Matthias Floetenmeyer

High-Resolution 3D Quantitative Analysis of Caveolar Ultrastructure and Caveola–Cytoskeleton Interactions

Caveolae are characteristic invaginations of the mammalian plasma membrane (PM) implicated in lipid regulation, signal transduction and endocytosis. We have employed electron microscope tomography (ET) to quantify caveolae structure–function relationships in three‐dimension (3D) at high resolution both in conventionally fixed and in fast‐frozen/freeze‐substituted (intact) cells as well as immunolabelled PM lawns. Our findings provide a detailed quantitative comparison of the average caveola dimensions for different cell types including tissue endothelial cells and cultured 3T3‐L1 adipocytes. These studies revealed the presence of a spiked caveolar coat and a wide caveolar neck open to the extracellular milieu that is sensitive to conventional fixation; the neck region appeared to form a specialized microdomain with associated cytoplasmic material. In endothelial cells in situ in pancreatic islets of Langerhans, the diaphragm spanning the caveolar opening was clearly resolved by ET, and the involuted 3D topology of the cell surface mapped to measure the contribution of caveolar membranes to local increases in the surface area of the PM. The complexity of connections among caveolae and to the actin cytoskeleton and microtubules suggests that individual caveolae may be interconnected through a complex filamentous network to form a single functional unit.

A Single Method for Cryofixation and Correlative Light, Electron Microscopy and Tomography of Zebrafish Embryos

The zebrafish is a powerful vertebrate system for cell and developmental studies. In this study, we have optimized methods for fast freezing and processing of zebrafish embryos for electron microscopy (EM). We show that in the absence of primary chemical fixation, excellent ultrastructure, preservation of green fluorescent protein (GFP) fluorescence, immunogold labelling and electron tomography can be obtained using a single technique involving high‐pressure freezing and embedding in Lowicryl resins at low temperature. As well as being an important new tool for zebrafish research, the maintenance of GFP fluorescence after fast freezing, freeze substitution and resin embedding will be of general use for correlative light and EM of biological samples.

Potential role of nitrite for abiotic Fe(II) oxidation and cell encrustation during nitrate reduction by denitrifying bacteria

ABSTRACT Microorganisms have been observed to oxidize Fe(II) at neutral pH under anoxic and microoxic conditions. While most of the mixotrophic nitrate-reducing Fe(II)-oxidizing bacteria become encrusted with Fe(III)-rich minerals, photoautotrophic and microaerophilic Fe(II) oxidizers avoid cell encrustation. The Fe(II) oxidation mechanisms and the reasons for encrustation remain largely unresolved. Here we used cultivation-based methods and electron microscopy to compare two previously described nitrate-reducing Fe(II) oxidizers ( Acidovorax sp. strain BoFeN1 and Pseudogulbenkiania sp. strain 2002) and two heterotrophic nitrate reducers (Paracoccus denitrificans ATCC 19367 and P. denitrificans Pd 1222). All four strains oxidized ∼8 mM Fe(II) within 5 days in the presence of 5 mM acetate and accumulated nitrite (maximum concentrations of 0.8 to 1.0 mM) in the culture media. Iron(III) minerals, mainly goethite, formed and precipitated extracellularly in close proximity to the cell surface. Interestingly, mineral formation was also observed within the periplasm and cytoplasm; intracellular mineralization is expected to be physiologically disadvantageous, yet acetate consumption continued to be observed even at an advanced stage of Fe(II) oxidation. Extracellular polymeric substances (EPS) were detected by lectin staining with fluorescence microscopy, particularly in the presence of Fe(II), suggesting that EPS production is a response to Fe(II) toxicity or a strategy to decrease encrustation. Based on the data presented here, we propose a nitrite-driven, indirect mechanism of cell encrustation whereby nitrite forms during heterotrophic denitrification and abiotically oxidizes Fe(II). This work adds to the known assemblage of Fe(II)-oxidizing bacteria in nature and complicates our ability to delineate microbial Fe(II) oxidation in ancient microbes preserved as fossils in the geological record.

Constitutive Formation of Caveolae in a Bacterium

Caveolin plays an essential role in the formation of characteristic surface pits, caveolae, which cover the surface of many animal cells. The fundamental principles of caveola formation are only slowly emerging. Here we show that caveolin expression in a prokaryotic host lacking any intracellular membrane system drives the formation of cytoplasmic vesicles containing polymeric caveolin. Vesicle formation is induced by expression of wild-type caveolins, but not caveolin mutants defective in caveola formation in mammalian systems. In addition, cryoelectron tomography shows that the induced membrane domains are equivalent in size and caveolin density to native caveolae and reveals a possible polyhedral arrangement of caveolin oligomers. The caveolin-induced vesicles or heterologous caveolae (h-caveolae) form by budding in from the cytoplasmic membrane, generating a membrane domain with distinct lipid composition. Periplasmic solutes are encapsulated in the budding h-caveola, and purified h-caveolae can be tailored to be targeted to specific cells of interest.

α-Actinin-3 deficiency results in reduced glycogen phosphorylase activity and altered calcium handling in skeletal muscle

Approximately one billion people worldwide are homozygous for a stop codon polymorphism in the ACTN3 gene (R577X) which results in complete deficiency of the fast fibre muscle protein alpha-actinin-3. ACTN3 genotype is associated with human athletic performance and alpha-actinin-3 deficient mice [Actn3 knockout (KO) mice] have a shift in the properties of fast muscle fibres towards slower fibre properties, with increased activity of multiple enzymes in the aerobic metabolic pathway and slower contractile properties. alpha-Actinins have been shown to interact with a number of muscle proteins including the key metabolic regulator glycogen phosphorylase (GPh). In this study, we demonstrated a link between alpha-actinin-3 and glycogen metabolism which may underlie the metabolic changes seen in the KO mouse. Actn3 KO mice have higher muscle glycogen content and a 50% reduction in the activity of GPh. The reduction in enzyme activity is accompanied by altered post-translational modification of GPh, suggesting that alpha-actinin-3 regulates GPh activity by altering its level of phosphorylation. We propose that the changes in glycogen metabolism underlie the downstream metabolic consequences of alpha-actinin-3 deficiency. Finally, as GPh has been shown to regulate calcium handling, we examined calcium handling in KO mouse primary mouse myoblasts and find changes that may explain the slower contractile properties previously observed in these mice. We propose that the alteration in GPh activity in the absence of alpha-actinin-3 is a fundamental mechanistic link in the association between ACTN3 genotype and human performance.

Protons Released During Pancreatic Acinar Cell Secretion Acidify the Lumen and Contribute to Pancreatitis in Mice

BACKGROUND & AIMSnSecretory granules are acidic; cell secretion will therefore lead to extracellular acidification. We propose that during secretion, protons co-released with proteins from secretory granules of pancreatic acinar cells acidify the restricted extracellular space of the pancreatic lumen to regulate normal physiological and pathophysiological functions in this organnnnMETHODSnExtracellular changes in pH were quantified in real time using 2-photon microscopy analysis of pancreatic tissue fragments from mouse models of acute pancreatitis (mice given physiological concentrations [10 -20 pM] of cholecystokinin or high concentrations of [100 nM] cerulein). The effects of extracellular changes in pH on cell behavior and structures were measured.nnnRESULTSnWith physiological stimulation, secretory granule fusion (exocytosis) caused acidification of the pancreatic lumen. Acidifications specifically affected intracellular calcium responses and accelerated the rate of recovery from agonist-evoked calcium signals. Protons therefore appear to function as negative-feedback, extracellular messengers during coupling of cell stimuli with secretion. At high concentrations of cerulein, large increases in secretory activity were associated with extreme, prolonged acidification of the luminal space. These pathological changes in pH led to disruption of intercellular junctional coupling, measured by movement of occludin and E-cadherin.nnnCONCLUSIONSnBy measuring changes in extracellular pH in pancreas of mice, we observed that luminal acidification resulted from exocytosis of zymogen granules from acinar cells. This process is part of normal organ function but could contribute to the tissue damage in cases of acute pancreatitis.

The caveolin–cavin system plays a conserved and critical role in mechanoprotection of skeletal muscle

The caveolar membrane microdomain plays an integral role in stabilizing the muscle fiber surface in mice and zebrafish.

Supramolecular organization of phycobiliproteins in the chlorophyll d-containing cyanobacterium Acaryochloris marina

Here we report the high‐resolution detail of the organization of phycobiliprotein structures associated with photosynthetic membranes of the chlorophyll d‐containing cyanobacterium Acaryochloris marina. Cryo‐electron transmission‐microscopy on native cell sections show extensive patches of near‐crystalline phycobiliprotein rods that are associated with the stromal side of photosynthetic membranes. This supramolecular photosynthetic structure represents a novel mechanism of organizing the photosynthetic light‐harvesting machinery. In addition, the specific location of phycobiliprotein patches suggests a physical separation of photosystem I and photosystem II reaction centres. Based on this finding and the known photosystems structure in Acaryochloris, we discuss possible membrane arrangements of photosynthetic membrane complexes in this species.

3-D analysis of bacterial cell-(iron)mineral aggregates formed during Fe(II) oxidation by the nitrate-reducing Acidovorax sp. strain BoFeN1 using complementary microscopy tomography approaches

The formation of cell-(iron)mineral aggregates as a consequence of bacterial iron oxidation is an environmentally widespread process with a number of implications for processes such as sorption and coprecipitation of contaminants and nutrients. Whereas the overall appearance of such aggregates is easily accessible using 2-D microscopy techniques, the 3-D and internal structure remain obscure. In this study, we examined the 3-D structure of cell-(iron)mineral aggregates formed during Fe(II) oxidation by the nitrate-reducing Acidovorax sp. strain BoFeN1 using a combination of advanced 3-D microscopy techniques. We obtained 3-D structural and chemical information on different cellular encrustation patterns at high spatial resolution (4-200xa0nm, depending on the method): more specifically, (1) cells free of iron minerals, (2) periplasm filled with iron minerals, (3) spike- or platelet-shaped iron mineral structures, (4) bulky structures on the cell surface, (5) extracellular iron mineral shell structures, (6) cells with iron mineral filled cytoplasm, and (7) agglomerations of extracellular globular structures. In addition to structural information, chemical nanotomography suggests a dominant role of extracellular polymeric substances (EPS) in controlling the formation of cell-(iron)mineral aggregates. Furthermore, samples in their hydrated state showed cell-(iron)mineral aggregates in pristine conditions free of preparation (i.e., drying/dehydration) artifacts. All these results were obtained using 3-D microscopy techniques such as focused ion beam (FIB)/scanning electron microscopy (SEM) tomography, transmission electron microscopy (TEM) tomography, scanning transmission (soft) X-ray microscopy (STXM) tomography, and confocal laser scanning microscopy (CLSM). It turned out that, due to the various different contrast mechanisms of the individual approaches, and due to the required sample preparation steps, only the combination of these techniques was able to provide a comprehensive understanding of structure and composition of the various Fe-precipitates and their association with bacterial cells and EPS.