George Posthuma

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.

Endosomal compartmentalization in three dimensions: implications for membrane fusion.

Endosomes are major sorting stations in the endocytic route that send proteins and lipids to multiple destinations in the cell, including the cell surface, Golgi complex, and lysosomes. They have an intricate architecture of internal membrane structures enclosed by an outer membrane. Recycling proteins remain on the outer membrane, whereas proteins that are destined for degradation in the lysosome are sorted to the interior. Recently, a retrograde pathway was discovered whereby molecules, like MHC class II of the immune system, return from the internal structures to the outer membrane, allowing their further transport to the cell surface for T cell activation. Whether this return involves back fusion of free vesicles with the outer membrane, or occurs via the continuity of the two membrane domains, is an unanswered question. By electron tomography of cryo-immobilized cells we now demonstrate that, in multivesicular endosomes of B-lymphocytes and dendritic cells, the inner membranes are free vesicles. Hence, protein transport from inner to outer membranes cannot occur laterally in the plane of the membrane, but requires fusion between the two membrane domains. This implies the existence of an intracellular machinery that mediates fusion between the exoplasmic leaflets of the membranes involved, which is opposite to regular intracellular fusion between cytoplasmic leaflets. In addition, our 3D reconstructions reveal the presence of clathrin-coated areas at the cytoplasmic face of the outer membrane, known to participate in protein sorting to the endosomal interior. Interestingly, profiles reminiscent of inward budding vesicles were often in close proximity to the coats.

The platelet interior revisited: electron tomography reveals tubular α-granule subtypes

We have used (cryo) electron tomography to provide a 3-dimensional (3D) map of the intracellular membrane organization of human platelets at high spatial resolution. Our study shows that the open canalicular system and dense tubular system are highly intertwined and form close associations in specialized membrane regions. 3D reconstructions of individual alpha-granules revealed large heterogeneity in their membrane organization. On the basis of their divergent morphology, we categorized alpha-granules into the following subtypes: spherical granules with electron-dense and electron-lucent zone containing 12-nm von Willebrand factor tubules, subtypes containing a multitude of luminal vesicles, 50-nm-wide tubular organelles, and a population with 18.4-nm crystalline cross-striations. Low-dose (cryo) electron tomography and 3D reconstruction of whole vitrified platelets confirmed the existence of long tubular granules with a remarkably curved architecture. Immunoelectron microscopy confirmed that these extended structures represent alpha-granule subtypes. Tubular alpha-granules represent approximately 16% of the total alpha-granule population and are detected in approximately half of the platelet population. They express membrane-bound proteins GLUT3 and alphaIIb-beta3 integrin and contain abundant fibrinogen and albumin but low levels of beta-thromboglobulin and no von Willebrand factor. Our 3D study demonstrates that, besides the existence of morphologically different alpha-granule subtypes, high spatial segregation of cargo exists within individual alpha-granules.

Lysozyme distribution and conformation in a biodegradable polymer matrix as determined by FTIR techniques.

Lysozyme distribution and conformation in poly(lactic-co-glycolic acid)(PLGA) microspheres was determined using various infrared spectroscopic techniques. Infrared microscopy and confocal laser scanning microscopy indicated that the protein was homogeneously distributed inside the microspheres in small cavities resulting from the water-in-oil emulsification step. Part of the protein was observed at or near the cavity walls, while the rest was located within these cavities. Attenuated total reflectance (ATR) and photoacoustic spectroscopy (PAS) also showed that there is hardly any protein at the surface of the microspheres. Since this microsphere formulation gave a large burst release (ca. 50%), this burst release can not be caused by protein at the surface of the particles. Probably, the protein is rapidly released through pores in the PLGA matrix. Conformational analysis of lysozyme in the PLGA microspheres by KBr pellet transmission suffered from band shape distortion and baseline slope. Despite incomplete subtraction of the PLGA background, a characteristic band of non-covalent aggregates at 1625 cm(-1) was observed in the second derivative spectrum of the protein Amide I region. The other Fourier-transform infrared (FTIR) methods yielded similar results, indicating that the sample preparation procedure did not introduce artifacts. The observed aggregation signal may correspond to the protein adsorbed to the cavity walls inside the microspheres.

Immunogold Labeling of Cryosections from High-Pressure Frozen Cells

Immunogold labeling of cryosections according to Tokuyasu (Tokuyasu KT. A technique for ultracyotomy of cell suspensions and tissues. J Cell Biol 1973;57:551–565), is an important and widely used method for immunoelectron microscopy. These sections are cut from material that is chemically fixed at room temperature (room temparature fixation, RTF). Lately in many morphological studies fast freezing followed by cryosubstitution fixation (CSF) is used instead of RTF. We have explored some new methods for applying immunogold labeling on cryosections from high‐pressure frozen cells (HepG2 cells, primary chondrocytes) and tissues (cartilage and exocrine pancreas). As immunolabeling has to be carried out on thawed and stable sections, we explored two ways to achieve this: (1) The section fixation method, as briefly reported before (Liou W et al. Histochem Cell Biol 1996;106:41–58 and Möbius W et al. J Histochem Cytochem 2002;50:43–55.) in which cryosections from freshly frozen cells were stabilized in mixtures of sucrose and methyl cellulose and varying concentrations of glutaraldehyde, formaldehyde and uranyl acetate (UA). Only occasionally does this method reveal section areas with excellent cell preservation and negatively stained membranes like Tokuyasu sections of RTF material. (Liou et al.) (2) The rehydration method, a novel approach, in which CSF with glutaraldehyde and/or osmium tetroxide (OsO4) was followed by rehydration and cryosectioning as in the Tokuyasu method. Especially, the addition of UA and low concentrations of water to the CSF medium favored superb membrane contrast. Immunogold labeling was as efficient as with the Tokuyasu method.

Usefulness of the Immunogold Technique in Quantitation of a Soluble Protein in Ultra-thin Sections

We used a model system to study whether measurements of absolute local antigen concentrations at the electron microscopic level are feasible by counting immunogold labeling density in ultra-thin sections. The model system consisted of a matrix of a variable concentration of gelatin, which was mixed with given concentrations of rat pancreas amylase and fixed according to various fixation protocols. With a relatively mild fixation, there was no clear proportionality between anti-amylase gold labeling and amylase concentration in ultra-thin cryosections. This was presumably due to uncontrolled loss of amylase from the sections. After stronger fixation with 2% glutaraldehyde for 4 hr, labeling density reflected the amylase concentration very well. We observed that matrix (gelatin) density influenced labeling density. A low gelatin concentration of 5% allowed penetration of immunoreagents into the cryosection, resulting in a high and variable labeling density. In gelatin concentrations of 10% and 20%, labeling density was lower but proportional to amylase concentration. To establish an equal (minimal) penetration of immunoreagents, we embedded model blocks with different matrix densities in polyacrylamide (PAA). In ultra-thin cryosections of these PAA-embedded blocks, anti-amylase labeling was proportional to amylase concentration even at a low (5%) gelatin concentration. Anti-amylase labeling in ultra-thin sections from Lowicryl K4M low temperature-embedded blocks was higher than in PAA sections, but the results were less consistent and depended to some extent on matrix density. These results, together with the earlier observation that acrylamide completely penetrates intracellular compartments (Slot JW, Geuze HJ: Biol Cell 44:325, 1982), demonstrate that it is possible to measure true intracellular concentrations of soluble proteins in situ using ultra-thin cryosections of PAA-embedded tissue.

Inhibition of amyloid fibril formation of human amylin by N-alkylated amino acid and alpha-hydroxy acid residue containing peptides

Amyloid deposits are formed as a result of uncontrolled aggregation of (poly)peptides or proteins. Today several diseases are known, for example Alzheimers disease, Creutzfeldt-Jakob disease, mad cow disease, in which amyloid formation is involved. Amyloid fibrils are large aggregates of beta-pleated sheets and here a general method is described to introduce molecular mutations in order to achieve disruption of beta-sheet formation. Eight backbone-modified amylin derivatives, an amyloidogenic peptide involved in maturity onset diabetes, were synthesized. Their beta-sheet forming properties were studied by IR spectroscopy and electron microscopy. Modification of a crucial amide NH by an alkyl chain led to a complete loss of the beta-sheet forming capacity of amylin. The resulting molecular mutated amylin derivative could be used to break the beta-sheet thus retarding beta-sheet formation of unmodified amylin. Moreover, it was found that the replacement of this amide bond by an ester moiety suppressed fibrillogenesis significantly. Introduction of N-alkylated amino acids and/or ester functionalities-leading to depsipeptides-into amyloidogenic peptides opens new avenues towards novel peptidic beta-sheet breakers for inhibition of beta-amyloid aggregation.

Subcellular distribution of CFTR in rat intestine supports a physiologic role for CFTR regulation by vesicle traffic.

Abstract. The cystic fibrosis transmembrane conductance regulator (CFTR) is a cAMP-activated chloride channel critical to intestinal anion secretion. In addition to phosphorylation, vesicle traffic regulates CFTR in some epithelial cells. Studies of cultured intestinal cells are conflicting regarding the role of cAMP-dependent vesicle traffic in regulating chloride transport. Whether CFTR is present in vesicular compartments within chloride secretory cells in the intestine is unknown and the role of cAMP-dependent vesicle insertion in regulating CFTR and intestinal fluid secretion remains unclear. The purpose of this study was to: (1) examine and quantify the subcellular distribution for CFTR in rat intestine, (2) further define the ultrastructure of the previously identified CFTR High Expresser (CHE) cell, and (3) examine the cellular distribution of CFTR following cAMP stimulation in vivo. Using the sensitive techniques of cryoimmunogold electron microscopy we identified CFTR in subapical vesicles and on the apical plasma membrane in crypt, Brunner glands, and CHE cells. cAMP stimulation in rat proximal small intestine produced a fluid secretory response and was associated with an apical redistribution of CFTR, supporting a physiologic role for cAMP-dependent CFTR vesicle insertion in regulating CFTR in the intestine.

A reliable and convenient method to store ultrathin thawed cryosections prior to immunolabeling.

Ultracryotomy of fixed specimens in combination with immunogold labeling is widely used for ultrastructural localization of many interesting molecules. Since the introduction of this technique, vast improvements in techniques and machinery have been established and the entire process has been made easier and more accessible. Normally, sections are cut and labeled within 1 day to prevent possible loss or redistribution of soluble antigens within the sections. An increasing demand for more sections and multiple labeling protocols prompted us to investigate the extent to which ultrathin cryosections can be stored. This would render the time spent behind an ultracryomicrotome more efficient and would allow immunogold labeling at a later stage. We investigated whether gelatin plates, 2.3 M sucrose, or 1.0% methyl cellulose/1.2 M sucrose can be used to store thawed frozen sections for a longer period of time. Ultrathin sections of mildly fixed tissue and cultured cells were stored for up to 6 months before immunogold labeling. The preservation of the ultrastructure of stored sections was excellent and was similar to that of immediately processed sections. Importantly, prolonged storage did not affect the labeling intensity.

The ER to Golgi Interface is the Major Concentration Site of Secretory Proteins in the Exocrine Pancreatic Cell

By using quantitative immuno‐electron microscopy of two‐sided labeled resin sections of rat exocrine pancreatic cells, we have established the relative concentrations of the secretory proteins amylase and chymotrypsinogen in the compartments of the secretory pathway. Their total concentration over the entire pathway was ∼ 11 and ∼ 460 times, respectively. Both proteins exhibited their largest increase in concentration between the endoplasmic reticulum and cis‐Golgi, where they were concentrated 3–4 and 50–70 times, respectively. Over the further pathway, increases in concentration were moderate, albeit two times higher for chymotrypsinogen than for amylase. From trans‐Golgi to secretory granules, where the main secretory protein concentration is often thought to occur, relatively small concentration increases were observed. Additional observations on a third secretory protein, procarboxypeptidase A, showed a concentration profile very similar to chymotrypsinogen. The relatively high concentration of amylase in the early compartments of the secretory route is consistent with its exceptionally slow intracellular transport. Our data demonstrate that secretory proteins undergo their main concentration between the endoplasmic reticulum and cis‐Golgi, where we have previously found concentration activity associated with vesicular tubular clusters (Martínez‐Menárguez JA, Geuze HJ, Slot JW, Klumperman J. Cell 1999; 98: 81–90).