Insect UV-, and green-photoreceptor membranes studied by the freeze-fracture technique

Summary The membranes of the microvilli of UV- and green-photoreceptors of the ant Myrmecia gulosa have been studied with the freeze-fracture technique. Both inner fracture faces, the cytoplasmic P-face and the extracellular E-face, are covered by globular particles. The P-face particles appear to be randomly distributed, occasionally forming clusters. Their density is about 7,000/m², and their mean diameter is 8.5 nm. The E-face particles, however, are arranged in an ordered square pattern with a center-to-center spacing of 9 nm. The density and distribution of P- and E-face particles are the same in both the UV- and the green-photoreceptor membranes. No differences were found in the ultrastructural organization of photoreceptor membranes after dark or light adaptation. It is suggested that the P-face particles represent rhodopsin molecules.     

Analysis of desmosomal intramembrane particle populations and cytoskeletal elements: Detergent extraction and freeze-fracture

Summary We have examined sections and freeze-fracture replicas of Triton X-100 detergent-extracted desmosomes from murine palatal epithelium. After extraction of lipids as well as soluble proteins, a cytoskeletal framework remained which consisted of intermediate filaments, microfilaments, and intact desmosomal skeletons. Traversing filaments, which link the intermediate filaments to large intramembrane particles of the P-face, appeared undisturbed within the desmosomal skeletons. Compared to unextracted controls, extracted specimens displayed P- and E-face desmosomal intramembrane particles which were more fully exposed. A broad range of sizes and shapes was apparent for the P-face associated particles. E-face particles, some of which were exposed for the first time, were more homogeneous and generally smaller. Statistical data gathered from a large sample of P- and E-face particle diameters disclosed significant differences among the populations of the two faces. Both fracture faces of extracted desmosomal domains displayed a residual surface upon which the exposed particles seemed to remain lodged. The newly revealed structural features are presented in an hypothetical molecular model which provides for both vertical and horizontal stabilization of desmosomal subcomponents. The model may ultimately be relatable to emerging biochemical characterization.     

A freeze fracture and thin section study of intestinal cell membranes and intercellular junctions of a nematode, Ascaris

The microvillar and lumenal plasma membrane P-face of Ascaris intestinal cells is shown to be covered by relatively large (13 nm) particles at a fairly high density (1000/μm²), while the E-face has virtually none. The P-face of the lateral cell membranes, those separating the cells, have fewer and smaller (8 nm) particles. The intestinal cells are also shown to be connected by an apical complex of smooth septate and tricellular junctions similar to those found between some insect midgut cells. A periodic layer of tannic acid staining material is found on the cytoplasmic sides of the smooth septate junction, and when the intercellular space is filled with lanthanum, smoothly curved, 10 nm wide septal walls can be seen. Below the belt of septate junctions are a large number of gap junctions. These have closely packed arrays of particles on the P-face with some particle aggregates adhering to the closely packed pit arrays on the E-face.     

A novel adhering junction in the apical ciliary apparatus of the rotifer Brachionus plicatilis (Rotifera, Monogononta)

Cultures of the rotifer Brachionus plicatilis were examined with regard to their interepithelial junctions after infiltration with the extracellular tracer lanthanum, freeze-fracturing or quick-freeze deepetching. The lateral borders between ciliated cells have an unusual apical adhering junction. This apical part of their intercellular cleft looks desmosome-like, but it is characterized by unusual intramembranous E-face clusters of particles. Deep-etching reveals that these are packed together in short rows which lie parallel to one another in orderly arrays. The true membrane surface in these areas features filaments in the form of short ribbons; these are produced by projections, possibly part of the glycocalyx, emerging from the membranes, between which the electron-dense tracer lanthanum permeates. These projections appear to overlap with each other in the centre of the intercellular cleft; this would provide a particularly flexible adaptation to maintain cell-cell contact and coordination as a consequence. The filamentous ribbons may be held in position by the intramembranous particle arrays since both have a similar size and distribution. These contacts are quite different from desmosomes and appear to represent a distinct new category of adhesive cell-cell junction. Beneath these novel structures, conventional pleated septate junctions are found, exhibiting the undulating intercellular ribbons typical of this junctional type, as well as the usual parallel alignments of intramembranous rows of EF grooves and PF particles. Below these are found gap junctions as close-packed plaques of intramembranous particles on either the P-face or E-face. After freeze-fracturing, the complementary fracture face to the particles shows pits, usually on the P-face, arrayed with a very precise hexagonal pattern.     

Active zones and receptor surfaces of freeze-fractured crayfish phasic and tonic motor synapses

Deep and superficial flexor muscles in the crayfish abdomen are innervated respectively by small populations of physiologically distinct phasic and tonic motoneurons. Phasic motoneurons typically produce large EPSP's, releasing 100 to 1000 times more transmitter per synapse than their tonic counterparts, and exhibiting more rapid synaptic depression with maintained stimulation. Freeze-fracturing the abdominal flexor muscles yielded images of phasic and tonic synapse-bearing terminals. The two types of synapse are qualitatively similar in ultrastructure, displaying on the presynaptic membrane's P-face synaptic contacts recognized by relatively particle-free oval plaques which are often framed by the muscle fiber's E-face leaflet with its associated receptor particles. Situated within these presynaptic plaques are discrete clusters of large intramembrane particles, forming active zone (AZ) sites specialized for transmitter release. AZs of phasic and tonic synapses are similar: 80% had a range of 15–40 large particles distributed in either paired spherical clusters or in linear form, with a few depressions denoting sites of synaptic vesicle fusion or retrieval around their perimeters. The packing density of particles is similar for phasic and tonic AZs. The E-face of the muscle membrane displays oval-shaped receptor-containing sites made up of tightly packed intramembranous particles. Phasic and tonic receptor particles are packed at similar densities and the measured values resemble those of several other crustacean and insect neuromuscular junctions. Overall, the similarity between phasic and tonic synapses in the packing density of particles at their presynaptic AZs and postsynaptic receptor surfaces suggests similar regulatory mechanisms for channel insertion and spacing. Furthermore, the findings suggest that morphological differences in active zones or receptor surfaces cannot account for large differences in transmitter release per synapse.     

Preparation-dependent distribution of intramembranous particles in freeze-fracture replicas of the neuromuscular junction of the locust Schistocerca gregaria

Summary Freeze-fracture replicas of the neuromuscular junction were prepared from untreated retractor unguis muscles of the locust Schistocerca gregaria that were rapidly frozen by contact with a copper block cooled by liquid helium. These replicas were compared with others prepared from tissue following fixation with glutaraldehyde and cryoprotection in glycerol. Freeze-fracture of rapidly frozen tissue produced replicas of high quality with little evidence of tissue damage by ice crystals in the superficial layers. The gross fracturing characteristics of the neuromuscular junction were consistent with replicas from fixed and cryoprotected tissue; all of the membrane specializations were recognisable but with some alterations in infrastructure. In tissue replicas prepared using either method intramembranous particles in the presynaptic membrane were arranged in a bar-like array. The intramembranous particles of this presynaptic bar array of the rapidly frozen material were large and found on the E-face of the cleaved membrane. This contrasts with the P-face distribution of the comparable particles in muscles fixed in glutaraldehyde and cryoprotected in glycerol, in which they are also smaller and more numerous. This difference in partitioning between rapidly frozen, and fixed, cryoprotected nerve terminals is not found at cholinergic synapses and thus may reflect functional differences between the two types of junction.Indentations of the nerve-terminal membrane occur in replicas from rapidly frozen muscle as well as fixed and cryoprotected muscle suggesting they are not fixation or glycerol-induced artifacts. It is suggested from their position and size that these indentations are more likely to be part of a membrane retrieval system than exocytotic figures.This work was supported by an S.E.R.C. project grant to I.R.D.     

Structure of the Thylakoids and Envelope Membranes of the Cyanelles of Cyanophora paradoxa

The cyanelles of Cyanophora paradoxa Korsch. are photosynthetically active obligate endosymbionts in which phycobiliproteins serve as the major accessory pigments. Freeze-fracture electron micrographs of thylakoids in isolated cyanelles reveal long parallel rows of particles covering most of the E-face, while a more random particle arrangement is evident in some areas. The center-to-center spacing of particles within these rows is about 10 nanometers. Their mean diameter was measured at 9.4 nanometers. The particles on the P-face have a mean diameter of 7.2 nanometers. Thylakoids that retained nearly the full complement of phycobiliproteins (determined spectrophotometrically and by gel electrophoresis) were isolated from the cyanelles. In thin sections of these preparations, rows of disc-shaped phycobilisomes are evident on the surface of the thylakoids. The spacing of the rows of phycobilisomes corresponds to that of the rows of E-face particles (approximately 45 nanometers, center to center). The periodicity of the disc-shaped phycobilisomes within a row is 10 nanometers suggesting a one-to-one association between phycobilisomes and E-face particles.

In addition, visualization of the protoplasmic surface (PS) of isolated thylakoids by freeze-etch electron microscopy shows that rows of disc-shaped phycobilisomes are aligned directly above rows of particles exhibiting two subunits, presumably the P-surface projections of the 10-nanometer intramembrane particles. These observations, together with earlier studies indicating that the 10-nanometer E-face particles probably represent photosystem II (PSII) complexes, suggest that phycobilisomes are positioned on the thylakoid surface in direct contact with PSII centers within the thylakoid membrane.

The inner envelope membrane of the cyanelles, observed in freeze-fracture replicas, resembles cyanobacterial plasma membranes and is dissimilar to the chloroplast envelope membranes of red or green algae. The envelope of isolated cyanelles exhibits two additional layers: (a) a 5- to 7-nanometer-thick layer that lies adjacent to the inner membrane and which seems to correspond to the peptidoglycan layer of cyanobacteria; and (b) a layer external to the purported peptidoglycan layer that exhibits fracture faces similar to those of the lipopolysaccharide layer of gram negative bacteria. Our findings indicate that the supramolecular architecture of cyanelles differs only slightly from free-living cyanobacteria to which they are presumably related.

     

Sperm morphology and distribution of intramembranous particles in the sperm heads of selected freshwater teleosts

The morphology of spermatozoa and the distribution of intramembranous particles (IMPs) in sperm-head membranes in teleostean fish were examined ultrastructurally to clarify the presence of characteristic arrays (parallelogram or hexagon in packing) of IMPs. The following four species of fish were used: goldfish (Carassius auratus), loach (Misgurnus anguillicaudatus), flat bitterling (Acheilognatus rhombeus), sweetfish (Plecoglossus altivelis). It was demonstrated that spermatozoa of all these fish were devoid of an acrosomal structure in the anterior portion of the head. Spermatozoa had round heads in goldfish, loach and flat bitterling. Two centrioles (proximal centriole and basal body) were present and located adjacent to each other in all fish. The characteristic arrays of IMPs were found in spermatozoa of goldfish and flat bitterling. IMPs were more numerous on the P-face than on the E-face in all species. The present work showed that the characteristic arrays of IMPs were not common structures in spermatozoa of teleostean fish.     

Studies on membrane specializations in tentacular retractor muscle of the gastropod,Limax sp.

Retractor muscle cells of the optic tentacle of Limax sp. occur as a network beneath the epithelium. The cells are spindle-shaped, irregularly cross-striated, and they contain a large number of subsarcolemmal caveolae. Freeze-fracture images of the sarcoplasmic reticulum, caveolae and sarcolemma demonstrate distinct particulate organizations. Membranes of the sarcoplasmic reticulum contain typical 7–9 nm PF-face particles. The caveolae membranes contain linear, sometimes rhombic arrays of 12–15 nm EF-face particles. An extensive area of the sarcolemmal surface is occupied by caveolar invaginations. Other areas of the sarcolemma contain linear arrays of 7–9 nm PF-face particles and a few rhombic ordered, 7–9 nm PF-face particles. The results of this study are discussed relative to previous studies on paniculate arrays in muscle membranes. It is concluded that these highly specialized sarcolemmal and caveolar paniculate organizations may, in some way, reflect the large surface area changes which occur in these muscle cells.     

Membrane specializations in the paired spermatozoa of dytiscid water beetles

The paired spermatozoa of the dytiscid beetles Dytiscus marginalis and Hydaticus seminiger were studied by electron microscopy with the aim of examining whether the regions of the cell membrane in the zones of sperm conjugation might differ from other regions and to explore whether these cells had any other specialized domains of the cell membrane that could be recognized by the freeze-fracturing technique. The spermatozoa are conjugated along one side of the sperm head and proximal tail portion, called the ventral side. The cell membrane was seen to contain tightly packed intramembranous particles (IMPs) that were predominantly located in the external membrane face (the E-face). In thin sections the cell membrane had a ladder-like appearance at these regions and a specialized type of glycocalyx seen as a fluffy material containing granules. Other specialized membrane domains could also be recorded: a ribbon of particles in the protoplasmic face (P-face) of the dorsal side of the spermatozoon at the proximal tail portion and regularly arranged particle rows in the P-face of the distal tail portion. These domains corresponded to regions where the glycocalyx is prominent. Both the E-face and the P-face of the cell membrane were seen to contain numerous intramembranous particles, which suggests an active function for both membrane leaflets; this is in contrast to the situation in most cells where the particles are mainly in the P-face. The functions of the intramembranous particles in the specialized domains of the cell membrane remains unknown. Some particles may represent receptors or ion gates, others proteins with a mechanical function.     

Changes in thylakoid structure associated with the differentiation of heterocysts in the cyanobacterium, Anabaena cylindrica.

The thylakoids of vegetative cells of the filamentous cyanobacterium, Anabaena cylindrica, are capable of oxygen-evolving photosynthesis and contain both Photosystems I and II (PSI and PSII). The heterocysts, cells specialized for nitrogen fixation, do not produce oxygen and lack Photosystem II activity, the major accessory pigments, and perhaps the chlorophyll a associated with PSII. Freeze-fracture replicas of vegetative cells and of heterocysts reveal differences in the structure of the thylakoids. A histogram of particle sizes on the exoplasmic fracture face (E-face, EF) of vegetative cell thylakoids has two major peaks, at 75 and 100 A. The corresponding histogram for heterocyst thylakoids lacks the 100 A size class, but has a very large peak at about 55 A with a shoulder at 75 A. Histograms of protoplasmic fracture face (P-face, PF) particle diameters show single broad peaks, the mean diameter being 71 A for vegetative cells and 64 A for heterocysts. The thylakoids of both cell types have about 5600 particles/micrometers2 on the P-face. On the E-face, the density drops from 939 particles/micrometers2 on vegetative cell thylakoids to 715 particles/micrometers2 on heterocyst thylakoids. The data suggest that the 100 A E-face particle of vegetative cell thylakoids is a PSII complex. The 55 A EF particle of heterocysts may be part of the nitrogenase complex or a remnant of the PSII complex. The role of the 75 A EF particle is unknown. Other functions localized on cyanobacterial thylakoids, such as respiration and hydrogenase activity, must be considered when interpreting the structure of these complex thylakoids.     

Molecular structure of the axolemma of developing axons following altered gliogenesis in rat optic nerve

Axonal and axolemmal development of fibers from rat optic nerves in which gliogenesis was severely delayed by systemic injection of 5-azacytidine (5-AZ) was examined by freeze-fracture electron microscopy. In neonatal (0-2 days) rat optic nerves, all fibers lack myelin, whereas in the adult, virtually all axons are myelinated. The axolemma of neonatal premyelinated fibers is relatively undifferentiated. The P-fracture face (P-face) displays a moderate (approximately 550/micron 2) density of intramembranous particles (IMPs), whereas the E-fracture face (E-face) has few IMPs (approximately 125/micron 2) present. By 14 days of age, approximately 25% of the axons within control optic nerves are ensheathed or myelinated, with the remaining axons premyelinated. The ensheathed and myelinated fibers display increased axonal diameter compared to premyelinated axons, and these larger caliber fibers exhibit marked axonal membrane differentiation. Notably, the P-face IMP density of ensheathed and myelinated fibers is substantially increased compared to premyelinated axolemma, and, at nodes of Ranvier, the density of E-face particles is moderately high (approximately 1300/micron 2), in comparison to internodal or premyelinated E-face axolemma. In optic nerves from 14-day-old 5-AZ-treated rats, few oligodendrocytes are present, and the percentage of myelinated fibers is markedly reduced. Despite delayed gliogenesis, some unensheathed axons within 5-AZ-treated optic nerves display an increased axonal diameter compared to premyelinated fibers. Most of these large caliber fibers also exhibit a substantial increase in P-face IMP density. Small (less than 0.4 micron) diameter unensheathed axons within treated optic nerves maintain a P-face IMP density similar to that of control premyelinated fibers. Regions of increased E-face particle density were not observed. The results demonstrate that some aspects of axolemma differentiation continue despite delayed gliogenesis and the absence of glial ensheathment, and suggest that axolemmal ultrastructure is, at least in part, independent of glial cell association.     

Tight junctions in the choroid plexus epithelium. A freeze-fracture study including complementary replicas

The tight junctions of the choroid plexus epithelium of rats were studied by freeze-fracture. In glutaraldehyde-fixed material, the junctions exhibited rows of aligned particles and short bars on P-faces, the E-faces showing grooves bearing relatively many particles. A particulate nature of the junctional strands could be established by using unfixed material. The mean values of junctional strands from the lateral, third, and fourth ventricles of Lewis rats were 7.5 +/- 2.6, 7.4 +/- 2.2, and 7.5 +/- 2.4; and of Sprague-Dawley rats 7.7 +/- 3.4, 7.4 +/- 2.3, and 7.3 +/- 1.6. Examination of complementary replicas (of fixed tissue) showed that discomtinuities are present in the junctional strands: 42.2 +/- 4.6% of the length of measured P-face ridges were discontinuities, and the total amount of complementary particles in E-face grooves constituted 17.8 +/- 4.4% of the total length of the grooves, thus approximately 25% of the junctional strands can be considered to be discontinuous. The average width of the discontinuities, when corrected for complementary particles in E-face grooves, was 7.7 +/- 4.5 nm. In control experiments with a "tighter" tight junction (small intestine), complementary replicas revealed that the junctional fibrils are rather continuous and that the very few particles in E-face grooves mostly filled out discontinuities in the P-face ridges. Approximately 5% of the strands were found to be discontinuous. These data support the notion that the presence of pores in the junctional strands of the choroid plexus epithelium may explain the high transepithelial conductance in a "leaky" epithelium having a high number of junctional strands. However, loss of junctional material during fracturing is also considered as an alternative explanation of the present results.     

Changes in thylakoid structure associated with the differentiation of heterocysts in the cyanobacterium, Anabaena cylindrica

The thylakoids of vegetative cells of the filamentous cyanobacterium, Anabaena cylindrica, are capable of oxygen-evolving photosynthesis and contain both Photosystems I and II (PSI and PSII). The heterocysts, cells specialized for nitrogen fixation, do not produce oxygen and lack Photosystem II activity, the major accessory pigments, and perhaps the chlorophyll a associated with PSII. Freeze-fracture replicas of vegetative cells and of heterocysts reveal differences in the structure of the thylakoids. A histogram of particle sizes on the expolasmic fracture face (E-face, EF) of vegetative cell thylakoids has two major peaks, at 75 and 100 Å. The corresponding histogram for heterocyst thylakoids lacks the 100 Å size class, but has a very large peak at about 55 Å with a shoulder at 75 Å. Histograms of protoplasmic fracture face (P-face, PF) particle diameters show single broad peaks, the mean diameter being 71 Å for vegetative cells and 64 Å for heterocysts. The thylakoids of both cell types have about 5600 particles/μm² on the P-face. On the E-face, the density drops from 939 particles/μm² on vegetative cell thylakoids to 715 particles/μm² on heterocyst thylakoids. The data suggest that the 100 Å E-face particle of vegetative cell thylakoids is a PSII complex. The 55 Å EF particle of heterocysts may be part of the nitrogenase complex or a remnant of the PSII complex. The role of the 75 Å EF particle is unknown. Other functions localized on cyanobacterial thylakoids, such as respiration and hydrogenase activity, must be considered when interpreting the structure of these complex thylakoids.     

Developmental changes in P-face and E-face particle densities of Xenopus cardiac muscle plasma membrane

P- and E-face particle densities (PPD and EPD) were measured in electron micrographs of freeze-fractured cardiac sarcolemma from eight developmental stages of Xenopus laevis (stages 33/34 (33 post-otic somite embryos) to 66 (fully metamorphosed juvenile toad], using stereo-imaged replicas. We found striking progressive increases in PPD and EPD, most rapid between stages 33/34 and 37/38; that PPD was significantly greater than EPD at all stages; that both PPD and EPD of stereo-imaged replicas were about X2 greater than corresponding values not stereo-imaged; and that sarcolemmal PPD of late anuran embryonic and post-metamorphosis hearts were significantly greater than our previously determined PPD values for chick late embryo and adult mammalian sarcolemma. We suggest that PPD and EPD depend on how membrane particles segregate during freeze-fracture and on the relative contributions of membrane-spanning and non-membrane-spanning integral membrane protein complexes to each fracture face.     

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.     

Structure of the plasmalemma of human spermatozoa after treatment with antispermatozoa serum and concanavalin A

Human ejaculated spermatozoa were treated with antispermatozoa serum as well as with the same serum and concanavalin. A. At both experimental conditions clusters of intramembranous particles both on P-face and on E-face in the acrosomal and postacrosomal regions were seen. The clusters were with different form and size and were built up from different number of intramembranous particles. Large areas with single particles or in some cases devoid of these particles were found out.     

Freeze-fracture study of plasma membranes in wild type and daunorubicin-resistant Ehrlich ascites tumor and P388 leukemia cells

The plasma membrane is considered to play a major role in the development and maintenance of the multidrug resistance (MDR) phenotype, a role which may in part be mediated by an inducible 170 kD transmembrane protein (P-170). The present freeze-fracture study of plasma membranes of daunorubicin-resistant Ehrlich ascites and P388 leukemia cells demonstrated a significant increase in the density of intramembrane particles (IMP) in the P-face, but not the E-face, of resistant sublines compared with wild type cells. Furthermore, a three-dimensional histogram plot of the diameters of P-face IMPs in Ehrlich ascites tumor cells showed the emergence of a subpopulation of 9 × 11 nm IMPs not found in wild type cells. The size of these IMPs would be consistent with a MW of approximately 340 kD, thus indicating that P-170, shown to be present in both resistant cell lines by Western blot analysis and immunohistochemical staining, exists as a dimer in the plasma membrane. Incubation with the calcium channel blocker verapamil, in concentrations known to inhibit daunorubicin efflux in resistant cells, showed evidence of membrane disturbance in the form of IMP clustering in both wild type and resistant Ehrlich ascites tumor cells. However, incubation with daunorubicin itself did not alter the freeze-fracture morphology of the plasma membranes.     

Freeze-fracture study of plasma membranes in wild type and daunorubicin-resistant Ehrlich ascites tumor and P388 leukemia cells

The plasma membrane is considered to play a major role in the development and maintenance of the multidrug resistance (MDR) phenotype, a role which may in part be mediated by an inducible 170 kD transmembrane protein (P-170). The present freeze-fracture study of plasma membranes of daunorubicin-resistant Ehrlich ascites and P388 leukemia cells demonstrated a significant increase in the density of intramembrane particles (IMP) in the P-face, but not the E-face, of resistant sublines compared with wild type cells. Furthermore, a three-dimensional histogram plot of the diameters of P-face IMPs in Ehrlich ascites tumor cells showed the emergence of a subpopulation of 9 X 11 nm IMPs not found in wild type cells. The size of these IMPs would be consistent with a MW of approximately 340 kD, thus indicating that P-170, shown to be present in both resistant cell lines by Western blot analysis and immunohistochemical staining, exists as a dimer in the plasma membrane. Incubation with the calcium channel blocker verapamil, in concentrations known to inhibit daunorubicin efflux in resistant cells, showed evidence of membrane disturbance in the form of IMP clustering in both wild type and resistant Ehrlich ascites tumor cells. However, incubation with daunorubicin itself did not alter the freeze-fracture morphology of the plasma membranes.     

Molecular architecture of membranes involved in excitation-contraction coupling of cardiac muscle

Peripheral couplings are junctions between the sarcoplasmic reticulum (SR) and the surface membrane (SM). Feet occupy the SR/SM junctional gap and are identified as the SR calcium release channels, or ryanodine receptors (RyRs). In cardiac muscle, the activation of RyRs during excitation-contraction (e-c) coupling is initiated by surface membrane depolarization, followed by the opening of surface membrane calcium channels, the dihydropyridine receptors (DHPRs). We have studied the disposition of DHPRs and RyRs, and the structure of peripheral couplings in chick myocardium, a muscle that has no transverse tubules. Immunolabeling shows colocalization of RyRs and DHPRs in clusters at the fiber's periphery. The positions of DHPR and RyR clusters change coincidentally during development. Freeze-fracture of the surface membrane reveals the presence of domains (junctional domains) occupied by clusters of large particles. Junctional domains in the surface membrane and arrays of feet in the junctional gap have similar sizes and corresponding positions during development, suggesting that both are components of peripheral couplings. As opposed to skeletal muscle, membrane particles in junctional domains of cardiac muscle do not form tetrads. Thus, despite their proximity to the feet, they do not appear to be specifically associated with them. Two observations establish the identify of the structurally identified feet arrays/junctional domain complexes with the immunocytochemically defined RyRs/DHPRs coclusters: the concomitant changes during development and the identification of feet as the cytoplasmic domains of RyRs. We suggest that the large particles in junctional domains of the surface membrane represent DHPRs. These observations have two important functional consequences. First, the apposition of DHPRs and RyRs indicates that most of the inward calcium current flows into the restricted space where feet are located. Secondly, contrary to skeletal muscle, presumptive DHPRs do not show a specific association with the feet, which is consistent with a less direct role of charge movement in cardiac than in skeletal e-c coupling.