An investigation into the possible light-shielding role of gas vacuoles in a planktonic blue-green alga

When the gas vacuoles of Anabaena flos-aquae Bréb. ex Born. et Flah. are collapsed, the optical properties of the alga change. While this may suggest a light-shielding role, photosynthetic measurements indicate that intact gas vacuoles reduce the light falling on the thylakoids by only 4%, or less. Intact gas vacuoles offer no protection against the lethal effects of ultraviolet light. When the alga is grown at high light intensity the gas vacuoles are fewer in number but are oriented peripherally in the cells. However, this does not markedly affect their light shielding efficiency. Spectrophotometric measurements carried out by others indicate a light shielding role by gas vacuoles in a non-planktonic blue-green alga, Nostoc muscorum Kütz., but do not give a quantitative estimate of this effect. In Anabaena no definite evidence of light-shielding is obtained by such a method. All of the experiments described were conducted with dilute algal suspensions to investigate shielding effects in individual cells. Possible self-shading effects in dense suspensions and surface water blooms require further investigation.     

Kinetics of the assembly of gas vacuoles in the blue-green alga Microcystis aeruginosa Kuetz. emend. Elekin.

Summary In exponentially growing cultures of the blue-green alga Microcystis aeruginosa the number of gas vacuoles per cell decreases and reaches a value of 4.5×10³ at 1.2×10⁷ cells per ml. The assembly of gas vacuoles with respect to number and length was followed after the organelles were caused to collapse by a pulse of ultrasound. The change in the number N of gas vacuoles per cell is N=224.8×t ^0.757, 0<t<24 h. After 24 h 50% of the value of non-sonicated cultures is reached. The changes in the length L of the organelles is expressed by L=87.06 ×t ^0.4084, 0<t<24 h. After 24 h 85% of the control value is reached.Abbreviations used EDTA ethylene diamine tetraacetate - BSA bovine serum albumine - P probability - N number of gas vacuoles - L length of gas vacuoles in nm - t time in hours     

Physiological effects of the presence and absence of gas vacuoles in the blue-green alga,Microcystis aeruginosa Kuetz. emend. Elenkin

Physiological evidence was obtained for a light shielding role for gas vacuoles inMicrocystis aeruginosa Kuetz. emend. Elenkin, by comparing photosynthetic oxygen evolution, growth behaviour and pigment composition of cells with intact or collapsed gas vacuoles. The oxygen evolution rates were strongly dependent on cell concentration, a maximum rate for cells with intact gas vacuoles occurring at about 1.4×10⁹ cells/ml and for cells with collapsed gas vacuoles at about 2.5×10⁹ cells/ml. By using light saturation curves for oxygen evolution, it was estimated that at low light intensities up to 30% of the photosynthetically useable light was shielded at a cell concentration of 6×10⁸ cells/ml. Collapsing the gas vacuoles twice daily did not alter the initial growth rate of the cultures, but enabled them to reach a higher final cell density. Collapsing of gas vacuoles during growth for about four generations resulted in a lower level of all acetone soluble pigments with a greater relative reduction in carotenoids than in chlorophyll a. Collapse of the gas vacuoles does not alter the cell volume. Various optical interactions which could account for light shielding are discussed.     

The role of the motile tubular vacuole system in mycorrhizal fungi

Mycorrhizal fungi, to be effective for the plant, must be able to transfer mineral nutrient elements from sites of uptake at hyphal tips across various distances to the exchange region in the mycorrhiza. Vacuoles are likely to be important in this transport, since they contain elements of nutritional significance in abundance. In tip cells of hyphae of most fungi –- known to include three ectomycorrhizal basidiomycetes, an ericoid mycobiont, and two arbuscular mycorrhizal fungi –- the vacuoles form a motile tubular reticulum. The vacuoles are most active in hyphal tips, but non-motile vacuoles at a distance from the tip can be induced to become motile by environmental changes. Neither the tubular vacuolar reticulum nor its contents are properly preserved by conventional fixation and embedding. Vacuolar tubules are readily shown in vivo with fluorescent tracers, throughout the extramatrical mycelium and in outer hyphae of the sheath in eucalypt mycorrhizas synthesised with Pisolithus sp., but they have proved harder to label in field-collected ectomycorrhizas and ericoid mycorrhizas. Freeze-substitution does preserve the structure of vacuoles and vacuolar tubules, and careful anhydrous techniques allow them to be microanalysed, indicating high content of K and P in vacuoles of hyphal tips, and also in sheath and Hartig net of ectomycorrhizas. Vacuoles contain polyphosphate in diffuse, non-granular form. Polyphosphate is present right up to the tip region of hyphae as well as in sheath and Hartig net: thus important mineral nutrient elements are present at both ends of the long hyphal transport pathway. Exactly what happens in between, however, remains to be elucidated.     

Absence of gas vesicle protein in a mutant of Anabaena flos-aquae

Filaments without gas vacuoles arose spontaneously in the gas-vacuolate alga Anabaena flos-aquae. The non-vacuolate mutant was enriched by repeated sedimentation and subsequently cloned by microsyringe transfer. No revertants have been observed. In the gas-vacuolate wild-type alga the gas vesicle protein was clearly distinguished by gel electrophoresis as one of the ten most abundant protein species present in whole cell extracts. Electrophoresis indicated that the mutant had lost the ability to synthesize the gas vesicle protein. A second mutant partially defective in production of gas vacuoles and gas vesicle protein has been isolated.Abbreviations gv gas vesicle protein - pb phycobilin - TCA trichloracetic acid     

Assembly of gas vacuoles in a cell-free system of the blue-green algaMicrocystis aeruginosa kuetz. emend. elenkin

Summary In a cell-free homogenate of the blue-green algaMicrocystis aeruginosa gas vacuoles are assembled within the first half hour after incubation.     

Gas Vacuoles and Flotation in the Testate Amoeba Arcella discoides

The natural formation of gas vacuoles as a method of movement is described for the testate amoeba Arcella discoides. These vacuoles are used to float the organism from the substrate to the surface in an inverted position.     

Isolation and chemical characterization of gas-vacuole membranes fromMicrocystis aeruginosa Kuetz. emend. Elenkin

Summary A method involving penicillin treatment was developed to osmotically lyse the cells of the blue-green alga,Microcystis aeruginosa Kuetz. emend. Elenkin, and release the pressure-sensitive gas vacuoles intact. The gas vacuoles were purified by liquid-polymer partitioning or by macromolecular sieving and centrifugation. The degree of purification of the gas vacuoles was followed by observation in the electron microscope and by the use of C¹⁴-labeled vacuolated and nonvacuolated strains ofM. aeruginosa. The gas-vacuole membrane is composed of only protein consisting of 10% basic, 18% acidic and 52% non-polar amino acids.Supported by U.S. Atomic Energy Commission, Contract No. AT(11-1)-1338.     

The properties and buoyancy-providing role of gas vacuoles in Trichodesmium Ehrenberg

All three species of the marine blue-green alga Trichodesmium collected in the Sargasso and Caribbean seas were found to possess gas vacuoles. The constituent gas vesicles were much stronger than those found in any freshwater blue-green alga, the mean critical collapse pressures being 12 bars in T. erythraeum, 34 bars in T. contortum and 37 bars in T. thiebautii. This great strength is obviously an adaptation to the hydrostatic pressures at the depths to which these organisms occur in the ocean. In each case the gas vesicles are far too strong to be collapsed by rising cell turgor pressure, though gas-vacuolation could be slowly regulated by the differential growth of gas vesicles and cells. Since the vesicles are of a similar shape and size to those in other species, the vesicle wall material must be stronger. The majority of Trichodesmium colonies collected were positively buoyant, and in all cases tested the buoyancy was dependent on the presence of gas vacuoles. The buoyancy is important in increasing the residence time of these slowly growing algae in the euphotic zone and it is responsible for the surface water-blooms which they form.     

Counting of gas vacuoles by electron microscopy in lysates and purified fractions ofmicrocystis aeruginosa

Summary A microdroplet spray method is described to determine quantitatively the number of gas vacuoles in purified fractions and in total lysates of the blue-green alga,Microcystis aeruginosa.It is found that 6.45×10¹² gas vacuoles of 370 nm length make up one mg of protein. This supports the idea that the entire organelle is made up by a single layer of protein only. The gas vacuole number per cell varies with the stage of growth between 3,700 and 11,000.     

CYTOMORPHOLOGICAL CHARACTERIZATION OF THE PLANKTONIC DIAZOTROPHIC CYANOBACTERIA TRICHODESMIUM SPP. FROM THE INDIAN OCEAN AND CARIBBEAN AND SARGASSO SEAS1

Trichodesmium Ehrenberg species were collected in the Caribbean Sea, Sargasso Sea, and coastal areas of Tanzania (Indian Ocean). The specimens were divided into five species on the basis of morphometric characters such as cell dimensions and colony formation: T. tenue Wille, T. erythraeum Ehrenberg, T. thiebautii Gomont, T. hildebrandtii Gomont, and T. contortum Wille. In addition, Trichodesmium sp., a spherical colony of uncertain taxonomic position was examined. The cell structure of each species was investigated by means of light, scanning electron, and transvnission electron microscopy. Particular attention was paid to the presence and ultrastructural arrangement of gas vacuoles and glycogen fiber clusters (GFCs). This resulted in identification of two major groups of species: 1) T. tenue, Trichodesmium sp. with spherical-shaped colonies, and T. erythraeum with GFCs and more or less localized gas vacuoles; and 2) T. thiebautii, T. hildebrandtii, and T. contortum lacking GFCs and with gas vacuoles spread at random. The species within each group were further characterized with respect to the dimension of the gas vesicles, cylindrical bodies, scroll bodies, and a new cellular inclusion body, Differences in colony formation and cell dimensions correlated with specific ultrastructural characters in five of the six forms. This is the first ultrastructural study comparing different forms of Trichodesmium sampled at geographically remote areas and shows that one species appears identical regardless of the sampling site. Some of the species had not been investigated earlier, and probably more species are to be identified and analyzed.     

The development and vertical distribution of populations of gas-vacuolate bacteria in a eutrophic,monomictic lake

The role of gas vacuoles in the vertical stratification of planktonic bacteria is analysed. Measurements made with certain gas-vacuolate bacteria in laboratory culture suggest that only colonial forms could sink or float fast enough to form population maxima in lakes by vertical migration from other depths. It is suggested that in the case of individual cells the importance of the buoyancy provided by gas vacuoles is to minimise sinking rates and thereby to increase residence times of the organisms at depths where conditions support their growth.Changes in the vertical distribution of a number of gas-vacuolate bacteria were followed throughout the year in a monomictic, eutrophic lake (Crose Mere, Shropshire). All were restricted to the anaerobic hypolimnion which developed in summer. The various species formed maxima at different depths and times. With some of them (e.g. species of Thiopedia, Pelonema and Brachyarcus) growth was necessary to explain their development. In others (e. g. species of Pelodictyon and two colourless bacteria) vertical migrations might also have contributed to their development.     

Intracellular Bubble Formation: Differences in Gas Supersaturation Tolerances Between Tetrahymena and Euglena1

Cells of Tetrahymena pyriformis, T. thermophila, and Euglena gracilis were saturated with nitrogen gas at pressures up to 300 atm and rapidly decompressed. Damage was assessed by measuring post-decompression cell fragmentation or viability. Occurrence of intracellular bubbles was determined by cinephotomicrography performed during the decompression or by direct observations afterwards. The extreme gas supersaturations induced led to intracellular bubble formation and rupture in cells of Tetrahymena that contained food vacuoles, but only with supersaturations of 175 atm or higher; 225 atm left few cells intact. Bubbles were never observed in cells of Euglena or in Tetrahymena cells freed of food vacuoles, even when they were decompressed from substantially higher nitrogen supersaturations. Cells of Euglena were most resistant and were unaffected by supersaturations up to 250 atm.     

The buoyancy-providing role of gas vacuoles in an aerobic bacterium

The heterotrophic, freshwater bacterium Prosthecomicrobium pneumaticum Staley possesses sufficient gas vacuoles to render it buoyant at all stages of growth. Although the cells have a turgor pressure of about 300 kPa, there is no evidence that this pressure is important in causing collapse of the constituent gas vesicles. A mutant of the bacterium, which produced only 0.2% of the amount of gas vacuoles produced by the wild type, was isolated. It always sank in liquid culture. Wild type and mutant bacteria grew at the same rate in shaken culture, but in static culture the wild type, which floated to the liquid surface grew more quickly than the mutant, which sank. Other competition experiments suggested that the advantage gained in floating at the surface was simply that oxygen was more readily available there to this obligate aerobe. Similar advantages may benefit gas vacuolate forms in natural habitats.A second mutant was isolated which produced about 40% fewer gas vacuoles than the wild type in corresponding stages of growth, insufficient to provide buoyancy, and unlikely to be of selective value. The occurrence of this mutant suggests there may be duplication of the gas vacuole gene.Abbreviations T turbidity - PST pressure sensitive turbidity - kPa kilo-Pascals (100 kPa=1 bar)     

The ultrastructure of the marine blue green alga,Trichodesmium erythraeum,with special reference to the cell wall,gas vacuoles,and cylindrical bodies

Summary The marine blue green alga, Trichodesmium erythraeum, was studied with electron microscopy in an attempt to elucidate the structural basis for its rapid lysis when removed from its marine environment. In this connection, it was found that a thining of the electron-dense layer of the longitudinal wall at the site adjacent to transverse wall attachment was responsible for lysis. The underlying biochemical basis for this change has not been elucidated because of the extreme difficulties of maintaining and growing the alga in culture under defined conditions. Several other features of considerable interest also were found. Especially interesting is the very regular array of gas vacuoles in the form of a hollow cylinder which shields most of the photosynthetic system. It was suggested that the gas vacuoles might possibly function optically, having adaptive value in protecting the free-floating alga from excessive radiation. In addition, a detailed structure of the cylindrical bodies was presented, and its structure with the photosynthetic lamellae was compared. On the basis of sectoring to form fragments of double lamellar units from the cylindrical body which are identical in structure to the photosynthetic lamellae, it has been postulated that the cylindrical body may be the site of synthesis for the photosynthetic system in Trichodesmium erythraeum.     

Ultrastructural Characteristics of Three Chenopod Halophytes Lacking Salt Excretion Structures

Plants maintained in high soil salinity generally develop particular structures to either tolerate or survive such adverse environments. Excretion of excess ions by special salt glands or other similar structures is a well-known phenomenon for regulating the mineral content of many halophytes. However, the three chenopod halophytes of Suaeda inhabit high saline soils, yet they exhibit no signs of salt excretion structures. The current study has been undertaken to assess the structural attributes of these halophytes to reveal their cellular characteristics during growth in salt tolerance. Transmission and scanning electron microscopy, as well as ion chromatography, have been employed for the study. One of the most noticeable features uncovered was the epidermal cutinization shown to be heavy on the outer epidermis and characterized externally by thick wax plates. Numerous vesicles and membranous invagination in the vacuoles were common features within the mesophyll cytoplasm. Invaginations of the vacuolar and/or plasma membrane frequently formed secondary vacuoles which later became distinct, membrane-bound compartments. Significant accumulation of solid sodium chloride salts was well demonstrated in the vacuoles of air-dried epidermis. Finally, salt tolerance mechanisms in these Suaeda have been discussed with respect to other halophyte modifications that improve salt tolerance in various ways.     

Isolation of gas vacuole-less mutants of the blue-green alga Anabaenopsis raciborskii

From a bloom forming blue-green alga, Anabaenopsis raciborskii, spontaneous mutants, which had lost the ability to form gas vacuoles have been isolated; the mutant frequency was 4.8×10^-3. The filaments of gas vacuole-less mutants settled at the bottom of flasks in liquid culture media unlike the parent alga. The growth and nitrogen fixation were comparatively poor in the mutants.     

Effect of inhibitors and uncouplers on light-induced potential changes triggering photophobic responses

Light-energy absorption by Microcystis aeruginosa with and without gas vacuoles was observed, respectively by using an integrating sphere photometer. As far as the concentration of cell suspension of the order of 10⁶⁷ cells/ml in this work was concerned, the performance of gas vacuoles to shield incident light was most unlikely. Referring to a correlation secured by the integrating sphere photometer between light absorption and cell concentration of the suspension, a turbidostat culture of the blue-green alga demonstrated that the growth efficiency, Y _kJ defined as g cells harvested per kJ of light energy absorbed by the cells was nearly 0.004. This value of Y _kJ was almost the same as that of Spirulina platensis.Abbreviation vvm volume of air per volume of medium per min     

ELECTRON MICROSCOPY OF A CONTRACTILE-VACUOLE MUTANT OF CHLAMYDOMONAS MOEWUSII (CHLOROPHYTA) DEFECTIVE IN THE LATE STAGES OF DIASTOLE1

Electron microscopy of a “vacuole-less” mutant of Chlamydomonas moewusii Gerloff revealed the presence of small anterior vacuoles. These vacuoles behaved like contractile vacuoles in wild-type cells, but they were apparently unable to complete diastole and discharge their contents. When wild-type and mutant cells were incubated in hypertonic medium, small coated vacuoles persisted in the region where contractile vacuoles form. When these cells were transferred to hypotonic medium, the vacuoles appeared to fill and fuse to form larger vacuoles Shortly after the appearance of full expanded contractile vacuoles, collapsed vacuoles were observed in wild-type cells suggesting the completion of diastole and the onset of systole. In mutant cells, the initial steps of filling and fusion to form larger vacuoles apparent interactions of vacuoles with the plasma membrane were not observed. New contractile vacuoles accumulated around the nucleus. When fusion of the contractile vacuole with the plasma membrane was blocked by EGTA, a similar accumulation of large vacuoles occurred. Our observations suggest that the contractile-vacuole mutant of C. Moewusii produces vacuoles which can accumulate excess water as part of the mechanism of osmoregulation but which cannot complete diastole.     

Interactions Between Light and Gas Vacuoles in Halobacterium salinarium Strain 5: Effect of Ultraviolet Light

The potential light shielding by intracellular gas vacuoles in Halobacterium salinarium strain 5 was examined by looking at the ultraviolet light inactivation curves of both wild-type cells and mutants which are defective in the production of gas vacuoles. Whereas strains defective in gas vacuole production were slightly more sensitive to ultraviolet inactivation, no significant differences in ultraviolet sensitivity were seen, indicating that these subcellular inclusion bodies are not effective as light-shielding organelles. In addition, it was shown that ultraviolet light acts as a plasmid-curing agent in Halobacterium.