Partial purification of an intercalated disc-containing cardiac plasma membrane fraction

The sarcolemma of cardiac muscle cells contains a specialised junctional region, the intercalated disc which includes three types of intercellular junction, the macula and fascia adherens and the nexus or gap junction. To facilitate the isolation of these junctions a procedure for the partial purification from mouse hearts of a subcellular fraction containing the intercalated disc region of the sarcolemma was developed. This involved investigating methods of tissue disruption that preserve the integrity of the intercalated disc and minimise myofibrillar entrapment of organelles. Examination of the distribution of marker enzymes showed that relative to the homogenate the intercalated disc fraction prepared by sucrose density centrifugation was only enriched 1.5- to 3-fold in 5'-nucleotidase and (Na+ + K+)-ATPase activities, whereas mitochondrial and sarcoplasmic reticulum marker enzymes were low. The properties of the intercalated disc-containing fraction were compared with the vesicular sarcolemmal fractions devoid of junctional complexes prepared by other methods.     

THE ULTRASTRUCTURE OF CARDIAC DESMOSOMES IN THE TOAD AND THEIR RELATIONSHIP TO THE INTERCALATED DISC

The fine structure of desmosomes and intercalated discs in the toad heart is discussed. A definite relationship between the dense components of these structures and the dense region of the Z band is demonstrated. The dense region of the Z band characteristically widens at its approach to the plasma membrane, and often terminates beneath it in a distinct discoidal plaque. Cardiac desmosomes appear to be structures which result from the intimate apposition of plaques of Z band material. These desmosomes retain the Z band function as sites of attachment for myofilaments. The suggestion is made that rotation of a desmosome through 90° and splitting of filaments from the adjacent sarcomere could result in the formation of a simple step-like intercalated disc. Intermediate stages in this process are illustrated. Complex discs present in the toad probably represent the alignment of groups of simple discs produced by contractile forces. Possible physiologic functions of the disc and desmosome are discussed. Other morphologic features of toad cardiac cells include a distinct amorphous outer coat to the sarcolemma, a prominent N band, and a granular sarcoplasm with poorly developed reticulum.     

The ultrastructure of Blastocystis galli from chickens

The ultrastructure stages of Blastocystis galli were studied in chicken's intestine and in laboratory cultures. There were found morphological structures: surface coat (cell from chickens' intestine showed a very thick surface coat); cell membrane--there were some small electron-opaque deepening "pockets" on the membrane; inner membrane; endoplasmic reticulum with attached ribosomes, which present in the cytoplasm; all cells contained numerous of small vacuoles and large glycogen inclusions in cytoplasm; mitochondria with tubular cristae; nucleus with granules condensed chromatin; central vacuole; Golgi complex was represented by number of plates grouped in a pite; the cyst-like forms were surrounded by multilayered wall.     

Endocytosis in spermatids during spermiogenesis of the mouse

In the course of spermiogenesis in the mouse, spermatid cytoplasm contains numerous membrane pits, vesicles and membranous tubules which are frequently anastomosed. Pale and dense multivesicular bodies (MVB) and secondary lysosome-like structures are also present in the cytoplasm. In order to study the pathway of non-specific adsorptive endocytosis in spermatids, cationic ferritin (CF) was directly microinjected into the lumen of seminiferous tubules, and added to germinal cell culture. Tissue and cultures were fixed at various time intervals after injection. Two-5 hr after microinjection of tracer, CF was found simultaneously in vesicles, tubules, MVB and in lysosome-like bodies present in spermatids at all steps of spermiogenesis. Various membranous components of the Golgi medulla, and the innermost transsaccule of the Golgi cortex were labelled simultaneously. In primary cultures of spermatids, the vesicles contained the marker 5 min after its deposition; 10 min after deposition, CF was evident in tubules; at 30 min, CF was present in pale MVB; at 1 hr, the dense MVB and lysosome-like bodies were labelled. Finally, at 2 hr 30 min, vesicles and tubules of the Golgi medulla contained CF grains. Apparently spermatids are very active cells in the process of adsorptive endocytosis throughout spermiogenesis. Endocytosis in spermatids is probably one of the mechanisms involved in the uptake of material used to build up spermatozoa components. The strong labelling of the Golgi region probably point to its role in recycling endocytosed membranes.     

Ultrastructural studies on the heart of bony-fish larvae

The ultrastructure of the heart in 2 and 6 d old larvae of Melanogrammus aeglefinus and 1, 7, 14, and 21 d old larvae of Poecilia reticulata, is described. Additional studies were done on prenatal specimens of P. reticulata. In the atrium of M. aeglefinus the endocardium is separated from the muscle wall by a wide, electron lucent space, which probably contains cardiac jelly (Davis 1924). The myocardium is an 1 cell-thick layer in the atrium, whereas it consists of 2 to 4 cells in the ventricle. Cardiac trabeculae seem to be absent. The contractile material appears more developed at the endocardial side of the muscle wall than at the epicardial side. Thus, in the latter area the myofibrils are thin, few in number, and embedded in large amounts of free ribosomes. Often they radiate from a spot of electron dense material or an intercalated disc. Generally, intercalated discs, short nexuses and specific heart granules (Jamieson and Palade 1964) occur in ventricular as well as in atrial myocardial tissue. In P. reticulata cardiac jelly seems absent, whereas cardiac trabeculae occur regularly, particularly in the ventricle. The myofibrillar apparatus displays a nearly adult structure. However, in the ventricular wall, there occur spots and bands of intracellular, electron dense material at that sarcolemma facing the subepicardial space. Normally, myofibrils extend from this material into the cellular cytoplasm. Subsarcolemmal electron dense material was only scarcely seen in the atrial wall.(ABSTRACT TRUNCATED AT 250 WORDS)     

Observations on the Fine Structure of the Turtle Atrium

The general fine structure of the atrial musculature of the turtle heart is described, including; the nature of the sarcolemma; the cross-banded structure of the myofibrils; the character of the sarcoplasm, and the form and disposition of its organelles. An abundant granular component of the sarcoplasm in this species is tentatively identified as a particulate form of glycogen. The myocardium is composed of individual cells joined end to end at primitive intercalated discs, and side to side at sites of cohesion that resemble the desmosomes of epithelia. Transitional forms are found between desmosomes and intercalated discs. Both consist of a thickened area of the cell membrane with an accumulation of dense material in the subjacent cytoplasm. This dense amorphous component is often continuous with the Z substance of the myofibrils and may be of the same composition. The observations reported reemphasize the basic similarity between desmosomes and terminal bars of epithelia and intercalated discs of cardiac muscle. Numerous unmyelinated nerves are found beneath the endocardium. Some of these occupy recesses in the surface of Schwann cells; others are naked axons. No specialized nerve endings are found. Axons passing near the sarcolemma contain synaptic vesicles, and it is believed that this degree of proximity is sufficient to constitute a functioning myoneural junction.     

Microspore development inBrassica napus and the effect of high temperature on division in vivo and in vitro

Summary Brassica napus cv. Topas microspores isolated and cultured near the first pollen mitosis and subjected to a heat treatment develop into haploid embryos at a frequency of about 20%. In order to obtain a greater understanding of the induction process and embryogenesis, transmission electron microscopy was used to study the development of pollen from the mid-uninucleate to the bicellular microspore stage. The effect of 24 h of high temperature (32.5 °C) on microspore development was examined by heat treating microspore cultures or entire plants. Mid-uninucleate microspores contained small vacuoles. Late-uninucleate vacuolate microspores contained a large vacuole. The large vacuole of the vacuolate stage was fragmented into numerous small vacuoles in the late-uninucleate stage. The late-uninucleate stage contained an increased number of ribosomes, a pollen coat covering the exine and a laterally positioned nucleus. Prior to the first pollen mitosis the nucleus of the lateuninucleate microspore appeared to be appressed to the plasma membrane; numerous perinuclear microtubules were observed. Microspores developing into pollen divided asymmetrically to form a large vegetative cell with amyloplasts and a small generative cell without plastids. The cells were separated by a lens-shaped cell wall which later diminished. At the late-bicellular stage the generative cell was observed within the vegetative cell. Starch and lipid reserves were present in the vegetative cell and the rough endoplasmic reticulum and Golgi were abundant. The microspore isolation procedure removed the pollen coat, but did not redistribute or alter the morphology of the organelles. Microspores cultured at 25 °C for 24 h resembled late-bicellular microspores except more starch and a thicker intine were present. A more equal division of microspores occurred during the 24 h heat treatment (32.5 °C) of the entire plant or of cultures. A planar wall separated the cells of the bicellular microspores. Both daughter cells contained plastids and the nuclei were of similar size. Cultured embryogenie microspores contained electron-dense deposits at the plasma membrane/cell wall interface, vesicle-like structures in the cell walls and organelle-free regions in the cytoplasm. The results are related to embryogenesis and a possible mechanism of induction is discussed.Abbreviations B binucleate - LU late uninucleate - LUV late uninucleate vacuolate - M mitotic - MU mid-uninucleate - RER rough endoplasmic reticulum - TEM transmission electron micrograph     

Membrane protein trafficking through the common apical endosome compartment of polarized Caco-2 cells.

By raising monoclonal antibodies to the apical surface of Caco-2 cells we have identified a membrane protein (p100) that internalizes and recycles constitutively between the apical plasma membrane and endosomes in the apical cytoplasm. By applying tracers bound to the transferrin receptor, which internalizes and recycles back to the basolateral border, we demonstrate that the apical endosomes containing p100 include a subset of multivesticular bodies (MVB), which are also accessible to proteins arriving from the basolateral endosome. Tracers bound to EGF receptors and alpha-2-macroglobulin, which internalize from the basolateral border and are degraded, probably in lysosomes, also pass through the p100-containing MVB. These studies therefore suggest that the apical cytoplasm of Caco-2 cells contains a population of MVB capable of receiving membrane proteins trafficking in from both apical and basolateral borders and then routing them to a variety of cell surface and intracellular destinations. The differential distribution of apical and basolateral tracers within the 50-nm-diameter tubules connected to these p100-positive apical MVB suggests that the destination of proteins trafficking from the MVB back to apical and basolateral surfaces is determined by the tubules to which they gain access.     

Replication of an entomopoxvirus in two lepidopteran cell lines

Pseudaletia separata entomopoxvirus replicated in two lepidopteran cell lines, SIE-MSH-805-F and BM-N. Microscopic examination, and the virus passage tests, of infected cultures indicated that the virus replicated more readily in the former cell line. Virus release by exocytosis occurred in both cell lines. A sequence of virus morphogenesis in the cultured cells was described, based on electron microscopic observations of thin sections. The nucleus of infected cells contained spherical inclusions, and the cytoplasm contained virions, immature virus forms, spheroids, and spindles. A portion of the virions in the cytoplasm was occluded within spheroids, which were often associated with crystallogenic matrix. Virions acquired a coat prior to their occlusion.     

Diurnal changes of lysosome-related bodies in the crayfish photoreceptor cells

Summary The effect of illumination on the degradation of microvillar membrane in the invertebrate photoreceptor cell has been correlated with the appearance in the cytoplasm of certain distinct lysosome-related bodies. Three types of organelles were distinguished in the retinula cell cytoplasm of the crayfish, multivesicular bodies (MVB), both large (4.20-1.50 m) and small (1.49-0.30 m), combination bodies (CB), and lamellar bodies (LB). Under diurnal lighting conditions significant temporal differences were found in the appearance of these three classes of organelles in the retinula cell. Small MVB are present at a consistent level throughout most of the diurnal cycle but show peak numbers at 30 min after light onset and again after 6 h of dark adaptation. Large MVB increase significantly 1 h after light onset and remain elevated through 4 h in the light. After 4 h the large MVB decline gradually for the remaining light period. Combination bodies and LB do not begin to increase until 1 h after light onset and are at peak levels between 4 and 6 h into the light period. The minimum rhabdome diameter coincides with the peak levels of large MVB, CB, and LB. These data support the hypothesis that light causes microvillar membrane breakdown, resulting in the initial production of MVB which in turn undergo degradation to form CB and finally LB. This primary degradative response appears to be completed within the first 8 h of the light period.Supported by a grant from the National Science Foundation (BNS77-15803) and PHS Grant S05-RR-7031     

A three-dimensional study of organelle interrelationships in regenerating rat liver. 3. Organelles related to bile.

A number of cell structures are described which show a morphological relationship to the bile canaliculi. Two types of peribiliary vesicles are identified: osmication positive ones occurring between the bile canaliculi and the osmicated immature Golgi cisternae and probably deriving from the latter, and osmication negative ones related to MVB, on which they appear as buds. Small coated vesicles are seen attached to this second type. Large lacunae may originate from MVB, as suggested by the MVB-like internal vesicles they may contain. Some stay in luminal continuity with the bile canaliculi. Canalicular coated vesicles are seen as parts of the canalicular plasma membrane and free in the cytoplasm.     

A simplified method for the rapid isolation of cardiac intercalated discs

A simple and rapid method for the isolation of intercalated discs from a single rat heart is described. The outstanding features of this method are (i) a large quantity of starting material is not necessary, (ii) ultracentrifugation and separating gradient steps are not required, (iii) the disc fraction is relatively pure as verified by electron microscopy, and (iv) the starting tissue is rapidly homogenized into buffer, reducing possible damage to membrane structures after animal death. The fraction is rich in intercellular junctions, with gap junctions, fasciae adherentes and maculae adherentes all appearing well preserved. It should prove a useful starting base for further purification of these junctions and of sarcolemma from a specific portion of the cell surface membrane, namely the major area of structural interaction between adjacent cardiac cells.     

Structure of the novel membrane-coating material in proton-secreting epithelial cells and identification as an H+ATPase

Specialized proton-secreting cells known collectively as mitochondria-rich cells are found in a variety of transporting epithelia, including the kidney collecting duct (intercalated cells) and toad and turtle urinary bladders. These cells contain a population of characteristic tubulovesicles that are believed to be involved in the shuttling of proton pumps (H+ATPase) to and from the plasma membrane. These transporting vesicles have a dense, studlike material coating the cytoplasmic face of their limiting membranes and similar studs are also found beneath parts of the plasma membrane. We have recently shown that this membrane coat does not contain clathrin. The present study was performed to determine the structure of this coat in rapidly frozen and freeze-dried tissue, and to determine whether the coat contains a major membrane protein transported by these vesicles, a proton pumping H+ATPase. The structure of the coat was examined in proton-secreting, mitochondria-rich cells from toad urinary bladder epithelium by rapidly freezing portions of apical membrane and associated cytoplasm that were sheared away from the remainder of the cell using polylysine-coated coverslips. Regions of the underside of these apical membranes as large as 0.2 micron2 were decorated by studlike projections that were arranged into regular hexagonal arrays. Individual studs had a diameter of 9.5 nm and appeared to be composed of multiple subunits arranged around a central depression, possibly representing a channel. The studs had a density of approximately 16,800 per micron2 of membrane. Similar arrays of studs were also found on vesicles trapped in the residual band of cytoplasm that remained attached to the underside of the plasma membrane, but none were seen in adjacent granular cells. To determine whether these arrays of studs contained H+ATPase molecules, we examined a preparation of affinity-purified bovine medullary H+ATPase, using the same technique, after incorporation of the protein eluted from a monoclonal antibody affinity column into phospholipid liposomes. The affinity-purified protein was shown to be capable of ATP-dependent acidification. In such preparations, large paracrystalline arrays of studs identical in appearance to those seen in situ were found. The dimensions of the studs as well as the number per square micrometer of membrane were identical to those of toad bladder mitochondria-rich cells: 9.5 nm in diameter, 16,770 per micron2 of membrane.(ABSTRACT TRUNCATED AT 400 WORDS)     

Pinocytosis in the root cells of a salt-accumulating halophyte <Emphasis Type="Italic">Suaeda altissima</Emphasis> and its possible involvement in chloride transport

Ultrastructure of root cells in salt-accumulating halophyte Suaeda altissima (L.) Pall. was examined with transmission electron microscopy. Plants were grown hydroponically on nutrient media containing 3, 50, 250, and 500 mM NaCl. Some plants were exposed to hypersomotic salt shock by an abrupt increase in NaCl concentration from 50 to 400 mM. Growing S. altissima plants at high NaCl concentrations induced the formation of type 1 pinocytotic structures in root cells. Type 1 structures appeared as pinocytotic invaginations of two membranes, the plasmalemma and tonoplast. These invaginations into vacuoles gave rise to freely ‘floating’ multivesicular bodies (MVB) enclosed by a double membrane layer. The pinocytotic invaginations and MVB contained the plasmalemma-derived vesicles and membranes of endosome origin. The hyperosmotic salt shock led to formation of type 2 and type 3 pinocytotic structures. The type 2 structures were formed as pinocytotic invaginations of the tonoplast and gave rise to MVB in vacuoles. Unlike type 1 MVB, the type 2 MVB had only one enclosing membrane, the tonoplast. The type 3 structures appeared as the plasmalemma-derived vesicles located in the periplasmic space. The cytochemical electron-microscopy method was applied to determine the intracellular Cl^? localization. This method, based on sedimentation of electron-dense AgCl granules in tissues treated with silver nitrate, showed that the pinocytotic structures of all types contain Cl^? ions. The presence of Cl^? in pinocytotic structures implies the involvement of these structures in Cl^? transport between the apoplast, cytoplasm, and the vacuole.     

Nosema notabilis (Microsporidia), its ultrastructure and effect on the myxosporean host Ortholinea polymorpha

Nosema notabilis Kudo, 1939 produces chain-forming meronts with a dense cell coat in direct contact with the host cell cytoplasm. Cytoplasmic microtubules and membranaceous whorls could be observed in meront cytoplasm. Sporonts differ in that they have a thicker cell wall and more conspicuous endoplasmic reticulum (ER) cisternae. Sporoblasts have an externally ridged cell wall. Spores have an apically located anchoring disc, an isofilar polar tube with 6 to 9 turns and polyribosomal strands in the sporoplasm. Diplokarya occur in all stages. Heavily infected plasmodia of Ortholinea polymorpha (Davis, 1917) reveal marked pathological signs. The most prominent are reduction of surface projections and/or pinocytosis, inflated mitochondria with altered inner structures, affected vegetative nuclei, damage to generative cells and occurrence of various anomalous formations in the plasmodium cytoplasm. The damage may result in complete disintegration of the plasmodium. However, the development of the microsporidian is affected by a remarkably high percentage of teratological stages revealing membranaceous and tubular structures.     

Colocalization of aldolase and FBPase in cytoplasm and nucleus of cardiomyocytes

The protein exchange method, immunocytochemistry and the nuclear import of fluorophore-labeled enzymes were used to investigate the colocalisation of aldolase and FBPase in cardiomyocytes. The results indicate in vivo interaction of these two enzymes. In the cardiomyocyte cytoplasm, these enzymes were found to colocalise at the Z-line and on intercalated discs. The translocation of both enzymes through the nuclear pores was also investigated. The immunocytochemistry revealed the colocalisation of aldolase and FBPase in the heterochromatin region of cardiomyocyte nuclei. The Pearson's correlation coefficients, which represent the degree of colocalisation were 0.47, 0.52 and 0.66 in the sarcomer, the intercalated disc and the nucleus, respectively. This is the first report on aldolase and FBPase colocalisation in cardiomyocytes. Interaction of aldolase with FBPase, which results in heterologous complex formation, is necessary for glyconeogenesis to proceed. Therefore, this metabolic pathway in the sarcomer, in the intercalated disc as well as in the nucleus might be expected.     

FOWLER'S BACILLUS AND ITS PARASPORAL BODY

Fowler's bacillus is one of several organisms which form a non-viable inclusion or parasporal body during the process of sporulation. This body is globular and may be as large as or larger than the spore. Its position in the cell is not random; the spore is terminal and the body paracentral, lying between the spore and the remaining vegetative cell chromatin bodies. On completion of sporulation both spore and body are contained within an exosporium. The sequence in the development of the cell structures was followed in ultrathin sections of material fixed in permanganate. When sporulation is well advanced the body begins to grow from a single crystal, then presumably as a result of some disorientation in the growth process it develops as a multicrystalline body with the lattices orientated at different angles. When the body approximates the spore in size, a lamella coat is formed and an exosporium develops which eventually encircles the body and the spore. Other lamella systems microscopically similar to those surrounding the parasporal body develop free in the cytoplasm outside the exosporium. In both of these systems the number of lamellae is variable. The spore coat of Fowler's bacillus, consisting of an outer lamella layer and an inner unresolved amorphous layer has been found microscopically identical to the spore coat of B. cereus. In both organisms the lamella layer of the spore coat consists, in contrast to the other lamella systems, of a regular number of lamellae. Physiological tests would indicate that Fowler's bacillus is a variety of B. cereus.     

DIFFERENTIAL GERMINATION OF RAY AND DISC ACHENES IN HEMIZONIA INCRESCENS (ASTERACEAE)

The differential germination responses of ray and disc achenes of Hemizonia increscens (Asteraceae) were compared in field and laboratory investigations in order to gain insight into the ecological and evolutionary significance of heterocarpy. In the field, 200 ray and 200 disc achenes were placed in native, sterilized soil in a series of cleared, randomized, replicated plots. In a nearby plot a similar number of achenes were placed in plastic petri dishes in which high moisture conditions were maintained. Disc achene germination occurred under relatively minimal moisture conditions (<1 cm rainfall for 19 days) and relatively mild temperature regimes (21–7 C). Disc achene germination began three days after planting in the field plot and four days after they were put into the field petri dishes. In contrast, the onset of ray achene germination occurred 21 days after planting in the field plot and 19 days after planting in the field petri dishes. Averages of 2.05 and 2.71 disc achenes/day germinated in the field plot and field petri dishes, respectively. These contrasted with averages of 0.57 and 0.50 ray achenes/day germinated in the field plot and in the field petri dishes, respectively. A total of 67.5% and 69% disc achenes germinated in the field plot and the field petri dishes, but only 18% and 16.5% ray achenes germinated in the field plot and field petri dishes, respectively. Three separate treatments, using 100 ray and 100 disc achenes in each, were performed in laboratory growth chambers: 1) nicking the fruit coat, 2) excising the embryo, and 3) leaving the fruit coat intact. Onset of germination for all disc achene treatments occurred after three days. No significant differences were found among the three disc achene treatments in timing, rate, or germination percentage. All three disc treatments in the laboratory closely paralleled those for disc achenes in the field plots in time and germination percentage, but rates of germination were not as high. Germination of the nicked and excised ray achenes treatments began after four days, while germination of the untreated ray achenes began after 27 days. Untreated ray achenes in the laboratory paralleled the ray achenes in both field experiments in rate and germination percentage, but were delayed in time of germination. The nicked and excised ray achene treatments, however, were similar to the disc achene treatments in time of germination, and were not significantly different from disc achenes in rate of germination. These data suggest 1) that ray and disc achenes are markedly different in germination under identical conditions in field and laboratory experiments, and 2) this difference in germination response may be due to the thicker pericarp of the ray achenes.     

Ruminococcus flavefaciens Cell Coat and Adhesion to Cotton Cellulose and to Cell Walls in Leaves of Perennial Ryegrass (Lolium perenne)

Ruminococcus flavefaciens was shown to possess a prominent glycoprotein coat, which contained rhamnose, glucose, and galactose as its principal carbohydrates. Periodate-reactive carbohydrate occurred as a surface layer of the coat. The ruminococci adhered strongly by means of this coat to cotton cellulose and to cell walls in leaf sections of Lolium perenne L. (perennial ryegrass). The coat was diffuse at the point of contact so that the bacterial cell wall was in close contact with the substrate. Adhesion was influenced by the availability of damaged plant cell walls and by the cell wall type and occurred most rapidly to cell walls of the epidermis and sclerenchyma, followed by the phloem and mesophyll. Plaques of bacteria with filamentous coat extensions developed on all these tissues. The bacteria did not readily adhere to the walls of the bundle sheath cells or metaxylem or protoxylem vessels and did not adhere to the cuticle or chloroplasts. The epidermal and phloem cell walls were more rapidly digested than the walls of other cell types.