of these ultrastructural features, plus the fact that the striated cells are intermixed with muco-serous cells in the tubules, makes it most unlikely that the external nasal gland ofTiliqua rugosa is capable of elaborating an hyperosmotic fluid. What is more, this has never been conclusively demonstrated in this species in physiological studies.The progressive specialisation of the striated cells from the distal to the proximal section of the tubules poses the problem of the origin and differentiation of this cell type.A review of results obtained from the study ofTiliqua rugosa and other species of lizards shows that the nature of the relationship between structure and function of the external nasal gland is far from clear. The existence of salt glands, capable of excreting hyperosmotic solutions, is invariably linked with the presence in the gland of well-developed striated segments composed almost entirely of cells possessing extensive interdigitations of the lateral membranes. Amongst terrestrial lizards, nasal salt glands are usually found in herbivorous species and they are primarily adapted to the extrarenal excretion of potassium ions. The problem for carnivorous species is more often that of an excess of sodium rather than potassium ions and with the possible exceptionAcanthodactylus species, functional nasal salt glands have not been demonstrated in terrestrial carnivores, despite the presence in some cases of well-developed striated segments in the gland having a similar structure to those found in herbivores. In humid regions, carnivorous lizards probably never require extrarenal excretory mechanism and in arid regions their survival is assured by their capacity to tolerate hypernatraemia when confronted with excessive salt loads. Salt glands capable of eliminating sodium ions to any extent have only been described in two littoral species, an herbivorous iguanid and a carnivorous varanid. Unfortunately the structure of their respective nasal glands has not yet been described and their further study would be desirable.     

The chromoplasts of Or mutants of cauliflower (Brassica oleracea L. var. botrytis)

Summary. The Or mutation in cauliflower (Brassica oleracea L. var. botrytis) leads to abnormal accumulations of -carotene in orange chromoplasts, in tissues in which leucoplasts are characteristic of wild-type plants. Or chromoplasts were investigated by light microscopy of fresh materials and electron microscopy of glutaraldehyde- and potassium permanganate-fixed materials. Carotenoid inclusions in Or chromoplasts resemble those found in carrot root chromoplasts in their optical activity and angular shape. Electron microscopy revealed that the inclusions are made up of parallel, membrane-bound compartments. These stacks of membranes are variously rolled and folded into three-dimensional objects. We classify Or chromoplasts as membranous chromoplasts. The Or mutation also limits plastid replication so that a single chromoplast constitutes the plastidome in most of the affected cells. There are one to two chromoplasts in each cell of a shoot apex. The ability of differentiated chromoplasts to divide in the apical meristems of Or mutant plants resembles the ability of proplastids to maintain plastid continuity from cell to cell in meristems of Arabidopsis thaliana mutants in which plastid replication is drastically limited. The findings are used to discuss the number of levels of regulation involved in plastid replication.     

Protoplasmic streaming in the giant unicellular green algaAcetabularia mediterranea

Summary Protoplasmic Streaming inAcetabularia mediteranea has been studied by microcinematography in 1. germinating zygotes, 2. germlings before the differentiation of rhizoids and apices, 3. young cells with rhizoids and apices, 4. vegetative cells-several centimeters in length, 5. cells with a maximum sized cap, containing secondary nuclei, and 6. cells after cyst formation. Intracellular transport is found to occur at a network-system of thin filaments and at a different system of headed streaming bands. At the network of filaments chloroplasts are found to move at a velocity of 1–2 m/sec. Headed streaming bands move along the filaments and may lead without interruption from the rhizoid to the apex of the cell andvice versa. The front zone of the streaming bands is occupied by a leading cytoplasmic head-structure. Small vesicles, polyphosphate granula and secondary nuclei are the predominant moving structures in headed streaming bands. The velocity of these particles is found to be 3–11 m/sec. The filament system is found during all developmental stages. Headed streaming bands are undetectable in germinating zygotes and develop from small cytoplasmic droplets in germlings to broad heavily loaded bands in the huge vegetative cell.Transport of secondary nuclei by headed streaming bands is not observed during mitotic divisions and after cyst formation, though moving bands are still present for several weeks after cyst formation.     

On T-tubule openings at the sarcolemma of white fast-twitch muscle fibres in fish and frog

Summary In white muscle fibres of a teleost fish T-tubule openings may occur regularly at all Z-disc levels between adjacent peripheral myofibrils, the T-tubule openings thus occurring at a density of ca. 0.9 m^-2.In frog white fibres, T-tubule openings are infrequently seen in material fixed like the fish material. In material prepared according to the albumin method of Gray (1975, 1976 a, b) which renders the muscle fibres swollen, straight tubules or sometimes chains of vesicles instead are seen opening at the sarcolemmal surface. Such tubules occur at a higher density than expected from experiments with local activation of contraction. Lability and dynamics within the T-system normally and during fixation are discussed.