Fine Structure of Bacillus subtilis : I. Fixation

The fine structure of Bacillus subtilis has been studied by observing sections fixed in KMnO₄, OsO₄, or a combination of both. The majority of examinations were made in samples fixed in 2.0 per cent KMnO₄ in tap water. Samples were embedded in butyl methacrylate for sectioning. In general, KMnO₄ fixation appeared to provide much better definition of the boundaries of various structures than did OsO₄. With either type of fixation, however, the surface structure of the cell appeared to consist of two components: cell wall and cytoplasmic membrane. Each of these, in turn, was observed to have a double aspect. The cell wall appeared to be composed of an outer part, broad and light, and an inner part, thin and dense. The cytoplasmic membrane appeared (at times, under KMnO₄ fixation) as two thin lines. In cells fixed first with OsO₄ solution, and then refixed with a mixture of KMnO₄ and OsO₄ solutions, the features revealed were more or less a mixture of those revealed by each fixation alone. A homogeneous, smooth structure, lacking a vacuole-like space, was identified as the nuclear structure in a form relatively free of artifacts. Two unidentified structures were observed in the cytoplasm when B. subtilis was fixed with KMnO₄. One a tortuous, fine filamentous element associated with a narrow light space, was often found near the ends of cells, or attached to one end of the pre-spore. The other showed a special inner structure somewhat similar to cristae mitochondriales.     

Permanganate Fixation of Plant Cells

In an evaluation of procedures explored to circumvent some of the problems of osmium tetroxide-fixation and methacrylate embedding of plant materials, excised segments of root tips of Zea mays were fixed for electron microscopy in potassium permanganate in the following treatment variations: unbuffered and veronal-acetate buffered solutions of 0.6, 2.0, and 5.0 per cent KMnO₄ at pH 5.0, 6.0, 6.7, and 7.5, and temperatures of 2–4°C. and 22°C. After fixation the segments were dehydrated, embedded in epoxy resin, sectioned, and observed or photographed. The cells of the central region of the rootcap are described. The fixation procedures employing unbuffered solutions containing 2.0 to 5.0 per cent KMnO₄ at a temperature of 22°C. gave particularly good preservation of cell structure and all membrane systems. Similar results were obtained using a solution containing 2.0 per cent KMnO₄, buffered with veronal-acetate to pH 6.0, and a fixation time of 2 hours at 22°C. The fixation procedure utilizing veronal-acetate buffered, 0.6 per cent KMnO₄ at 2–4°C. and pH 6.7 also gave relatively good preservation of most cellular constituents. However, preservation of the plasma membrane was not so good, nor was the intensity of staining so great, as that with the group of fixatives containing greater concentrations of KMnO₄. The other fixation procedures did not give satisfactory preservation of fine structure. A comparison is made of cell structures as fixed in KMnO₄ or OsO₄.     

PERMANGANATE FIXATION OF THE GOLGI COMPLEX AND OTHER CYTOPLASMIC STRUCTURES OF MAMMALIAN TESTES

Observations on the fine structure of KMnO₄-fixed testes of small mammals (guinea pig, rat, and mouse) reveal certain morphological differences between the spermatogenic and Sertoli cells which have not been demonstrated in the same tissue fixed with OsO₄. Aggregates of minute circular profiles, much smaller than the spherical Golgi vesicles, are described in close association with the Golgi complex of developing spermatids. Groups of dense flattened vesicles, individually surrounded by a membrane of different dimensions than that which bounds most of the other cell organelles, appear dispersed within the cytoplasm of some spermatogenic cells. Flattened vesicles of greater density than those belonging to the Golgi complex are reported confined to the inner Golgi zone of developing guinea pig spermatids between the Golgi cisternae and the head cap. The profiles of endoplasmic reticulum within spermatocytes appear shorter, wider, and more tortuous than those of Sertoli cells. Minute cytoplasmic particles approximately 300 A in diameter and of high electron opacity appear randomly disposed in some Sertoli cells. Groups of irregular-shaped ovoid bodies within the developing spermatids are described as resembling portions of cytoplasm from closely adjacent spermatids. Interpretation is presented regarding the fine structure of KMnO₄-fixed testes in view of what has already been reported for mammalian testes fixed in OsO₄.     

THE OCCURRENCE OF A SUBUNIT PATTERN IN THE UNIT MEMBRANES OF CLUB ENDINGS IN MAUTHNER CELL SYNAPSES IN GOLDFISH BRAINS

Observations additional to those previously reported (34) on boutons terminaux and club endings on Mauthner cell lateral dendrites, primarily as seen in sections of permanganate-fixed material, are described. Certain new findings on OSO₄-fixed endings are also included. The boutons terminaux are closely packed in the synaptic bed with ~ 100 to 150 A gaps between their contiguous unit membranes and a few interspersed glial extensions. Their synaptic membrane complexes (SMC) appear as pairs of unit membranes separated by ~ 100 to 150A clefts. They contain many vesicles and unoriented mitochondria, but no neurofilaments. The club endings after KMnO₄ fixation are, as after OSO₄ fixation (34), again seen surrounded by a layer of extracellular matrix material. These endings contain relatively few synaptic vesicles, a few unit membrane limited tubules ~ 300 A in diameter, and mitochondria oriented perpendicular to the SMC. Neurotubules and neurofilaments are not clearly seen. These components are also virtually absent in the Mauthner cytoplasm. No ribosomes are seen in the KMnO₄-fixed material. The unit membranes of the SMC of club endings show up clearly in essentially the same junctional relations described after formalin-OSO₄ fixation (34). In addition, the synaptic discs in transverse section show a central beading repeating at a period of ~ A associated with scalloping of the cytoplasmic surfaces. In oblique views, dense lines are seen repeating at a period of ~ 90 A. In frontal views a hexagonal array of close-packed polygonal facets is seen. These repeat at a period of ~ 95 A. Each has a central dense spot <25 A in diameter. Similar subunits are seen in the unit membranes of synaptic vesicles.     

A "MICROTUBULE" IN PLANT CELL FINE STRUCTURE

This paper reports an electron microscope examination of the cortices of some plant cells engaged in wall formation. Previous studies of similar material fixed in OSO₄ alone have disclosed discontinuities in the plasma membrane and other evidence of inadequate fixation. After glutaraldehyde, used as a fixative in this present study, the general preservation of cortical fine structure is greatly improved. This is shown, for example, by the first evidence of slender tubules, 230 to 270 A in diameter and of indeterminate length, in plant cells of this type. They have been found in the cortical regions of cells of two angiosperms and one gymnosperm, representing all the material so far studied following this method of fixation. The tubules are identical in morphology to those also observed here in the mitotic spindles of plant cells, except that the latter have a somewhat smaller diameter. It is noted that the cortical tubules are in a favored position to govern cytoplasmic streaming and to exert an influence over the disposition of cell wall materials. In this regard it may be of some significance that the tubules just beneath the surface of the protoplast mirror the orientation of the cellulose microfibrils of the adjacent cell walls.     

Spermatogenesis in animals as revealed by electron microscopy

Summary Testes of Bombyx mori Linné were fixed in buffered (pH 8.2) 1% OsO₄ or 3 % KMnO₄ and thin sections of the tissue, embedded in methacrylate or epoxy Epon resin, were studied under the electron or light microscope.At the late stage of differentiation of the spermatid, the nucleus shows an elongated conical contour, being composed of fine fibrillar elements. These fibrillar elements fixed in OsO₄ measure 100 to 130 Å in diameter, while those fixed with KMnO₄ are approximately 70 Å in diameter.It has been found for the first time in the spermiogenesis of the silkworm that two bands and a tubular structure develop in close proximity to one another and attached to the plasma membrane of the spermatid. The two bands fixed in OsO₄ are electron dense, but in the material fixed with KMnO₄, one of them, situated within the cell body, is as dense as that fixed in OsO₄, while the other, outside the cell body, is much less dense. These apparently novel apparatuses develop from the caudal nuclear region along the elongating spermatid, but the dense band intertwines with the acrosome in the apical region of the nucleus along the major axis of spermatid, while the tubular structure and the clear band reach far into the nutritive cell where the dense band and acre-some are not visible.A possible relationship between the tubular structure and the nutritive cell has been discussed.This study was supported by Grant GM-8327-03 from the United States Public Health Service.     

Straight Oso4 versus Glutaraldehyde-Oso4 In Sequence as Fixatives for the Granular Vesicles in Sympathetic Axons of the Rat Pineal Body

Pineal bodies were removed immediately after death from 6 rats: representing both sexes, and adult and 21-day postnatal ages; cut into 2 or 3 pieces, and subjected to experimental fixations at pH 7.3, 0-4 C as follows: 1-2 hr in 1% OsO₄, with veronal-acetate buffer of phosphate buffer; 3-4 hr in 3% or 6% glutaraldehyde in 0.1 M or 0.2 M phosphate buffer, with or without 1% sucrose. Specimens from OsO₄ were dehydrated, and embedded in epoxy resin; those from glutaraldehyde were allowed to soak in buffer for 12-16 hr, then transferred to 1% OsO₄ at 0-4 C for 2 hr, and embedded in the same manner as the ones fixed directly in OsO₄. Representative electron micrographs of postganglionic sympathetic endings were studied for the morphology and frequency of granular vesicles. No consistent difference was shown between vesicles fixed in OsO₄ buffered by phosphate or by veronal-acetate, nor was there any effect caused by the different concentrations used for the glutaraldehyde solution; however, vesicles fixed by the glutaraldehyde-OsO₄ sequence showed an enhancement in the graininess of their membranes, were slightly larger, and had a much larger dense core than those fixed by OsO₄ alone. After glutaraldehyde-OsO₄, granular vesicles showed a frequency of 81%, whereas after direct fixation in OsO₄, only 40% without significant change their number per unit area. Therefore, glutaraldehyde-OsO₄ seems to be more effective than straight OsO₄ for the demonstration of granular vesicles in the autonomic nervous system.     

Studies on reaction and binding of monoamines after fixation and processing for electron microscopy with special reference to fixation with potassium permanganate

Summary In the present paper certain properties of potassium permanganate (KMnO₄), a fixative used for electron microscopical investigations, have been studied in model test tube experiments and on tissues. Evidence was obtained that KMnO₄ reacts with different types of biogenic monoamines resulting in a formation of a precipitate. In addition, also various monoamine analogues, precursors and metabolites reacts with KMnO₄. The reaction taking place may be an oxidation-reduction-reaction in which KMnO₄ is reduced, probably mainly to manganese dioxide by hydroxyl groups of the amines and related compounds. This is corroborated by the fact that no reaction takes place between KMnO₄ and -phenylethylamine or amphetamine, two substances, which lack hydroxyl groups.Using labelled monoamines evidence was obtained that the amine partly is retained within the precipitate formed after the reaction with KMnO₄ and also in tissues fixed with KMnO₄, indicating a possibility to perform autoradiographic studies on KMnO₄ fixed tissue.Electron microscopic studies on tissues fixed under various conditions revealed that fixation with low concentrations (0.6 and 1.0%) of KMnO₄ and at high temperatures (about 20° C) leads to inferior results as to general morphology and as to the visualization of intraneuronal amine stores.Different types of permanganates were tested as fixatives. These results show that fixation with permanganates with monovalent metallic ions (K⁺, Li⁺ and Na⁺) give good results of comparable quality, whereas fixation with zinc permanganate results in seriously destroyed tissues. However, tissue fixed with calcium permanganate reveals very distinct membranes. Furthermore, evidence was obtained that fixation with high concentrations of LiMnO₄ (6 and 9%) and NaMnO₄ (6 and 9%) was more sensitive as to the demonstration of monoamines at the ultrastructural level as compared to 3% KMnO₄. Thus, with e.g. 6 and 9% LiMnO₄ small granular vesicles could be seen in slices from the caudate nucleus after incubation with -methyl-dopamine. This was not possible when using 3% KMnO₄ as a fixative.     

Development of the bacteroid in the root nodule of barrel medic (Medicago tribuloides Desr.) and subterraneum clover (Trifolium subterraneum L.)

Summary The development of the bacteriod is traced from thin sections of slices of nodules fixed in KMnO₄ and OsO₄. While in the infection thread the Rhizobium cell has the ultrastructure characteristic of gram-negative bacteria, with two unit membranes bounding a granular cytoplasm containing dense bodies, a nucleoid area and inclusion granules. A 10–12 fold increase in size, a loss of inclusion granules and the formation of a membrane envelope around each Rhizobium cell follows the dispersal of the rhizobia through the host cytoplasm. As the bacteriods develop there is a loss of fibrillar material from the nucleoid region and changes occur in the distribution of ribosome-like particles in both host and bacterial cells. When fully differentiated and presumably fixing nitrogen the bacteroids from the red zone of subterraneum clover nodules but not barrel medic have a well developed intra-cytoplasmic membrane system.     

FINE STRUCTURES OF INTRACYTOPLASMIC ORGANELLES OF MYCOBACTERIA

The fine structure of the intracytoplasmic organelles of mycobacteria was studied by means of electron microscopy of ultrathin sections. A well-preserved nuclear apparatus was obtained by fixation with OsO₄ in acetate-veronal buffer, containing calcium and tryptone, or in collidine-HCl buffer, followed by uranyl-acetate treatment and embedding in araldite. A low density nuclear region was filled with fine fibrils, 30 A in diameter, in parallel or concentric arrangement. A membranous organelle, tentatively designated as "lamellar structure," consists of unit membranes in lamellar arrangement. The thickness of each lamella in this membranous organelle coincides with that of the three-layered cytoplasmic membrane Moreover, the continuity of this unit membrane with the cytoplasmic membrane was demonstrated.     

The legume Rhizosphere

Summary Examination of the root surfaces of Medicago tribuloides Desr. with phase contrast microscopy or electron microscopy using thin sections revealed the presence of a layer of material outside the root surface. In thin sections of KMnO₄ fixed roots this layer was composed of a thin electron dense layer, an electron dense granular matrix of varying width and an enclosing electron dense membrane. After inoculation with an effective Rhizobium strain, rhizobia were found aggregated in a definite zone adjacent to the root surface when either living roots were examined by phase microscopy or thin sections by electron microscopy. This layer was also found in inoculated and uninoculated roots of Trifolium fragiferum and T. pratense. The bacteria were packed with inclusion granules and lay enclosed by a membrane layer adjacent to the granular matrix seen in uninoculated roots. The ultrastructural organisation of root hairs is essentially similar to that of other differentiated root cells. The replicated surface of the uninoculated root hair wall is largely amorphous with a few sculptured portions resembling a cuticle layer. The inoculated root hair wall often shows areas of exposed, open microfibrillar meshwork with rhizobia sitting on the microfibrils. The rhizobia resemble a flagellated, coccoid swarmer form of Rhizobium which is found in the barrel medic rhizosphere.     

Improved structural preservation in freeze-substituted sporidia ofUstilago avenae—a comparison with low-temperature embedding

Summary In the present study the cellular fine structure of freeze-substituted sporidia of the phytopathogenic fungusUstilago avenae is investigated by means of thin-section electron microscopy. A conventional embedding method using Spurr's low viscosity resin is compared with the recently developed methacrylate mixtures Lowicryl^® K 4 M and HM 20 resin. Generally, freeze-substitution yields improved preservation of fine structural details of the fungus compared to previously applied conventional fixation methods. Using double fixation during freeze-substitution prior to conventional embedding the fungal membrane system (plasmalemma, endoplasmic reticulum), organelles (mitochondria, nucleus etc.) and other cytoplasmic features (ribosomes, cytoskeleton) appear well resolved and smoothly contoured. Aldehyde fixed and Lowicryl embedded sporidia ofU. avenae resemble these double fixed fungal specimens fairly closely. The complete low-temperature preparation produces visualization of distinct cellular details although contrast reversal of cellular membranes (er, mitochondria etc.) is sometimes observed. In particular, fine structure resolution is enhanced in Lowicryl HM 20 embedded fungal cells. This is due also to significant improvement in staining of the cellular membranes, cytoskeleton (microfilaments and microtubules) and Golgi apparatus-like areas, using tannic acid. In case of the fungusU. avenae, freeze-substitution in combination with mild glutaraldehyde fixation and final low-temperature embedding in HM 20 resin prove suitable for improved preservation of cellular ultrastructure.Abbreviations cw cell wall - cy cytoplasm - FS freeze-substitution - FS-A GA/OsO₄ freeze-substitution and Spurr's LV-embedding - FS-B GA freeze-substitution and Lowicryl K 4 M LT-embedding - FS-C GA freeze-substitution and Lowicryl HM 20 LT-embedding - go Golgi apparatus-like body - GA glutaraldehyde - g glycogen deposit - l lipid droplet - LT low temperature - Lowicryl LT-embedding Lowicryl low-temperature embedding - Lowicryl LT-resin Lowicryl low-temperature resin - MeOH methanol - mf microfilament - mt microtubule - m mitochondrion - mvb multivesicular body - ne nuclear envelope - np nuclear pore - npl nucleoplasm - nu nucleolus - n nucleus - OsO₄ osmium tetroxide - pl plasmalemma - pr polyribosomes - Pb-citrate Reynolds' lead citrate - r ribosome - RT room temperature - rer rough endoplasmic reticulum - Spurr's LV-embedding Spurr's low viscosity embedding - Spurr's LV-resin Spurr's low viscosity resin - t tonoplast - Uac uranyl acetate - v vacuole     

The desmosome: Fine structural studies with freeze-fracture replication and tannic acid staining of sectioned epidermis

Desmosomes of larval and post-metamorphic newt epidermis have been studied by freeze-fracture replication both with and without prior glutaraldehyde fixation. Characteristic particles of a diameter (70-130 A) similar to that of typical membrane associated particles are found clustered on the exposed internal faces of adherent desmosomal membranes. They remain attached to the B-face in unfixed material, but occupy the desmosomal A-face after fixation. Membrane associated particles of nondesmosomal surfaces are found predominantly on the A-face in both fixed and unfixed epidermis. Suitably oriented replicas of unfixed desmosomes reveal profiles of apparent fine filaments extending from the region of tonofilament loops through the desmosomal plaque to traverse the cytoplasmic leaflet of the plasmalemma. They can be traced onto the B-face. Their position correlates to fine linear profiles noted in tannic acid/glutaraldehyde-fixed and sectioned desmosomes. The possibility that these represent a mechanism for anchorage of tonofilaments to the plaque and to the membrane is discussed. These and other fine structural features are compared and contrasted to the properties of hemidesmosomes described in the preceding report.     

THE FINE STRUCTURE OF CHONDROCOCCUS COLUMNARIS : I. Structure and Formation of Mesosomes

Cells of Chondrococcus columnaris were sectioned and examined in the electron microscope after fixation by two different methods. After fixation with osmium tetroxide alone, the surface layers of the cells consisted of a plasma membrane, a dense layer (mucopeptide layer), and an outer unit membrane. The outer membrane appeared distorted and was widely separated from the rest of the cell. The intracytoplasmic membranes (mesosomes) appeared as convoluted tubules packaged up within the cytoplasm by a unit membrane. The unit membrane surrounding the tubules was continuous with the plasma membrane. When the cells were fixed with glutaraldehyde prior to fixation with osmium tetroxide, the outer membrane was not distorted and separated from the rest of the cell, structural elements (peripheral fibrils) were seen situated between the outer membrane and dense layer, and the mesosomes appeared as highly organized structures produced by the invagination and proliferation of the plasma membrane. The mesosomes were made up of a series of compound membranes bounded by unit membranes. The compound membranes were formed by the union of two unit membranes along their cytoplasmic surfaces.     

The intracytoplasmic membrane system of the bacteroids of subterraneum clover nodules (Trifolium subterraneum L.)

Summary A vesicular intracytoplasmic membrane system is demonstrated in bacteroids from the leghaemoglobin filled zone of effective Trifolium subterraneum nodules after KMnO₄ and OsO₄ fixation. The system appears to be present in all mature bacteroids from this zone, and is derived from tubular invaginations of the plasma membrane of the bacteriod. A granular substance similar to the bacteroid cytoplasm is found in the vesicles which are bounded by a tripartite membrane approximately 80 Å wide, while the interspace between the vesicles is filled with a material of similar appearance to that in the interspace between bacteroid plasma membrane and cell wall.     

Evaluation of fixative composition,fixative storage,and fixation duration on the fine structure and volume of root-cell nucleoli

Summary— The effect of various combinations of three fixative compositions (glutaraldehyde buffered in veronal acetate, cacodylate, and piperazine-N, N'-bis[2-ethanesulfonic acid]—PIPES], two fixative storage times (fresh vs 6 weeks), and two fixation durations (3 h vs 9 days) on nucleolar fine structure and nucleolar volume in three root cell-types of oat seedlings (Avena sativa L, cv Seger) were evaluated. All fixatives show overall good preservation of fine structure. Nucleolar components are distinct and well delineated in cells fixed in solutions buffered with either cacodylate or veronal acetate; the components are more condensed when preserved in fixative buffered with PIPES. Nucleolar volume is greatest in cells fixed in the cacodylate fixative, and smallest in those preserved in the PIPES fixative. Among the treatments tested, the PIPES fixative evidently best maintains nucleolar volume. Distracting particulate deposits are abundant on nuclei and nucleoli in cells preserved in the veronal-acetate fixative. Contrary to common assumptions, aging of buffered fixative at room temperature for 6 weeks seems to affect neither the general quality of cellular preservation nor the pH of the fixatives, although nucleolar volume is reduced by such treatment. Long-period fixation (9 days) results in destruction of membrane integrity (mitochondria, plastids, ER), and shrinkage of organelles from the cytoplasm. Nucleolar volume is reduced with prolonged fixation.     

Intracellular distribution of mitochondria after geotropic stimulation of the oat coleoptile

The number of mitochondria is greater in the bottom than in the top of cells in geotropically stimulated oat (Avena sativa) coleoptiles. In the avascular tip and outer epidermis of subapical regions this difference occurs only in the lower tissues. These inequalities are found both in the KMnO₄⁻ and in the glutaraldehyde-fixed tissues; however, they are significant only in the former. Also, the number of mitochondria scored is consistently lower when the tissues were fixed in KMnO₄. These results suggest that mitochondria undergo a small degree of sedimentation after geostimulation, a redistribution reduced by the slower fixation with glutaraldehyde. Differences in mitochondrial number begin later than those in the amyloplast and the Golgi apparatus after geotropic stimulation. The cells in the avascular-tip region (a region having an important role in geotropism) have two to three times more mitochondria than the subapical cells.     

SOME DYNAMIC ASPECTS OF THE NUCLEAR ENVELOPE

Nuclei of frog oocytes were isolated, fixed in OsO₄ or KMnO₄, and washed. Nuclear envelopes were then dissected off, placed on grids, and air-dried for electron microscopy. Envelopes from immature oocytes at the stage of beginning yolk deposition were compared with those from mature oocytes. Envelopes from the immature stage had "pores" whose annuli contained more material and showed central globules in the center much more frequently than envelopes from mature eggs. Annuli and central globules had similar appearance and fixation properties, suggesting similar chemical composition. After fixation with KMnO₄, residual densities suggested that "pore" diaphragms are much more variable in thickness or composition in the younger stages. Envelopes of the immature oocytes had about 40 per cent more "pores" per unit area than mature envelopes. In crowding together, the "pores" tended to assume geometrical packing arrays in the young envelope, showing minimum center-to-center spacings of about 1530 A. Since the actual discontinuities in the membranes of the envelope are only about 950 A in diameter, this minimum distance of approach suggests that adjacent formations of the nuclear surface are associated with "pore" structure and perhaps set their limiting spacing distances. If this is true, then it can be deduced that "pore"-associated structures of the nuclear surface are probably circular in outline and about 1500 A in diameter. Isotopically labeled lysine was administered to intact, growing oocytes for 1 to 4 hours and the envelopes were subsequently isolated and fixed. Autoradiography of entire envelopes showed little or no incorporation of lysine into proteins, as compared with small fragments from other parts of the cell of roughly comparable mass. It was concluded that the isolated envelope, as seen in the electron micrographs, does not synthesize or turn over lysine-containing protein at a high rate.     

Flagellar surface morphology ofChlamydomonas eugametos

Summary Flagellar surfaces ofChlamydomonas eugametos fixed in OsO₄ were compared to those fixed in glutaraldehyde by scanning and transmission electron microscopical techniques. They appeared to be quite different. Flagella fixed in OsO₄ had a pleated membrane that vesiculated when Tris was present during fixation. Flagella fixed in glutaraldehyde of various concentrations and buffer strengths, appeared to have disc-bearing appendages which were continuous with the membrane. On growing flagella the appendages occurred after 2 hours and they increased in size and complexity during the next 3 to 4 hours. No structural differences were observed between flagella of vegetative cells and those of gametes. Mating competence of gametes appeared to parallel the development of mature appendage-bearing flagella. The possibility that membrane vesicles, found in the cell culture medium, are derived from the flagellar appendages is discussed.     

Bacterial mesosomes: Real structures of artifacts?

The ultrastructural study of membrane organization in gram-positive bacteria related to the OsO₄ fixation conditions revealed that large, complex mesosomes are observed only when the bacteria are subjected to an initial fixation with 0.1% OsO₄ in the culture broth, as in the prefixation step of the Ryter-Kellenberger procedure. Evidence was obtained suggesting that the large mesosomes are produced by this prefixation. The kinetic study of the membrane morphological alterations occurring during the prefixation of Bacillus cereus with 0.1% OsO₄ in the culture broth showed that the amount of mesosome material increases linearly from zero to a maximum observed at 1.7 min of prefixation and that at about this time a maximum is reached for the number of mesosomes per unity of cell area and for the average individual mesosome area. The large mesosomes observed in gram-positives fixed by the complete Ryter-Kellenberger procedure would be the result of the membrane-damaging action of 0.1% OsO₄. Such damaging action was deduced from the observation that 0.1% OsO₄ quickly lyses protoplasts and induces a quick and extensive leakage of intracellular K⁺ from B. cereus and Streptococcus faeculis. In support of that interpretation is the observation that in bacteria subjected to several membrane-damaging treatments, mesosome-like structures are seen after three different fixation procedures. In bacteria initially fixed with 1% OsO₄, 4% OsO₄ or 2.5% glutaraldehyde, no large, complex mesosomes are observed, small and simple invaginations of the cytoplasmic membrane being present. The size of these minute mesosomes is inversely proportional that causes of fixation. Uranyl acetate was found among the studied fixatives the one to the rate the least damage to bacterial membranes. This fixative satisfactorily preserves protoplasts. In bacteria initially fixed with uranyl acetate no mesosomes were found. The results of the present work throw serious doubts on the existence of mesosomes, both large and small, as real structures of bacterial cells. It is proposed that a continuous cytoplasmic membrane without infoldings (mesosomes) would be the real pattern of membrane organization in gram-positives.