Two-dimensional electrophoretic analysis of secretory-granule,granule-membrane,and plasma-membrane proteins of rat parotid cells

Secretory granules and plasma membranes were isolated from rat parotid cells and characterized enzymatically and by electron microscopy. The proteins of the secretory granule membranes, the secretory granules and the plasma membranes were characterized by two-dimensional polyacrylamide gel electrophoresis and visualized by silver staining. The granule membrane contains 166 polypeptides of which only 26 are also present in the granule contents. The membrane proteins have isoelectric points between 4.75 and 6.45 and apparent molecular weights of 17 000 to 190 000 Daltons. The granule content proteins are surprisingly complex and contain 122 polypeptides with molecular weights of 11 000 to 138 000 and isoelectric points of 4.8 to 6.55. Thirteen of these peptides are present as major species. The plasma membrane contains 172 polypeptide species with molecular weights from 17 000 to 200 000 Daltons and isoelectric points of 5.0 to 6.8. Thirty-five of the plasma membrane proteins are also present in the secretory granule membranes indicating that the two membranes have some enzymatic or structural properties in common. Thus, secretory granule membranes and plasma membranes from parotid cells have a more complex polypeptide composition than has previously been shown for membranes of this type. The systems developed are suitable for the analysis of regulatory events such as protein phosphorylation, proteolytic processing, and other types of post-translational modifications that may be important to the secretory mechanism.     

Development of Intracellular Membrane Systems in the Columnar Epithelium of the Urinary Bladder of the Euryhaline Goby Gillichthys mirabilis

The membrane systems in "columnar cells" of the goby urinary bladder were studied after staining with ferrocyanide-reduced osmium tetroxide (K arnovsky ). In addition to the endoplasmic reticulum, two distinct systems of membranes were observed: 1) a vesiculotubular system made up of vesicles and short tubules located between the Golgi area and the apical membrane and 2) well-developed infoldings of the laterobasal plasma membrane which form either complete or fenestrated sheets. Adaptation to 5% seawater or prolactin exposure of seawater fish induces a proliferation of these membrane systems and, in particular, of the complete infoldings of the laterobasal plasma membrane. These observations suggest high activity of these bladder cells in osmoregulatory adjustments to hypotonic environments. The divergence between cytological and physiological indicators of activity is considered.     

Light microscope immunolocation of Bacillus thuringiensis kurstaki delta-endotoxin in the midgut and Malpighian tubules of the tobacco budworm, Heliothis virescens

Light microscope immunofluorescence was used to localize the membrane binding of Bacillus thuringiensis kurstaki 63-kDa delta-endotoxin in Heliothis virescens midgut and Malpighian tubules. Staining was observed along all exposed mucosal (apical microvillar) plasma membranes. Interpretation of the serosal (basal) plasma membrane staining was complicated because the basal lamina also stained. The results suggest that the toxin binds to all exposed plasma membranes without apparent specificity for particular membrane domains.     

Differences between non-specific and bio-specific, and between equilibrium and non-equilibrium, interactions in biological systems

The interaction forces between biological molecules and surfaces are much more complex than those between non-biological molecules or surfaces, such as colloidal particle surfaces. This complexity is due to a number of factors: (i) the simultaneous involvement of many different molecules and different non-covalent forces - van der Waals, electrostatic, solvation (hydration, hydrophobic), steric, entropic and 'specific', and (ii) the flexibility of biological macromolecules and fluidity of membranes. Biological interactions are better thought of as 'processes' that evolve in space and time and, under physiological conditions, involve a continuous input of energy. Such systems are, therefore, not at thermodynamic equilibrium, or even tending towards equilibrium. Recent surface forces apparatus (SFA) and atomic force microscopy (AFM) measurements on supported model membrane systems (protein-containing lipid bilayers) illustrate these effects. It is suggested that the major theoretical challenge is to establish manageable theories or models that can describe the spatial and time evolution of systems consisting of different molecules subject to certain starting conditions or energy inputs.     

Ultrastructural localization of glycoproteins in rabbit fibroblasts altered by Herpes simplex virus type 1 infection

The periodic acid-thiocarbohydrazide (SO2)--OsO4 method was used to examine the distribution of glycoproteins in rabbit fibroblast cells infected with Herpes simplex virus type 1. In non-infected cells, a low level of staining was seen over the plasma membrane and the membranes of the Golgi apparatus. At 17 hr post-infection, the intensity of reaction was increased to include not only a relatively heavy staining of the plasma membrane, including the numerous microvilli characteristic of infected cells, and of the newly proliferated Golgi membranes, but also the envelopes of intracytoplasmic and extracellular virions. A very faint but only occasional staining also was associated with the virus-induced reduplications of the inner nuclear membrane and the envelopes of associated enveloping nucleocapsids. We suggest that such differences in the intensity of staining may be related either to the amount of glycoproteins or to the sequential maturation of the viral glycoproteins. We also observed that the structurally modified portions of the Golgi membranes at the position where intracytoplasmic naked nucleocapsids bud into the Golgi cisternae usually exhibit a more intense reaction for glycoproteins than do the adjacent portions of the Golgi membranes. This supports the evidence for an envelopment of nucleocapsids in the cytoplasm, but it does not indicate whether this event obligatorily follows or only occasionally takes the place of the envelopment of nucleocapsids at the inner nuclear membrane. In either event, the envelopes of all mature virions exhibit a prominent reaction to glycoproteins.     

Identification of a 200-kD, brefeldin-sensitive protein on Golgi membranes

A mAb AD7, raised against canine liver Golgi membranes, recognizes a novel, 200-kD protein (p200) which is found in a wide variety of cultured cell lines. Immunofluorescence staining of cultured cells with the AD7 antibody produced intense staining of p200 in the juxtanuclear Golgi complex and more diffuse staining of p200 in the cytoplasm. The p200 protein in the Golgi complex was colocalized with other Golgi proteins, including mannosidase II and beta-COP, a coatomer protein. Localization of p200 by immunoperoxidase staining at the electron microscopic level revealed concentrations of p200 at the dilated rims of Golgi cisternae. Biochemical studies showed that p200 is a peripheral membrane protein which partitions to the aqueous phase of Triton X-114 solutions and is phosphorylated. The p200 protein is located on the cytoplasmic face of membranes, since it was accessible to trypsin digestion in microsomal preparations, and is recovered in approximately equal amounts in membrane pellets and in the cytosol of homogenized cells. Immunofluorescence staining of normal rat kidney cells exposed to the toxin brefeldin A (BFA), showed that there was very rapid redistribution of p200, which was dissociated from Golgi membranes in the presence of this drug. The effect of BFA was reversible, since upon removal of the toxin, AD7 rapidly reassociated with the Golgi complex. In the BFA-resistant cell line PtK1, BFA failed to cause redistribution of p200 from Golgi membranes. Taken together, these results indicate that the p200 Golgi membrane-associated protein has many properties in common with the coatomer protein, beta-COP.     

On the heterogeneous glycosylation of the membranes of the trans Golgi network in rabbit luteal cells

In rabbit luteal cells the transmost element (G2) of the Golgi apparatus bears cytochemical resemblances to the limiting membrane of lysosomes and it was suggested that lysosomal membranes may originate from the above element. But in the normal Golgi apparatus it cannot be made out whether the considered molecules are indeed membrane bound. Perfusing the rabbit ovary with buffer containing monensin or ammonium chloride allowed to vesiculate the trans Golgi network (G2-G1) selectively. Controls showed a well-preserved ultrastructure. Parts of the limiting membrane of the vacuoles derived from the transmost reticulum (G2) were spiny coated and carried an osmiophilic inner layer. They also showed a heavy precipitate for acid phosphatase (AcPase) and were strongly stained with phosphotungstic acid (PTA) at low pH. By neutralizing the acidic groups, involved in the PTA-staining, it was possible to show that the same membranes were more heavily glycosylated. The MvB's and the limiting membrane of lysosomes showed the same staining characteristics. The other membrane domains revealed a gradient in PTA staining and in AcPase activity. It is concluded that the trans Golgi network (G2-G1) is an acidic compartment. The presence of differentially glycosylated membranes reveals a sorting mechanism for membranous components. The highly glycosylated membrane stretches seem to be involved in endocytosis and in the formation of lysosomal membranes.     

India ink staining of proteins on nylon and hydrophobic membranes

India ink was found to be an acceptable stain for proteins blotted or dotted onto positively charged nylon or hydrophobic membranes. The hydrophobic membrane, Immobilon, was an outstanding matrix for binding proteins and displayed low levels of background staining. The least amount of protein detected by india ink staining was between 1.0 and 10 ng. India ink staining of proteins on nylon membranes is an easy, inexpensive, and quick method for the unequivocal detection of both standards and unknowns in the same blot. However, inks, ink concentrations, fixing conditions, staining times, pH, washing conditions, and membrane lots all need to be controlled to achieve maximum sensitivity for protein detection following india ink staining.     

Characterization of electric field-induced fusion in erythrocyte ghost membranes

Fusion has been reported to occur in a variety of membrane systems in response to the application of certain electric currents to the medium (Zimmermann, U., 1982, Biochim. Biophys. Acta., 694:227-277). The application of a weak but continuous alternating current causes the membranes in suspension to become rearranged into the "pearl-chain" formation. Fusion can then be induced by one or more strong direct current pulses that cause pore formation. This results in the conversion of individual membranes in the "pearl-chain" formation to a single membrane with one or more hourglass constrictions that form lumens which connect the cytoplasmic compartments. As the diameter of the lumens increases, the overall membrane shape grows to one large sphere. To further characterize electric field-induced fusion, experiments were conducted using the erythrocyte ghost as a model membrane, and a new combination of electrical circuit and fusion chamber that is simpler and improved over previous systems. All odd- shaped ghosts (collapsed or partly collapsed spherical shapes, echinocytes, discocytes, and stomatocytes) in 30 mM phosphate buffer was first converted to spherocytes and then fused with increasing yields by increasing the number of pulses. After fusion, the lateral diffusion of a fluorescent lipid soluble label (Dil) from labeled to unlabeled membranes was observed to occur both with and without the appearance in phase-contrast optics of distinct communication (lumens) between cytoplasmic compartments of the fused membranes. Connections between cytoplasmic compartments, however, were unmistakable with the instant transfer of a fluorescent water-soluble label (fluorescein isothiocyanate-dextran) from labeled to unlabeled cytoplasmic compartments upon fusion. Although pulses still resulted in the lateral diffusion of Dil to unlabeled membranes, the presence of glycerol in the medium strongly reduced the yield of lumens observable by phase- contrast optics in fusion events. The presence of glycerol also inhibited the conversion of membranes to spherocytes, but did not inhibit the lateral diffusion of Dil from labeled to unlabeled membranes.     

Electron Spin Resonance and Fluorescence Observations on Erythrocytes,Erythrocyte Membranes, 13762 Mat-A Ascites Adenocarcinoma Cells,and Their Membranes,Effects of Membrane Perturbations

Membranes from erythrocytes or MAT-A 13762 tumor cells were labeled with the fatty acid spin probe I(5,10) or ANS and examined by spin resonance (ESR) or fluorescence polarization in the presence or absence of the perturbants EDTA, trypsin, glutaraldehyde, and dodecylsulfate. Extraction of cell membranes with hypotonic EDTA produced fragments in which the order parameters and fluorescence polarization values increased. Fluorescence polarization values using membranes labeled with diphenylhexatriene showed an apparent increase in membrane fluidity. A large portion of both I(5,10) and both fluorescence probes coextract with the peripheral membrane proteins in both membrane systems. Paramagnetic quenching of tryptophan fluorescence with I(5,10) and the spectral characteristics of ANS in these membranes indicated further that significant amounts of both probes bind either at or near the protein-lipid interface or directly to protein moieties. Trypsinization of cell membranes, which preferentially cleaves the large cytoskeletal proteins, fragmented the membranes and reduced the ESR order parameter. Glutaraldehyde immobilized I(5,10) in both types of membranes. These studies suggest that the association of cytoskeletal proteins with the membrane does not have any pronounced, consistent effect on biophysical properties of the bilayer.

Attempts to apply these same probes to studies of the plasma membranes of intact cells were not successful because of the diffusion of the probes into the cells. These studies also point out some difficulties in using probe-group techniques to determine the nature of changes in bilayer structural parameters and emphasize the need for a better understanding of probe-group localization and behavior in such studies.     

The septate junction limits mobility of lipophilic markers in plasma membranes ofHydra vulgaris (attenuata)

Summary Fluorescent lipophilic probes were used to study the role of septate junctions in maintaining distinct apical and basolateral domains of plasma membranes in epithelial cells of hydra. In short-term experiments, a 16-carbon chain aminofluorescein probe (AFC₁₆) was localized to the apical plasma membranes of ectodermal and endodermal epithelial cells when presented in the culture medium or injected into the gastric lumen, but did not demarcate basolateral membranes. In longer term experiments, basolateral membranes were stained and the staining was independent of temperature conditions. A dual 18-carbon chain indocarbocyanine probe (DiIC₁₈) gradually diffused across the septate junction to label basolateral membranes at room temperature, but not at 4°C. DiIC₁₈ also filled and stained certain mounted nematocytes. The results indicate that in hydra, lipophilic probes may be limited in mobility within the membrane plane by the septate junctions in a manner similar to vertebrate tight junctions, and that apical membranes of mature nematocytes are differentially permeable.     

Binding and detection of glycosaminoglycans immobilized on membranes treated with cationic detergents

Immobilization of molecules on surfaces is used for preparative, quantitative, and qualitative studies. Glycosaminoglycans (GAGs) are strongly hydrophilic and negatively charged molecules that do not bind well to either polystyrene surfaces or hydrophobic blotting membranes. Hydrophobic membranes were derivatized with cationic detergents to become hydrophilic and positively charged. The ability of the polyvinylidene fluoride and nitrocellulose membranes to retain GAGs increased up to 12.8 microg per spot in the dot blot assay when the membrane was treated with a cationic detergent. Immobilized GAGs were stained with alcian blue, and the staining intensity was quantitated by scanning and densitometry. The derivatized membranes were used for solid-phase extraction of GAGs in blood plasma, urine, or cerebrospinal fluid. The detection sensitivity was equal for different types of GAGs but there was a slight negative interference from fibrinogen in blood plasma. The immobilized GAGs could also be released from the membrane using a nonionic detergent at high ionic strength. Recovery of different proteoglycan populations, separated by electrophoresis and detected by reversible staining with toluidine blue, was 70-100%.     

Monitoring population dynamics of the thermophilic Bacillus licheniformis CCMI 1034 in batch and continuous cultures using multi-parameter flow cytometry

Multi-parameter flow cytometry was used to monitor the population dynamics of Bacillus licheniformis continuous cultivations and the physiological responses to a starvation period and a glucose pulse. Using a mixture of two specific fluorescent stains, DiOC6(3) (3,3'-dihexylocarbocyanine iodide), and PI (propidium iodide), flow cytometric analysis revealed cell physiological heterogeneity. Four sub-populations of cells could be easily identified based on their differential fluorescent staining, these correspond to healthy cells (A) stained with DiOC6(3); cells or spores with a depolarised cytoplasmic membrane (B), no staining; cells with a permeabilised depolarised cytoplasmic membrane (C), stained with PI; and permeablised cells with a disrupted cytoplasmic membrane 'ghost cells' (D), stained with both DiOC6(3) and PI. Transmission electron micrographs of cells starved of energy showed different cell lysis process stages, highlighting 'ghost cells' which were associated with the double stained sub-population. It was shown, at the individual cell level, that there was a progressive inherent fluctuation in physiological heterogeneity in response to changing environmental conditions. All four sub-populations were shown to be present during glucose-limited continuous cultures, revealing a higher physiological stress level when compared with a glucose pulsed batch. A starvation period (batch without additional nutrients) increased the number of cells in certain sub-populations (cells with depolarised cytoplasmic membranes and cells with permeabilised depolarised cytoplasmic membranes), indicating that such stress may be caused by glucose limitation. Such information could be used to enhance process efficiency.     

Biocytin hydrazide--a selective label for sialic acids, galactose, and other sugars in glycoconjugates using avidin-biotin technology

Biocytin hydrazide (BCHZ), a new, water-soluble, long-chained, biotin-containing hydrazide, was synthesized and used for the selective nonradioactive detection of glycoconjugates. Procedures were developed for labeling glycoconjugates on blots. The method involves either chemical (periodate-induced) or enzymatic (via galactose oxidase) oxidation of glycoconjugates, the resultant aldehyde groups are then labeled with biocytin hydrazide, followed by interaction with an avidin-based enzyme probe. Since the biotin-containing reagent is a relatively small, charged molecule, the primary labeling step may be carried out on intact cells and on membrane preparations as well as on blotted samples. On blots, the labeling pattern was similar for both periodate- and galactose oxidase-induced biotinylation procedures. In contrast, periodate-induced labeling of either erythrocyte membranes or cells (prior to blotting) produced an altered labeling pattern. Combined enzyme-induced biotinylation of membranes or cells resulted in a pattern similar to that observed for the direct staining of blots. Using galactose oxidase on human erythrocyte membranes, the procedure was sensitive enough to selectively label the Band 3 lactosaminoglycoprotein.     

Membrane Asymmetry and Expression of Cell Surface Antigens of Micrococcus lysodeikticus Established by Crossed Immunoelectrophoresis

Crossed immunoelectrophoresis of Triton X-100-solubilized plasma membranes of Micrococcus lysodeikticus established the presence of 27 discrete antigens. Individual antigens were identified as membrane components possessing enzyme activity by zymogram staining procedures and by reactivity of certain antigens with a selection of four lectins in the crossed-immunoelectrophoresis (immunoaffinoelectrophoresis) system. Absorption experiments with intact, stable protoplasts and isolated membranes established the asymmetric nature of the M. lysodeikticus plasma membranes. Of the 14 antigens with determinants accessible solely on the cytoplasmic face of the membrane, four possessed individual dehydrogenase activities, and a fifth was identifiable as a component possessing adenosine triphosphatase (EC 3.6.1.3) activity. Evidence from absorption studies with isolated membranes suggested that antigens such as the adenosine triphosphatase complex were more readily accessible to reaction with antibodies than was succinate dehydrogenase (EC 1.3.99.1), for example. Twelve antigens were located on the protoplast surface as determined by antibody absorption, and the succinylated lipomannan was identified as a major antigen. At least five other antigens possessed sugar residues that interacted with concanavalin A. With the antisera generated to isolated membranes, there was no evidence suggesting that any of these antigens was not detectable on either surface of the plasma membrane. From absorption experiments with washed, whole cells of M. lysodeikticus, it was concluded that the immunogens on the protoplast surface were also detectable on the surface of the intact cell. However, some of the components such as the succinylated lipomannan appeared to be exposed to a greater extent than others. The cytoplasmic fraction from M. lysodeikticus was used as an antigen source to generate antibodies, and 97 immunoprecipitates were resolvable by crossed immunoelectrophoresis. In the cytoplasm-anticytoplasm reference immunoelectrophoresis pattern of precipitates, three of the immunoprecipitates unique to the cytoplasmic fraction were identifiable by zymogram staining procedures as catalase (EC 1.11.1.6), isocitrate dehydrogenase (EC 1.1.1.42), and polynucleotide phosphorylase (EC 2.3.7.8). The identification of membrane and cytoplasmic antigens (including the above-mentioned enzymes) provides a sensitive analytical system for monitoring cross-contamination and antigen distribution in cellular fractions.     

A high-affinity reversible protein stain for Western blots

We describe a reversible staining technique, using MemCode, a reversible protein stain by which proteins can be visualized on nitrocellulose and polyvinylidine fluoride (PVDF) membranes without being permanently fixed to the membrane itself. This allows subsequent immunoblot analysis of the proteins to be performed. The procedure is applicable only to protein blots on nitrocellulose and PVDF membranes. MemCode is a reversible protein stain composed of copper as a part of an organic complex that interacts noncovalently with proteins. MemCode shows rapid protein staining, taking 30s to 1 min for completion. The method is simple and utilizes convenient application conditions that are compatible with the matrix materials and the protein. The stain is more sensitive than any previously described dye-based universal protein staining system. The turquoise-blue-stained protein bands do not fade with time and are easy to photograph compared to those stained with Ponceau S. Absorbance in the blue region of the spectrum offers good properties for photo documentation and avoids interference from common biological chromophores. The stain on the protein is easily reversible in 2 min for nitrocellulose membrane and in 10 min for PVDF membrane with MemCode stain eraser. The stain is compatible with general Western blot detection systems, and membrane treatment with MemCode stain does not interfere with conventional chemiluminescent or chromogenic detection using horseradish peroxide and alkaline phosphatase substrates. The stain is also compatible with N-terminal sequence analysis of proteins.     

The absence of nidogen 1 does not affect murine basement membrane formation

Nidogen 1 is a highly conserved protein in mammals, Drosophila melanogaster, Caenorhabditis elegans, and ascidians and is found in all basement membranes. It has been proposed that nidogen 1 connects the laminin and collagen IV networks, so stabilizing the basement membrane, and integrates other proteins, including perlecan, into the basement membrane. To define the role of nidogen 1 in basement membranes in vivo, we produced a null mutation of the NID-1 gene in embryonic stem cells and used these to derive mouse lines. Homozygous animals produce neither nidogen 1 mRNA nor protein. Surprisingly, they show no overt abnormalities and are fertile, their basement membrane structures appearing normal. Nidogen 2 staining is increased in certain basement membranes, where it is normally only found in scant amounts. This occurs by either redistribution from other extracellular matrices or unmasking of nidogen 2 epitopes, as its production does not appear to be upregulated. The results show that nidogen 1 is not required for basement membrane formation or maintenance.     

Blue Dry Western: Simple, economic, informative, and fast way of immunodetection

The analysis by electrophoresis followed by transfer to membranes and immunodetection (Western blot) is probably the most popular technique in protein study. Accordingly, it is a time- and money-consuming procedure. Here a protocol is described where immunodetection can be accomplished in 30 min. This approach also allows permanent staining of proteins by Coomassie Blue R on the membrane before immune staining with clear background and high sensitivity.     

Secretion granules of the rabbit parotid gland. Isolation, subfractionation, and characterization of the membrane and content subfractions.

A fraction of secretion granules has been isolated from rabbit parotid by a procedure which was found to be especially effective in reducing contamination resulting from aggregation and/or cosedimentation of granules with other cell particulates. The fraction, representing 15 percent (on the average) of the total tissue amylase activity, was homogeneous as judged by electron microscopy and contaminated to exceedingly low levels by other cellular organelles as judged by marker enzymatic and chemical assays. Lysis of the granules was achieved by their gradual exposure to hypotonic NaHCO3, containing 0.5 mM EDTA. The content and the membranes separated by centrifugation of the granule lysate were characterized primarily by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis which indicated that the content was composed of a limited number of molecular weight classes of polypeptides of which three bands (having approximate mol wt 58,000, 33, 000, and 12,000) could be considered major components. The gel profile of the membrane subfraction was characterized by 20-30 Coomassie brilliant blue-staining bands of which a single species of mol wt 40,000 was the conspicuous major polypeptide. Two types of experiments employing gel electrophoretic analysis were carried out for identifying and assessing the extent of residual secretory protein adsorbed to purified granule membranes: (a) examination of staining and radioactivity profiles after mixing of radioactive secretion granule extract with nonradioactively labeled granule membranes and (b) comparison of gel profiles of secretion granule extract and granule membranes with those of unlysed secretion granules and secretory protein dischraged from lobules in vitro or collected by cannulation of parotid ducts, the last two samples being considered physiologic secretory standards. The results indicated that the membranes were contaminated to a substantial degree by residual, poorly extractable secretory protein even though assays of membrane fractions for a typical secretory enzyme activity (amylase) indicated quite through separation of membranes and content. Hence, detailed examination of membrane subfractions for residual content species by gel electrophoresis points to the general unity and sensitivity of this technique as a means for accurately detecting a defined set of polypeptides occurring as contaminants in cellular fractions or organelle subfractions.     

Redistribution of cell membrane probes following contraction-induced injury of mouse soleus muscle

Our aim was to study how mouse skeletal muscle membranes are altered by eccentric and isometric contractions. A fluorescent dialkyl carbocyanine dye (DiOC₁₈(3)) was used to label muscle membranes, and the membranes accessible to the dye were observed by confocal laser scanning microscopy. Experiments were done on normal mouse soleus muscles and soleus muscles injured by 20 eccentric or 20 isometric contractions. Longitudinal optical sections of control muscle fibers revealed DiOC₁₈(3) staining of the plasmalemma and regularly spaced transverse bands corresponding in location to the T-tubular system. Transverse optical sections showed an extensive reticular network with the DiOC₁₈(3) staining. Injured muscle fibers showed distinctively different staining patterns in both longitudinal and transverse optical sections. Longitudinal optical sections of the injured fibers revealed staining in a longitudinally-oriented pattern. No correlations were found between the abnormal DiOC₁₈(3) staining and the reductions in maximal isometric tetanic force or release of lactate dehydrogenase (P0.32). Additionally, no difference in the extent of abnormal staining was found between muscles performing eccentric contractions and those performing the less damaging isometric contractions. However, many fibers in muscles injured by eccentric contractions showed swollen regions with marked loss of membrane integrity and an elevated free cytosolic calcium concentration as observed in Fluo-3 images. In conclusion, a loss of cell membrane integrity results from contractile activity, enabling DiOC₁₈(3) staining of internal membranes. The resulting staining pattern is striking and fibers with damaged cell membranes are easily distinguished from uninjured ones.