Aldehyde-fixed Cells Research Articles

Development of a green reversibly photoswitchable variant of Eos fluorescent protein with fixation resistance.

Superresolution microscopy determines the localization of fluorescent proteins with high precision, beyond the diffraction limit of light. Superresolution microscopic techniques include photoactivated localization microscopy (PALM), which can localize a single protein by the stochastic activation of its fluorescence. In the determination of single-molecule localization by PALM, the number of molecules that can be analyzed per image is limited. Thus, many images are required to reconstruct the localization of numerous molecules in the cell. However, most fluorescent proteins lose their fluorescence upon fixation. Here, we combined the amino acid substitutions of two Eos protein derivatives, Skylan-S and mEos4b, which are a green reversibly photoswitchable fluorescent protein (RSFP) and a fixation-resistant green-to-red photoconvertible fluorescent protein, respectively, resulting in the fixation-resistant Skylan-S (frSkylan-S), a green RSFP. The frSkylan-S protein is inactivated by excitation light and reactivated by irradiation with violet light, and retained more fluorescence after aldehyde fixation than Skylan-S. The qualities of the frSkylan-S fusion proteins were sufficiently high in PALM observations, as examined using α-tubulin and clathrin light chain. Furthermore, frSkylan-S can be combined with antibody staining for multicolor imaging. Therefore, frSkylan-S is a green fluorescent protein suitable for PALM imaging under aldehyde-fixation conditions.

Primary cultured neuronal networks and type 2 diabetes model mouse fatty liver tissues in aqueous liquid observed by atmospheric SEM (ASEM): Staining preferences of metal solutions

Neural networking, including axon targeting and synapse formation, is the basis of various brain functions, including memory and learning. Diabetes-mellitus affects peripheral nerves and is known to cause fatty liver disease. Electron microscopy (EM) provides the resolution required to observe changes in fine subcellular structures caused by such physiological and pathological processes, but samples are observed in vacuum. Environmental capsule EM can directly observe cells in a more natural aqueous environment, but the size-limited capsules restrict cell culturability. The recently developed atmospheric scanning electron microscope (ASEM) has an open, 35 mm sample dish, allowing the culture of primary cells, including neurons, on the electron-transparent film window fabricated in its base. The system’s inverted scanning electron microscope observes aldehyde-fixed cells or tissues from below through the silicon nitride film; the optical microscope located above allows direct correlation of fluorescence labeling. To observe fixed biological samples, damage due to low dose electron radiation is minimized in three ways. First, knock on damage that pushes out atoms is decreased by the low accelerating voltage of 10–30 kV. Second, increased radical generation due to the decreased acceleration voltage is countered by the addition of a radical scavenger, glucose or ascorbic acid, to the sample solution. Third, the large volume (max. 2 ml) of aqueous buffer surrounding the sample has a high specific heat capacity, minimizing the temperature increase caused by irradiation. Using ASEM, we have developed protocols for heavy metal staining in solution to selectively visualize intracellular structures. Various EM staining methods served as a starting point. Uranyl acetate preferably stains proteins and nucleic acid, and prior tannic acid treatment enhances membranes. Osmium tetroxide is suggested to enhance lipids, especially oil droplets. Imaging primary-culture neurons stained with platinum blue or uranyl acetate revealed growth cones, synapses, and 50–500 nm spines, together with neurite backbones and their associated structures. Correlative microscopy with immuno-fluorescence labeling suggested that these were mainly microtubule associated objects; some showed signs of a fission process and were, thus, possibly mitochondria. Liver tissue excised from the ob/ob type 2 diabetes model mouse, was stained with osmium tetroxide and observed using ASEM. Swollen bright balls occupied a large area of the cytoplasm and could be distinguished from vacuoles, suggesting that they are oil droplets. In some of the images, oil-like droplets were pressing surrounding structures, including sinusoids, significant for blood circulation in the liver. Based on these studies, ASEM combined with metal staining methods promises to allow the study of various mesoscopic-scale phenomena of cells and tissues immersed in natural aqueous environment in the near future. The quick nature of ASEM could facilitate not only the precise imaging for neuroscience but also the diagnosis of fatty liver disease and related diseases.

Sterol dynamics during endocytic trafficking in Arabidopsis.

Sterols are lipids found in membranes of eukaryotic cells. Functions of sterols have been demonstrated for various cellular processes including endocytic trafficking in animal, fungal, and plant cells. The ability to visualize sterols at the subcellular level is crucial to understand sterol distribution and function during endocytic trafficking. In plant cells, the polyene antibiotic filipin is the most extensively used tool for the specific detection of fluorescently labeled 3-β-hydroxysterols in situ. Filipin can to some extent be used to track sterol internalization in live cells, but this application is limited, due to the inhibitory effects filipin exerts on sterol-dependent endocytosis. Nevertheless, filipin-sterol labeling can be performed on aldehyde-fixed cells which allows for sterol detection in endocytic compartments. This approach can combine studies correlating sterol distribution with experimental manipulations of endocytic trafficking pathways. Here, we describe step-by-step protocols and troubleshooting for procedures on live and fixed cells to visualize sterols during endocytic trafficking. We also provide a detailed discussion of advantages and limitations of both methods. Moreover, we illustrate the use of the endocytic recycling inhibitor brefeldin A and a genetically modified version of one of its target molecules for studying endocytic sterol trafficking.

Influence of aldehyde fixation on the morphology of endosomes and lysosomes: quantitative analysis and electron tomography.

Cryoimmobilization is regarded as the most reliable method to preserve cellular ultrastructure for electron microscopic analysis, because it is both fast (milliseconds) and avoids the use of harmful chemicals on living cells. For immunolabelling studies samples have to be dehydrated by freeze-substitution and embedded in a resin. Strangely, although most of the lipids are maintained, intracellular membranes such as endoplasmic reticulum, Golgi and mitochondrial membranes are often poorly contrasted and hardly visible. By contrast, Tokuyasu cryosectioning, based on chemical fixation with aldehydes is the best established and generally most efficient method for localization of proteins by immunogold labelling. Despite the invasive character of the aldehyde fixation, the Tokuyasu method yields a reasonably good ultrastructural preservation in combination with excellent membrane contrast. In some cases, however, dramatic differences in cellular ultrastructure, especially of membranous structures, could be revealed by comparison of the chemical with the cryofixation method. To make use of the advantages of the two different approaches a more general and quantitative knowledge of the influence of aldehyde fixation on ultrastructure is needed. Therefore, we have measured the size and shape of endosomes and lysosomes in high-pressure frozen and aldehyde-fixed cells and found that aldehyde fixation causes a significant deformation and reduction of endosomal volume without affecting the membrane length. There was no considerable influence on the lysosomes. Ultrastructural changes caused by aldehyde fixation are most dramatic for endosomes with tubular extensions, as could be visualized with electron tomography. The implications for the interpretation of immunogold localization studies on chemically fixed cells are discussed.

Antibodies to the estrogen receptor-alpha modulate rapid prolactin release from rat pituitary tumor cells through plasma membrane estrogen receptors.

Antibodies (Abs) raised against the estrogen receptor-alpha (ERalpha) were used to investigate the role of ERalpha proteins located at the plasma membrane in mediating the rapid, estrogen-stimulated secretion of prolactin (PRL) from rat pituitary GH(3)/B6/F10 cells. Exposure of the cells to 1 nM 17beta-estradiol (E(2)) significantly increased PRL release after 3 or 6 min. When ERalpha Abs that bind specifically to ERalpha but are too large to diffuse into cells were tested for activity at the cell membrane, Ab R4, targeted to an ERalpha hinge region sequence, increased PRL release in a time- and concentration-dependent fashion. Ab H151, directed against a different hinge region epitope, decreased PRL release and blocked the stimulatory action of E(2). Abs raised against the DNA binding domain (H226) or the carboxyl terminus (C542) were not biologically active. When each Ab was examined for recognition of ERalpha on the cell surface by immunocytochemistry, all except H151 generated immunostaining in aldehyde-fixed cells. In live cells, however, Ab H151 but not Ab R4 blocked the membrane binding of fluorescently tagged E(2)-BSA. Overall, the data indicate that plasma membrane ERalpha proteins mediate estrogen-stimulated PRL release from GH(3)/B6/F10 cells. These results may also convey information about conformationally sensitive areas of the membrane form of ERalpha involved in rapid, nongenomic responses to estrogens.

Visualization of kinetochores and analysis of their refractility in crane-fly spermatocytes after aldehyde fixation.

Glutaraldehyde and formaldehyde were used to fix crane-fly spermatocytes for observation with differential interference contrast (DIC) microscopy. In aldehyde-fixed cells, kinetochores exhibit contrast not normally observed in living cells. Although the mechanism underlying this result is not understood, the visualization of kinetochores as distinct refractile objects opens the way for analysis of unstained kinetochores with the light microscope. The analysis of kinetochore refractility reported in this paper is made possible by the finding that the refractility of chromosomes in formaldehyde-fixed cells decreases as the concentration of formaldehyde is increased. In 4% formaldehyde, the refractility of chromosomes is matched with that of its surround, chromosomes appear invisible, and kinetochores may be analyzed as if chromosomes were not present. Kinetochores were imaged with DIC optics, and then digital image analysis was performed. Gray-level scans through the highlight and shadow of an individual kinetochore parallel to the axis of shear resulted in a curve having a slope proportional to the DIC optical path gradient. Curves from autosomal kinetochores imaged in anaphase had slopes approximately one-half those recorded at metaphase under identical optical conditions. By contrast, kinetochore thicknesses (defined as the distance between the peak and the valley of a gray-level scan) at those two stages were not significantly different. These data suggest a loss of dry mass from autosomal kinetochores during anaphase. Neither the refractility nor thickness of lagging sex kinetochores varied as autosomes went through anaphase. The conclusion drawn from these findings is that the decreased refractility of autosomal kinetochores in anaphase is movement-related.

Efficient immunocytochemical labeling of leukocyte microtubules with FluoroNanogold: an important tool for correlative microscopy.

We tested the immunoprobe FluoroNanogold (FNG) for its utility as an immunocytochemical labeling reagent. This immunoprobe consists of a 1.4-nm gold particle to which a specific Fab' fragment and a fluorochrome are conjugated. We employed the microtubules (MTs) of human phagocytic leukocytes as a model system for testing the usefulness of FNG as a secondary antibody for immunocytochemistry. We show that these fluorescently labeled ultrasmall immunogold particles are very efficient for labeling MTs in these cells. The signal from FNG can be detected directly by fluorescence microscopy or indirectly by other modes of optical microscopy and electron microscopy, after silver-enhancement of the gold. The spatial resolution of immunolabeled MTs obtained with FNG and silver enhancement was comparable to that of conventional immunofluorescence detection. Colloidal gold (5-nm and 10-nm in diameter), on the other hand, failed to label MTs in cells prepared in a similar manner. This difference in labeling was due in large part to greater penetration of 1.4-nm gold into aldehyde-fixed cells than either 5-nm or 10-nm gold particles. The fluorescent 1.4-nm immunoprobe was shown to be an important new tool for general use in correlative microscopy.

Application of the novel nucleic acid dyes YOYO-1, YO-PRO-1, and PicoGreen for flow cytometric analysis of marine prokaryotes.

Novel blue light-excited fluorescent dyes for nucleic acids (YOYO-1, YO-PRO-1, and PicoGreen) were tested on cultures of Escherichia coli and of a variety of marine prokaryotes. Results of flow cytometric DNA analyses were compared with those obtained with the UV-excited dyes bis-benzimide Hoechst 33342 or 4', 6-diamidino-2-phenylindole (DAPI). YOYO-1, YO-PRO-1, and PicoGreen can be used only on aldehyde-fixed cells and need to be supplemented with cofactors such as potassium, citrate, or EDTA. They are highly sensitive to ionic strength. Consequently, seawater culture samples cannot be stained directly with these dyes and require at least a 10-fold dilution with distilled water to obtain reliable fluorescence signals. After treatment with RNase, coefficients of variation for the G1 peak of the DNA distributions of the different strains tested with YOYO-1 or PicoGreen indicated in general an improvement over Hoechst 33342 staining. These novel dyes can be used to enumerate prokaryotic cells by flow cytometry, as demonstrated with E. coli. However, their sensitivity to ionic strength makes them unsuitable for cell cycle analysis in natural samples.

Expression of the Amyloid Precursor Protein of Alzheimer's Disease on the Surface of Transfected HeLa Cells

The principal component of the amyloid which accumulates in Alzheimer's Disease brain is a 4-kDa βA4 fragment of the amyloid precursor protein (APP). Although APP has the structural features of an integral transmembrane receptor, there has been limited evidence for expression of APP at the plasma membrane. The function of APP and related molecules is unknown. Using rabbit antisera to purified human brain APP, surface labeling of APP is demonstrable in HeLa cells transfected with the APP695 isoform. Indirect immunofluorescence indicates the presence of APP at the surface of unfixed or aldehyde-fixed cells; preembedding immunoelectron microscopy using 5- or 1-nm gold particles and silver enhancement confirms plasma membrane labeling as well as labeling within intracellular membrane vesicles. Immunolabeling of unfixed cells at 4°C followed by incubation at 37°C shows APP within endocytic vesicles. Transfected HeLa cells with prominent surface APP were larger with more extensive microvilli than nonimmunoreactive HeLa cells. This is consistent with the postulated role of APP as a mediator of cell surface adhesion and membranematrix stabilization.

S-100-Immunoreactive Giant Macrophages in Lymphoid Tissues of the Guinea Pig

Giant cells containing S-100 protein of the lymphoid tissues in the guinea pig were studied by immunohistochemistry using S-100 antiserum. S-100-immunoreactive giant cells were dendritic in shape, contained one or two irregular-shaped, euchromatic nuclei, phagosomes of various diameter, numerous mitochondria and microfilaments in the perikaryon, and extended cell processes free of cell organelles. These cells predominantly lined the superficial cortex facing the subcapsular sinus, were less numerously scattered in the medulla of lymph nodes and located at the marginal zone of the spleen. They also stained with S-100 alpha monoclonal antiserum and showed active phagocytosis for aldehyde-fixed red cells or colloidal carbon in the popliteal lymph node and spleen. S-100-immunoreactive giant cells also appeared in the corticomedullary zone of the thymus and in the interfollicular area of the Peyer's patches of the gut. Small sinus macrophages, which exhibited active phagocytosis for colloidal carbon but were less active for red cells in the popliteal lymph node and spleen, were not stained with S-100 antiserum. These findings indicate that S-100-immunoreactive giant cells of the lymph node and spleen are a subpopulation of macrophages different from S-100-negative cells of the small type.

Integrated morphometrical and electron energy loss image analysis in cytochemistry

One aspect of enzyme cytochemistry is, whether all macrophage lysosomal hydrolytical enzymes are present in an active form, or are activated upon stimulation. Integrated morphometrical and chemical analysis has been chosen as a tool to illucidate that cytochemical problem. Mouse peritoneal resident macrophages have been used as a model for this complicated integration of morphometrical and element-related data. Only aldehyde-fixed cells were treated with three cytochemical reactions to detect different enzyme activities within one cell (for details see [1,2]). The enzyme-related precipitates anticipated to be differentiated, were:(1).lysosomal barium and sulphur from aryl sulphatase activity,(2).lysosomal cerium and phosphate from acid phosphatase activity and(3).platinum/di-amino-benzidine( D A B) complex from endogenous peroxidase activity.

A simple two-step labeling procedure for ultrastructural localization of cell surface anionic sites.

We propose a new method for ultrastructural localization of cell surface anionic sites. The method consists of sequential interaction of aldehyde-fixed cells with a polycationic reagent, poly-L-lysine (PL), followed by secondary interaction with a negatively charged marker, ferritin. By use of PL of low molecular weight (4000) on aldehyde-pre-fixed red blood cells and macrophages, the reaction resulted in binding of ferritin particles to cell surface anionic sites with a density distribution resembling that of cationized ferritin (CF). The density of the attached ferritin molecules increased in direct correlation with the MW of PL used. The primary PL interaction can be carried out at low pH (less than 2), thus restricting the labeling mainly to membrane-bound sialyl residues.

An actin network is present in the cytoplasm throughout the cell cycle of carrot cells and associates with the dividing nucleus.

We have studied the F-actin network in cycling suspension culture cells of carrot (Daucus carota L.) using rhodaminyl lysine phallotoxin (RLP). In addition to conventional fixation with formaldehyde, we have used two different nonfixation methods before adding RLP: extracting cells in a stabilizing buffer; inducing transient pores in the plasma membrane with pulses of direct current (electroporation). These alternative methods for introducing RLP revealed additional features of the actin network not seen in aldehyde-fixed cells. The three-dimensional organization of this network in nonflattened cells was demonstrated by projecting stereopairs derived from through-focal series of computer-enhanced images. F-actin is present in interphase cells in four interconnected configurations: a meshwork surrounding the nucleus; thick cables in transvacuolar strands and deep in the cytoplasm; a finer network of bundles within the cortical cytoplasm; even finer filaments that run in ordered transverse array around the cell periphery. The actin network is organized differently during division but it does not disappear as do the cortical microtubules. RLP stains a central filamentous cortical band as the chromatin begins to condense (preprophase); it stains the mitotic spindle (as recently shown by Seagull et al. [Seagull, R. W., M. Falconer, and C. A. Weerdenburg, 1987, J. Cell Biol., 104:995-1004] for aldehyde fixed suspension cells) and the cytokinetic apparatus (as shown by Clayton, L., and C. W. Lloyd, 1985, Exp. Cell Res., 156:231-238). However, it is now shown that an additional network of F-actin persists in the cytoplasm throughout division associating in turn with the preprophase band, the mitotic spindle, and the cytokinetic phragmoplast.

Requirements for entry of poliovirus RNA into cells at low pH.

HeLa S3 cells were protected against infection by poliovirus type I by the presence of monensin and N,N'-dicyclohexylcarbodiimide (DCCD), compounds elevating the pH of acidic intracellular compartments. The protection was fully overcome by exposing the cells to pH 5.5 and lower, and at approximately pH 6.1 it was reduced by half. Measurements of the ability of the virus to enter the detergent phase under conditions where Triton X-114 was separated from water indicated that the virus is hydrophilic at neutral pH, and that it exposes hydrophobic regions at low pH. When the cells were pretreated with acetic acid, which reduces the intracellular pH, virus entry was inhibited, indicating that a pH gradient across the membrane is necessary for infection. Under all conditions which induced infection, the virus particles were altered to more slowly sedimenting material. Also, virus bound to aldehyde-fixed cells was altered when exposed to low pH at 37 degrees C. The data indicate that poliovirus bound to receptors on cells exposes hydrophobic regions at low pH, and that at physiological temperature it undergoes alteration. This alteration may be a necessary, but not sufficient requirement for infection.

Scintillation and autoradiographic studies on 63 nickel uptake in Pseudomonas tabaci.

Scintillation studies on the uptake of 63Ni2+ by Pseudomonas tabaci demonstrate an incorporation of approximately 2.5 nmol per 10(10) bacterial cells, in medium containing 12 nmol (8.3 microCi) per ml. Over 80% of the incorporated Ni2+ is lost from the cells during washing, fixation and dehydration with ethanol. The remaining insoluble (bound) 63Ni2+ has the highest level in cells fixed in acetic acid/ethanol (0.4 nmol/10(10) cells), with smarter amounts in paraformaldehyde- and glutaraldehyde-fixed cells. The radioactive level in aldehyde-fixed cells represents a total Ni2+ uptake of about 10(-18) g or 10(4) atoms per cell. Light- and electron-microscope autoradiography corroborated the scintillation studies in demonstrating a higher retention of label by cells fixed in acetic acid/ethanol, possibly reflecting a higher retention of medium Mr proteins with this type of fixation. High-resolution electron-microscope autoradiography involving gold latensification with physical development demonstrated a clear localization of silver grains to the central nucleoid region (seen most clearly over the discrete nucleoid of aldehyde-fixed cells) and within this to the chromatin (seen most clearly over the condensed chromatin of acetic acid/ethanol-fixed cells). It is suggested that the incorporated 63Ni2+ labels mainly central, genetically inactive DNA, while peripheral, actively transcribing DNA has little associated radioactivity. The pattern of cation association seen in this bacterium shows a number of close similarities to the situation seen in dinoflagellate cells.

Changes in Lectin-Binding Sites on the Thyroid Follicle Cell Surface Shown by the Ferritin-Labeling Technique

Lectin-binding sites on the porcine thyroid follicle cell surface wereexamined using ferritin conjugated Ricinus communis agglutinin (Fer-RCA) as a cytochemical stain for sugar residues on the plasma membranes. The porcine thyroid gland was dissociated in an enzyme solution containing collagenase and trypsin. The dissociated non-cultured cells and the disso-ciated then cultured cells, either unfixed or aldehyde-fixed, were labeled with Fer-RCA and processed for transmission electron microscopy. On aldehyde-fixed cells, the tagged ferritin particles representing RCA-binding sites were more abundant at the apical surface than at the baso-lateral surface. On unfixed cells, patchy and sparse redistribution of the Fer-RCA binding sites was seen on the baso-lateral surfaces, whereas on the apical surfaces it was not clear. Recovery of the binding capacity for Fer-RCA at the baso-lateral cell surfaces took place within 1 h, when Fer-RCA-labeled, unfixed, disso-ciated cells were incubated in the culture medium without Fer-RCA. The en-zymatic dissociation procedure did not seem to change the RCA-binding sites in terms of number and the distribution pattern over all the cellsurfaces, but to some degree it caused higher mobility and easier detachment of RCA-binding sites on the unfixed baso-lateral cell surfaces. We concluded that thyroid follicle cells have regional differences for their RCA-binding sites in the distribution and redistribution patterns between the apical and the baso-lateral cell surfaces. These regional differences in the RCA-binding sites may represent plasma membrane polarity, morphologically and functionally, in these highlyorganized tissue cells.

Distribution and movement of anionic cell surface sites in cultured human vascular endothelial cells

Cell surface anionic sites on primary and transformed cultures of human vascular endothelium were studied using cationized ferritin (CF) as an ultrastructural marker. The native distribution of anionic sites on the upper (free) surfaces of cells, fixed in situ with glutaraldehyde, was uniform. Binding of the polycationic ligand, CF, in unfixed cells induced redistribution of anionic sites. Rapid formation of discrete patches of CF particles was followed by reappearance of binding between patches, movement of surface-bound CF into intercellular clefts, and endocytosis, over the next 30 min. Aldehyde-fixed cells, detached from the culture surface, bound CF on both upper and lower surfaces. The distribution and mobility of negatively charged membrane components in vascular endothelium may have relevance for thrombosis, atherogenesis, and vascular permeability.

Effect of acetaldehyde and glutaraldehyde fixation on the surface properties of red blood cells as determined by partition in aqueous phases

A correlation between partition of cells in dextran/polyethylene glycol aqueous phase systems and their relative electrophoretic mobilities is often in evidence. Absence of such a correlation is indicative that partition measures surface properties other than charge at the plane of shear. Acetaldehyde- and glutaraldehyde-fixed erythrocytes were partitioned in two-polymer phases and their electrophoretic mobility examined in order to investigate the circumstances under which the above-indicated correlation holds. Aspects of the effect of fixation of cells on their surface properties was thereby obtained. 1. 1. Acetaldehyde-fixed and normal human red blood cells have similar partitions and similar electrophoretic mobilities; glutaraldehyde-fixed red cells display markedly increased partitions and mobilities. 2. 2. Lipid-extracted aldehyde-fixed cells have substantially increased partitions, but unchanged mobilities, when compared with the fixed cells from which they were prepared. This indicates that the removal of lipid exposes a higher density of charge groups deeper in the membrane than is measurable by electrophoresis under the conditions used. 3. 3. The countercurrent distribution obtained with fixed cells depends on the length of time chosen for phase settling. Short times result in a single distribution while longer settling times give rise to a two-peak distribution. The latter phenomenon probably arises from a time-dependent aggregation of the fixed cells in the phases. 4. 4. Electrophoretic examination of the glutaraldehyde-fixed cells from different cavities along the extraction train indicates that the fixation process does not eliminate differences in the relative electrophoretic mobilities of erythrocytes of different ages.

Use of stable sensitized cells in an improved indirect microhemagglutination test for malaria.

Aldehyde-fixed cells sensitized with Plasmodium knowlesi and P. falciparum antigens were tested with sera from P. vivax and P. falciparum infections. Titers were improved by use of a mixture of cells sensitized with the two antigens.

Chloroplast organization and the ultrastructural localization of photosystems I and II

Chlorophyll and lipids are retained in chloroplasts when aldehyde-fixed cells are embedded in water-containing glutaraldehyde-urea resins. The ordered array of thylakoid membranes then is preserved and seen with precision, permitting unusually accurate measurements of the various components of grana. A spatially precisely defined interthylakoid gap, about 40 A thick, invariably is evident. Its contents are differentiated by KMnO 4 when this is applied as an oxidative stain. The layer has hydrophilic properties, and reasons are presented for believing that it includes at least a portion of the porphyrin groups associated with the chlorophyll. The photooxidation of diaminobenzidine results in the deposition of reaction products on both the thylakoid and stromal membranes. With longer incubation, the polymers accumulate in the loculi and stromal channels. This reaction is regarded as being a function of Photosystem I. The photoreduction of ferricyanide results in dense deposits in the interthylakoid gaps. This reaction is regarded as being a function of Photosystem II. In summary, it is evident that the thylakoid membranes demonstrate both a morphological and functional asymmetry or “sidedness.”