Adaptive-weighted cubic B-spline using lookup tables for fast and efficient axial resampling of 3D confocal microscopy images

Confocal laser scanning microscopy has become a most powerful tool to visualize and analyze the dynamic behavior of cellular molecules. Photobleaching of fluorochromes is a major problem with confocal image acquisition that will lead to intensity attenuation. Photobleaching effect can be reduced by optimizing the collection efficiency of the confocal image by fast z-scanning. However, such images suffer from distortions, particularly in the z dimension, which causes disparities in the x, y, and z directions of the voxels with the original image stacks. As a result, reliable segmentation and feature extraction of these images may be difficult or even impossible. Image interpolation is especially needed for the correction of undersampling artifact in the axial plane of three-dimensional images generated by a confocal microscope to obtain cubic voxels. In this work, we present an adaptive cubic B-spline-based interpolation with the aid of lookup tables by deriving adaptive weights based on local gradients for the sampling nodes in the interpolation formulae. Thus, the proposed method enhances the axial resolution of confocal images by improving the accuracy of the interpolated value simultaneously with great reduction in computational cost. Numerical experimental results confirm the effectiveness of the proposed interpolation approach and demonstrate its superiority both in terms of accuracy and speed compared to other interpolation algorithms.

An automatic segmentation algorithm for 3D cell cluster splitting using volumetric confocal images

With the rapid advance of three-dimensional (3D) confocal imaging technology, more and more 3D cellular images will be available. Segmentation of intact cells is a critical task in automated image analysis and quantification of cellular microscopic images. One of the major complications in the automatic segmentation of cellular images arises due to the fact that cells are often closely clustered. Several algorithms are proposed for segmenting cell clusters but most of them are 2D based. In other words, these algorithms are designed to segment 2D cell clusters from a single image. Given 2D segmentation methods developed, they can certainly be applied to each image slice with the 3D cellular volume to obtain the segmented cell clusters. Apparently, in such case, the 3D depth information with the volumetric images is not really used. Often, 3D reconstruction is conducted after the individualized segmentation to build the 3D cellular models from segmented 2D cellular contours. Such 2D native process is not appropriate as stacking of individually segmented 2D cells or nuclei do not necessarily form the correct and complete 3D cells or nuclei in 3D. This paper proposes a novel and efficient 3D cluster splitting algorithm based on concavity analysis and interslice spatial coherence. We have taken the advantage of using the 3D boundary points detected using higher order statistics as an input contour for performing the 3D cluster splitting algorithm. The idea is to separate the touching or overlapping cells or nuclei in a 3D native way. Experimental results show the efficiency of our algorithm for 3D microscopic cellular images.

An automatic method for identifying appropriate gradient magnitude for 3D boundary detection of confocal image stacks

Gradients play an important role in 2D image processing. Many edge detection algorithms are gradient-based. We are interested in 3D boundary detection which can be considered as an extension of 2D edge detection in 3D space. In this paper, an algorithm to automatically and quantitatively measure the suitability of gradient magnitudes in detection of 3D boundary points of confocal image stacks is presented. A Measurement Function is defined to evaluate the suitability of each gradient magnitude chosen to be the threshold for 3D boundary detection. The application of Gauss's Divergence Theorem provides a solution to calculate the Measurement Function numerically. The gradient magnitude at which the maximum of the Measurement Function is achieved can be utilized as the most appropriate threshold for gradient-based boundary detection and other operations like volume visualization.

Is all of the endoplasmic reticulum created equal? The effects of the heterogeneous distribution of endoplasmic reticulum Ca2+-handling proteins

The endoplasmic reticulum is a heterogeneous compartment with respect to the distribution of its Ca2+-handling proteins, namely the Ca2+-binding proteins, the Ca2+ pumps and the Ca2+ release channels. The nonuniform distribution of these proteins may explain the functional heterogeneity of the endoplasmic reticulum, such as the generation of spatially complex Ca2+ signals, Ca2+ homeostasis, and protein folding and quality control.

Ca2+ signaling and calcium binding chaperones of the endoplasmic reticulum

The endoplasmic reticulum is a centrally located organelle which affects virtually every cellular function. Its unique luminal environment consists of Ca(2+) binding chaperones, which are involved in protein folding, post-translational modification, Ca(2+) storage and release, and lipid synthesis and metabolism. The environment within the lumen of the endoplasmic reticulum has profound effects on endoplasmic reticulum function and signaling, including apoptosis, stress responses, organogenesis, and transcriptional activity. Calreticulin, a major Ca(2+) binding (storage) chaperone in the endoplasmic reticulum, is a key component of the calreticulin/calnexin cycle which is responsible for the folding of newly synthesized proteins and glycoproteins and for quality control pathways in the endoplasmic reticulum. The function of calreticulin, calnexin and other endoplasmic reticulum proteins is affected by continuous fluctuations in the concentration of Ca(2+) in the endoplasmic reticulum. Thus, changes in Ca(2+) concentration may play a signaling role in the lumen of the endoplasmic reticulum as well as in the cytosol. Recent studies on calreticulin-deficient and transgenic mice have revealed that calreticulin and the endoplasmic reticulum may be upstream regulators in the Ca(2+)-dependent pathways that control cellular differentiation and/or organ development.

Functional specialization of calreticulin domains

Calreticulin is a Ca2+-binding chaperone in the endoplasmic reticulum (ER), and calreticulin gene knockout is embryonic lethal. Here, we used calreticulin-deficient mouse embryonic fibroblasts to examine the function of calreticulin as a regulator of Ca2+ homeostasis. In cells without calreticulin, the ER has a lower capacity for Ca2+ storage, although the free ER luminal Ca2+ concentration is unchanged. Calreticulin-deficient cells show inhibited Ca2+ release in response to bradykinin, yet they release Ca2+ upon direct activation with the inositol 1,4,5-trisphosphate (InsP3). These cells fail to produce a measurable level of InsP3 upon stimulation with bradykinin, likely because the binding of bradykinin to its cell surface receptor is impaired. Bradykinin binding and bradykinin-induced Ca2+ release are both restored by expression of full-length calreticulin and the N + P domain of the protein. Expression of the P + C domain of calreticulin does not affect bradykinin-induced Ca2+ release but restores the ER Ca2+ storage capacity. Our results indicate that calreticulin may play a role in folding of the bradykinin receptor, which affects its ability to initiate InsP3-dependent Ca2+ release in calreticulin-deficient cells. We concluded that the C domain of calreticulin plays a role in Ca2+ storage and that the N domain may participate in its chaperone functions.

Endoplasmic reticulum in the heart, a forgotten organelle?

Our hypothesis is that sarcoplasmic and endoplasmic reticulum Ca2+ stores may be functionally distinct compartments in cardiomyocytes. Sarcoplasmic reticulum Ca2+ store is responsible for control of excitation-contraction coupling whereas endoplasmic reticulum compartment may provide Ca2+ for housekeeping and transcriptional functions.

Complete heart block and sudden death in mice overexpressing calreticulin

The expression of calreticulin, a Ca(2+)-binding chaperone of the endoplasmic reticulum, is elevated in the embryonic heart, and because of impaired cardiac development, knockout of the Calreticulin gene is lethal during embryogenesis. The elevated expression is downregulated after birth. Here we have investigated the physiological consequences of continued high expression of calreticulin in the postnatal heart, by producing transgenic mice that overexpress the protein in the heart. These transgenic animals exhibit decreased systolic function and inward I(Ca,L), low levels of connexin43 and connexin40, sinus bradycardia, and prolonged atrioventricular (AV) node conduction followed by complete heart block and sudden death. We conclude that postnatal downregulation of calreticulin is essential in the development of the cardiac conductive system, in particular in the sinus and AV nodes, when an inward Ca(2+) current is required for activation. This work identifies a novel pathway of events, leading to complete heart block and sudden cardiac death, which involves high expression of calreticulin in the heart.

Formation of retinal pigment epithelium in vitro by transdifferentiation of neural retina cells

Chick embryonic neural retina (NR) dedifferentiates in culture and can transdifferentiate spontaneously into retinal pigment epithelium (RPE). Both, primary RPE and transdifferentiated RPE (RPEt), are characterized by pigmentation, expression of RPE-specific protein, eRPEAG and lack of expression of the neural cell adhesion molecule, NCAM. In contrast, NR cells are unpigmented and express NCAM but not eRPE(AG). Functionally, both primary RPE and the RPEt cells display a pH(i) response to bFGF, which is different from that of the NR. We used these characteristics to distinguish cell types in primary cultures of chick NR and follow the changes in phenotype that occur during transdifferentiation. We show that the RPEt forms as small "islands" in the packed regions of the primary, "mother" NR cell sheets, in a stochastic process. Because of a small number of cells involved in the initiation of the transdifferentiation we refer to it as a "leader effect" to contrast it with the "community effect" which requires many competent cells to be present in a group to be able to respond to an inductive signal. The RPEt then expands centrifugally and underneath the surrounding NR sheet. To determine if the RPEt maintains its identity in isolation while displaying the RPE-typical phenotypic plasticity, we explanted the islands of RPEt and treated half of them with bFGF. The untreated RPEt maintained its closely packed, polygonal pigmented phenotype but the bFGF-treated RPEt transdifferentiated into a non-pigmented, NR-like phenotype, indicating that RPEt encompasses the full differentiation repertoire of native RPE.

Calreticulin affects beta-catenin-associated pathways

Calreticulin, a Ca(2+) storage protein and chaperone in the endoplasmic reticulum, also modulates cell adhesiveness. Overexpression of calreticulin correlates with (i) increased cell adhesiveness, (ii) increased expression of N-cadherin and vinculin, and (iii) decreased protein phosphorylation on tyrosine. Among proteins that are dephosphorylated in cells that overexpress calreticulin is beta-catenin, a structural component of cadherin-dependent adhesion complexes, a member of the armadillo family of proteins and a part of the Wnt signaling pathway. We postulate that the changes in cell adhesiveness may be due to calreticulin-mediated effects on a signaling pathway from the endoplasmic reticulum, which impinges on the Wnt signaling pathway via the cadherin/catenin protein system and involves changes in the activity of protein-tyrosine kinases and/or phosphatases.

The ins and outs of calreticulin: from the ER lumen to the extracellular space

Calreticulin was first isolated 26 years ago. Since its discovery as a minor Ca(2+)-binding protein of the sarcoplasmic reticulum, the appreciation of its importance has grown, and it is now recognized to be a multifunctional protein, most abundant in the endoplasmic reticulum (ER). The protein has well-recognized physiological roles in the ER as a molecular chaperone and Ca(2+)-signalling molecule. However, it has also been found in other membrane-bound organelles, at the cell surface and in the extracellular environment, where it has recently been shown to exert a number of physiological and pathological effects. Here, we will focus on these less-well-characterized functions of calreticulin.

Expression and purification of mammalian calreticulin in Pichia pastoris

Calreticulin is a 46-kDa Ca(2+)-binding chaperone of the endoplasmic reticulum membranes. The protein binds Ca(2+) with high capacity, affects intracellular Ca(2+) homeostasis, and functions as a lectin-like chaperone. In this study, we describe expression and purification procedures for the isolation of recombinant rabbit calreticulin. The calreticulin was expressed in Pichia pastoris and purified to homogeneity by DEAE-Sepharose and Resource Q FPLC chromatography. The protein was not retained in the endoplasmic reticulum of Pichia pastoris but instead it was secreted into the external media. The purification procedures reported here for recombinant calreticulin yield homogeneous preparations of the protein by SDS-PAGE and mass spectroscopy analysis. Purified calreticulin was identified by its NH(2)-terminal amino acid sequences, by its Ca(2+) binding, and by its reactivity with anti-calreticulin antibodies. The protein contained one disulfide bond between (88)Cys and (120)Cys. CD spectral analysis and Ca(2+)-binding properties of the recombinant protein indicated that it was correctly folded.

Calreticulin: one protein, one gene, many functions

The endoplasmic reticulum (ER) plays a critical role in the synthesis and chaperoning of membrane-associated and secreted proteins. The membrane is also an important site of Ca(2+) storage and release. Calreticulin is a unique ER luminal resident protein. The protein affects many cellular functions, both in the ER lumen and outside of the ER environment. In the ER lumen, calreticulin performs two major functions: chaperoning and regulation of Ca(2+) homoeostasis. Calreticulin is a highly versatile lectin-like chaperone, and it participates during the synthesis of a variety of molecules, including ion channels, surface receptors, integrins and transporters. The protein also affects intracellular Ca(2+) homoeostasis by modulation of ER Ca(2+) storage and transport. Studies on the cell biology of calreticulin revealed that the ER membrane is a very dynamic intracellular compartment affecting many aspects of cell physiology.

Fluorescence tracing of intracellular proteins

Developments in fluorescence microscopy and the availability of fluorescently labeled antibodies and probes for localization of molecules and organelles have made the microscope an indispensable tool with which one can map specific molecules to subcellular loci allowing deep insight into cell and organelle biology. Furthermore, confocal microscopy permits analysis of the three dimensional architecture of cells that could not be accomplished by conventional light microscopy. The goal of fluorescence protein tracing by microscopy is to visualize cellular constituents and general cytoarchitecture as close to native organization as possible. To achieve this, and to preserve cellular structure in the best possible manner, the specimen is usually fixed chemically. Here I review several standard fixation, permeabilization and labeling schemes followed by examples of several standard imaging techniques.

Tumor necrosis factor-alpha mediates lipopolysaccharide-induced macrophage inflammatory protein-2 release from alveolar epithelial cells. Autoregulation in host defense

Our recent studies have demonstrated that in response to lipopolysaccharide (LPS) challenge, alveolar epithelial cells produced tumor necrosis factor (TNF)-alpha, an early response cytokine in the inflammatory process. To investigate whether LPS-induced TNF-alpha release is related to other inflammatory mediators from the same cell type, we examined effects of LPS stimulation on macrophage inflammatory protein (MIP)-2 production by alveolar epithelial cells, and then examined the relationship between TNF-alpha and MIP-2 production. LPS stimulation induced a dose- and time-dependent release of MIP-2. The steady-state messenger RNA level of MIP-2 was significantly increased, with the MIP-2 protein localized within alveolar epithelial cells, as determined by confocal microscopy. The LPS-induced MIP-2 production is regulated at both the transcriptional and post-transcriptional levels. TNF-alpha also induced MIP-2 production from alveolar epithelial cells. Preincubation with an antisense oligonucleotide against TNF-alpha inhibited LPS-induced TNF-alpha in a dose-dependent and sequence-specific manner. The same antisense also inhibited MIP-2 production. The inhibitory effects were highly correlated. Polyclonal and monoclonal antibodies against TNF-alpha also attenuated LPS-induced MIP-2. These results suggest that LPS-induced MIP-2 release from alveolar epithelial cells may be mediated in part by TNF-alpha from the same cell type. This autoregulatory mechanism may amplify LPS-induced signals involved in host defense as well as in acute inflammatory reactions.

LPS-induced depolymerization of cytoskeleton and its role in TNF-alpha production by rat pneumocytes

Lipopolysaccharide (LPS) polymerizes microfilaments and microtubules in macrophages and monocytes. Disrupting microfilaments or microtubules with cytochalasin D (CytoD) or colchicine can suppress LPS-induced tumor necrosis factor-alpha (TNF-alpha) gene expression and protein production from these cells. We have recently demonstrated that primary cultured rat alveolar epithelial cells can produce TNF-alpha on LPS stimulation. In the present study, we found that the LPS-induced increase in TNF-alpha mRNA level and protein production in alveolar epithelial cells was not inhibited by CytoD or colchicine (1 nM to 10 microM). In fact, LPS-induced TNF-alpha production was further enhanced by CytoD (1-10 microM) and inhibited by jasplakinolide, a polymerizing agent for microfilaments. Immunofluorescent staining and confocal microscopy showed that LPS (10 microg/ml) depolymerized microfilaments and microtubules within 15 min, which was prolonged until 24 h for microfilaments. These results suggest that the effects of LPS on the cytoskeleton and the role of the cytoskeleton in mediating TNF-alpha production in alveolar epithelial cells are opposite to those in immune cells. This disparity may reflect the different roles between nonimmune and immune cells in host defense.

Calreticulin, a multifunctional Ca2+ binding chaperone of the endoplasmic reticulum

Calreticulin is a ubiquitous endoplasmic reticulum Ca2+ binding chaperone. The protein has been implicated in a variety of diverse functions. Calreticulin is a lectin-like chaperone and, together with calnexin, it plays an important role in quality control during protein synthesis, folding, and posttranslational modification. Calreticulin binds Ca2+ and affects cellular Ca2+ homeostasis. The protein increases the Ca2+ storage capacity of the endoplasmic reticulum and modulates the function of endoplasmic reticulum Ca2+-ATPase. Calreticulin also plays a role in the control of cell adhesion and steroid-sensitive gene expression. Recently, the protein has been identified and characterized in higher plants but its precise role in plant cells awaits further investigation.

Calreticulin affects focal contact-dependent but not close contact-dependent cell-substratum adhesion

We used two cell lines expressing fast (RPEfast) and slow (RPEslow) attachment kinetics to investigate mechanisms of cell-substratum adhesion. We show that the abundance of a cytoskeletal protein, vinculin, is dramatically decreased in RPEfast cells. This coincides with the diminished expression level of an endoplasmic reticulum chaperone, calreticulin. Both protein and mRNA levels for calreticulin and vinculin were decreased in RPEfast cells. After RPEfast cells were transfected with cDNA encoding calreticulin, both the expression of endoplasmic reticulum-resident calreticulin and cytoplasmic vinculin increased. The abundance of other adhesion-related proteins was not affected. RPEfast cells underexpressing calreticulin displayed a dramatic increase in the abundance of total cellular phosphotyrosine suggesting that the effects of calreticulin on cell adhesiveness may involve modulation of the activities of protein tyrosine kinases or phosphatases which may affect the stability of focal contacts. The calreticulin and vinculin underexpressing RPEfast cells lacked extensive focal contacts and adhered weakly but attached fast to the substratum. In contrast, the RPEslow cells that expressed calreticulin and vinculin abundantly developed numerous and prominent focal contacts slowly, but adhered strongly. Thus, while the calreticulin overexpressing RPEslow cells "grip" the substratum with focal contacts, calreticulin underexpressing RPEfast cells use close contacts to "stick" to it.

Calreticulin is essential for cardiac development

Calreticulin is a ubiquitous Ca2+ binding protein, located in the endoplasmic reticulum lumen, which has been implicated in many diverse functions including: regulation of intracellular Ca2+ homeostasis, chaperone activity, steroid-mediated gene regulation, and cell adhesion. To understand the physiological function of calreticulin we used gene targeting to create a knockout mouse for calreticulin. Mice homozygous for the calreticulin gene disruption developed omphalocele (failure of absorption of the umbilical hernia) and showed a marked decrease in ventricular wall thickness and deep intertrabecular recesses in the ventricular walls. Transgenic mice expressing a green fluorescent protein reporter gene under the control of the calreticulin promoter were used to show that the calreticulin gene is highly activated in the cardiovascular system during the early stages of cardiac development. Calreticulin protein is also highly expressed in the developing heart, but it is only a minor component of the mature heart. Bradykinin-induced Ca2+ release by the InsP3-dependent pathway was inhibited in crt-/- cells, suggesting that calreticulin plays a role in Ca2+ homeostasis. Calreticulin-deficient cells also exhibited impaired nuclear import of nuclear factor of activated T cell (NF-AT3) transcription factor indicating that calreticulin plays a role in cardiac development as a component of the Ca2+/calcineurin/NF-AT/GATA-4 transcription pathway.

Interaction between a Ca2+-binding protein calreticulin and perforin, a component of the cytotoxic T-cell granules

Calreticulin is a component of cytotoxic T-lymphocyte and NK lymphocyte granules. We report here that granule-associated calreticulin terminates with the KDEL endoplasmic reticulum retrieval amino acid sequence and somehow escapes the KDEL retrieval system. In perforin knock-out mice calreticulin is still targeted into the granules. Thus, calreticulin will traffic without perforin to cytotoxic granules. In the granules, calreticulin and perforin are associated as documented by (i) copurification of calreticulin with perforin but not with granzymes and (ii) immunoprecipitation of a calreticulin-perforin complex using specific antibodies. By using calreticulin affinity chromatography and protein ligand blotting we show that perforin binds to calreticulin in the absence of Ca2+ and the two proteins dissociate upon exposure to 0.1 mM or higher Ca2+ concentration. Perforin interacts strongly with the P-domain of calreticulin (the domain which has high Ca2+-binding affinity and chaperone function) as revealed by direct protein-protein interaction, ligand blotting, and the yeast two-hybrid techniques. Our results suggest that calreticulin may act as Ca2+-regulated chaperone for perforin. This action will serve to protect the CTL during biogenesis of granules and may also serve to regulate perforin lytic action after release.

Direct transdifferentiation in the vertebrate retina

Transdifferentiation is the process by which differentiated cells alter their identity to become other, distinct cell types. The conversion of neural retina into lens epithelium is one of the most spectacular examples of transdifferentiation. We show that the redirection of cell fate from neural retina to lens and subsequent transdifferentiation is independent of cell replication as it occurs in growth-arrested cell populations. Using DNA ratiometry of individual cells in these cultures we show that, indeed, individual amitotic cells do transdifferentiate. Hence, choice of fate in transdifferentiating cells does not rely on a "community effect" but instead can be categorized as a <<leadership effect>> For lack of overt lens progenitors, and most importantly, for its mitotic independence, we conclude that lens colony formation in vitro does occur by direct transdifferentiation and not by clonal proliferation of progenitor cells.

Heat shock-regulated expression of calreticulin in retinal pigment epithelium

Calreticulin is a major Ca2+ binding protein in the endoplasmic reticulum of non-muscle cells. In this report we show that calreticulin protein is strongly induced by heat shock. Activation and attenuation of the heat shock transcriptional response is caused by heat shock factor that binds to 5'-flanking sequences of heat shock responsive genes, the heat shock element. The smallest stretch of DNA that shows detectable binding of heat shock factor in vitro contains a two-sequence unit nGAAnnTTCn which exists in the 5'-flanking region of calreticulin DNA (5'-gGAAccCAGcgTTC-3'). The present data provide direct evidence that calreticulin expression can be modulated by heat shock. Thus, our results strengthen the hypothesis that calreticulin, in addition to its function as a cellular Ca2+ store, is a multifunctional protein which performs at least some of its functions from the lumen of the ER.

Functions of dystrophin and dystrophin associated proteins

Dystrophin is a protein product of the X-linked gene mutation that is responsible for Duchenne and Becker muscular dystrophies. The protein binds actin and associates with dystrophin-glycoprotein complex to link the cytoskeleton to the extracellular matrix. Defects in the components of the dystrophin-glycoprotein complex are responsible for several phenotypes of muscular dystrophy.

Calreticulin inhibits glucocorticoid- but not cAMP-sensitive expression of tyrosine aminotransferase gene in cultured McA-RH7777 hepatocytes

Calreticulin is a ubiquitously expressed Ca2+ binding protein of the endoplasmic reticulum which inhibits DNA binding and transcriptional activation by steroid hormone receptors. In this study the effects of calreticulin on tyrosine aminotransferase (TAT) gene expression in cultured McA-RH7777 hepatocytes was investigated. McA-RH7777 cells were stably transfected with calreticulin expression vector to generate cells overexpressing the protein. The transcriptional activity of the TAT gene, which is glucocorticoid-sensitive and cAMP-dependent, was investigated in the mock transfected McA-RH7777 and in cells overexpressing calreticulin (designated McA-11 and McA-17). In the presence of dexamethasone or the cAMP analog (CTP-cAMP) expression of the TAT gene was induced in mock transfected McA-RH7777 cells by approximately 4.5 and 5 fold, respectively. In McA-11 and McA-17 cells, overexpressing calreticulin, glucocorticoid-sensitive expression of the TAT gene was significantly inhibited, however, the CTP-cAMP-dependent expression of the TAT gene was not affected. The ability of calreticulin to inhibit glucocorticoid-sensitive TAT gene expression but not the cAMP-dependent expression of the gene suggests that the protein affects specifically the action of transcription pathways involving steroid receptors or transcription factors containing KxFF(K/R)R-like motifs. Calreticulin may play an important role in the regulation of glucocorticoid-sensitive pathway of expression of the hepatocytes specific genes during development.

Measurement of intracellular pH and pCa with a confocal microscope

In the late 1980s, the field of biological confocal microscopy exploded. So did traffic on the Internet. Considering the ongoing interest in the role of intracellular pH and pCa in all aspects of cell physiology, it is not surprising that the most frequently asked question on the Internet's confocal forum has been: 'How do I measure pH/pCa with a confocal microscope?' This article was inspired by these Internet discussions and attempts to answer this question by presenting the rationale for using (or not using) a confocal approach to measure intracellular ion concentration, assessing the feasibility of performing this task with currently prevailing hardware, assembling the currently available 'know-how' and telling 'how'.

Calreticulin modulates cell adhesiveness via regulation of vinculin expression

Calreticulin is an ubiquitous and highly conserved high capacity Ca(2+)-binding protein that plays a major role in Ca2+ storage within the lumen of the ER. Here, using L fibroblast cell lines expressing different levels of calreticulin, we show that calreticulin plays a role in the control of cell adhesiveness via regulation of expression of vinculin, a cytoskeletal protein essential for cell-substratum and cell-cell attachments. Both vinculin protein and mRNA levels are increased in cells overexpressing calreticulin and are downregulated in cells expressing reduced level of calreticulin. Abundance of actin, talin, alpha 5 and beta 1 integrins, pp125 focal adhesion kinase, and alpha-catenin is not affected by the differential calreticulin expression. Overexpression of calreticulin increases both cell-substratum and cell-cell adhesiveness of L fibroblasts that, most surprisingly, establish vinculin-rich cell-cell junctions. Upregulation of calreticulin also affects adhesion-dependent phenomena such as cell motility (which decreases) and cell spreading (which increases). Downregulation of calreticulin brings about inverse effects. Cell adhesiveness is Ca2+ regulated. The level of calreticulin expression, however, has no effect on either the resting cytoplasmic Ca2+ concentration or the magnitude of FGF-induced Ca2+ transients. Calreticulin, however, participates in Ca2+ homeostasis as its level of expression affects cell viability at low concentrations of extracellular Ca2+. Consequently, we infer that it is not the Ca2+ storage function of calreticulin that affects cell adhesiveness. Neither endogenous calreticulin nor overexpressed green fluorescent protein-calreticulin construct can be detected outside of the ER. Since all of the adhesion-related effects of differential calreticulin expression can be explained by its regulation of vinculin expression, we conclude that it is the ER-resident calreticulin that affects cellular adhesiveness.

Endoplasmic reticulum form of calreticulin modulates glucocorticoid-sensitive gene expression

Calreticulin is a ubiquitously expressed Ca2+-binding protein of the endoplasmic reticulum (ER), which inhibits DNA binding in vitro and transcriptional activation in vivo by steroid hormone receptors. Transient transfection assays were carried out to investigate the effects of different intracellular targeting of calreticulin on transactivation mediated by glucocorticoid receptor. BSC40 cells were transfected with either calreticulin expression vector (ER form of calreticulin) or calreticulin expression vector encoding calreticulin minus leader peptide, resulting in cytoplasmic localization of the recombinant protein. Transfection of BSC40 cells with calreticulin expression vector encoding the ER form of the protein led to 40-50% inhibition of the dexamethasone-sensitive stimulation of luciferase expression. However, in a similar experiment, but using the calreticulin expression vector encoding cytoplasmic calreticulin, dexamethasone-stimulated activation of the luciferase reporter gene was inhibited by only 10%. We conclude that the ER, but not cytosolic, form of calreticulin is responsible for inhibition of glucocorticoid receptor-mediated gene expression. These effects are specific to calreticulin, since overexpression of the ER lumenal proteins (BiP, ERp72, or calsequestrin) has no effect on glucocorticoid-sensitive gene expression. The N domain of calreticulin binds to the DNA binding domain of the glucocorticoid receptor in vitro; however, we show that the N+P domain of calreticulin, when synthesized without the ER signal sequence, does not inhibit glucocorticoid receptor function in vivo. Furthermore, expression of the N domain of calreticulin and the DNA binding domain of glucocorticoid receptor as fusion proteins with GAL4 in the yeast two-hybrid system revealed that calreticulin does not interact with glucocorticoid receptor under these conditions. We conclude that calreticulin and glucocorticoid receptor may not interact in vivo and that the calreticulin-dependent modulation of the glucocorticoid receptor function may therefore be due to a calreticulin-dependent signaling from the ER.

Overexpression of calreticulin increases intracellular Ca2+ storage and decreases store-operated Ca2+ influx

The widely distributed and highly conserved Ca(2+)-binding protein calreticulin has been suggested to play a role as a Ca2+ storage protein of intracellular Ca+ stores. To test this hypothesis, we have generated a mouse L fibroblast cell line stably transfected with a calreticulin expression vector. The calreticulin content of the overexpressers was increased by 1.6 +/- 0.2-fold compared with mock-transfected cells. The total cellular Ca2+ content of calreticulin-overexpressing and control cells, as assessed by equilibrium 45Ca+2 uptake, was 141 +/- 8 and 67 +/- 6 pmol of Ca2+/10(6) cells, respectively (i.e. a 2.1 +/- 0.2-fold increase in the Ca2+ content of calreticulin-overexpressing cells). Over 80% of the increased Ca2+ content was found within thapsigargin-sensitive Ca2+ stores. The pattern of calreticulin distribution, revealed by immunofluorescence microscopy, showed an endoplasmic reticulum-like pattern and was identical in overexpressers and control cells. In overexpressers, cytosolic free [Ca2+] elevations due to Ca2+ release were enhanced when either ATP or a combination of ionomycin and thapsigargin was used as a stimulus. In contrast, thapsigargin-induced Ca2+ and Mn2+ influxes from the extracellular space were markedly diminished in calreticulin-overexpressing cells, suggesting an active involvement of calreticulin in the regulation of store-operated Ca2+ influx.

Regulation of calcium binding proteins calreticulin and calsequestrin during differentiation in the myogenic cell line L6

In this report we defined the structural and temporal limits within which calreticulin and calsequestrin participate in the muscle cell phenotype, in the L6 model myogenic system. Calreticulin and calsequestrin are two Ca2+ binding proteins thought to participate in intracellular Ca2+ homeostasis. We show that calsequestrin protein and mRNA were expressed when L6 cells were induced to differentiate, during which time the level of expression of calreticulin protein did not change appreciably. Calreticulin mRNA levels, however, were constant throughout L6 cell differentiation except for slight decline in the mRNA levels at the very late stages of L6 differentiation (day 11-12). We also show that the two Ca2+ binding proteins are coexpressed in differentiated L6 cells. Based on its mobility in SDS-PAGE, L6 rat skeletal muscle cells in culture expressed cardiac isoform of calsequestrin. In the mature rat skeletal muscle, calreticulin and calsequestrin were localized to sarcoplasmic reticulum (SR). Calreticulun, but not calsequestrin, staining was also observed in the perinuclear region. These data suggest that expression of calreticulin and calsequestrin may be under different control during myogenesis in rat L6 cells in culture.

Use of a new fluorescent probe, seminaphthofluorescein-calcein, for determination of intracellular pH by simultaneous dual-emission imaging laser scanning confocal microscopy

A new pH indicator, seminaphthofluorescein (SNAFL)-calcein acetoxymethyl ester, was used for intracellular pH (pHi) measurement in living MDCK cells with a laser scanning confocal microscope (LSCM) equipped with an Argon/Krypton laser and dual-excitation and dual-emission (FITC/Texas Red) filter set. SNAFL-calcein excitation maxima are approximately 492/540 nm (acid/base) and emission maxima are approximately 535/625 nm (acid/base) with a pKa value at approximately 7.0. The absorption/emission spectra of SNAFL-calcein indicate that the ratio of emission intensities of its basic/acidic forms is pH dependent. With an Argon/Krypton LSCM, we were able to monitor the acidic and basic forms of this dye simultaneously using dual-excitation (488/568 nm) and dual-emission (525-614 nm/> or = 615 nm) wavelengths (lambda s). The simultaneous dual-excitation/emission LSCM system allows for efficient recording of pHi dynamics (time resolution approximately 1 sec) in living cells. We have analyzed emission stability of the dye at different temperatures (22 degrees C and 37 degrees C) and constant pH, and at the same temperature (22 degrees C) but various pHs (6.6, 7.0, and 7.4). Bleaching rate is slightly higher at 37 degree C than that at 22 degrees C. The basic form of the dye (lambda Em approximately 625 nm) has a slightly higher bleaching rate than the acidic form (lambda Em approximately 535 nm) in standard culture medium (pH 7.3) at either 22 degree C or 37 degrees C. The pHi in MDCK cells calculated from ratio images (535 nm/625 nm) was 7.19 +/- 0.03 (mean +/- SEM, n = 20). Calibration experiments show that the useful pH range of SNAFL-calcein appears to be between 6.2 and 7.8, as the dye is difficult to calibrate outside this pH range.

Cellular adhesiveness, contractility, and traction: stick, grip, and slip control

Translocation of cells over solid substrata depends on generation of motive force, in crawling tissue cells, brought about by regulated contractility of intracellular actomyosin. Intracellular contractile machinery has a direct, structural connection to the cell surface. Hence, regulated adhesiveness of the cell surface provides a mechanism whereby a cell can fine tune the extent of tractional forces that are necessary for effective translocation. Cells are able to control adhesiveness of surfaces (stick), contractility (grip), and the extent of traction exerted on the substratum (slip). Here, I discuss several aspects of local (subcellular) regulation of adhesiveness and contractility and speculate on how cells, given a choice of the substratum, decide on how and where to apply traction.

Cell shape, intracellular pH, and fibroblast growth factor responsiveness during transdifferentiation of retinal pigment epithelium into neuroepithelium in vitro

In this report we show that some retinal pigment epithelial (RPE) cells, with no expression of neural cell adhesion molecule (N-CAM) (RPEN-CAM-), spontaneously lose pigment and start to express N-CAM in culture. Chick RPE cells normally do not express N-CAM, while the protein is present in chick neural retina. Thus some of the RPE cells in culture started to transdifferentiate into a neuroepithelium (NEN-CAM+). We have measured intracellular pH (pHi) in the RPE cultures and followed its changes in response to basic fibroblast growth factor (bFGF). The depigmented cells protrude above the RPE cell sheet and have a lower resting pHi (approximately 7.05) than the pigmented RPE cells (approximately 7.15). The majority of cells with low resting pHi express N-CAM. The difference in the resting pHi between RPEN-CAM- and NEN-CAM+ cells is not due to the N-CAM expression by NEN-CAM+ cells, as their pHi is the same as the pHi of freshly plated single "round" RPEN-CAM- cells that have not spread yet. NEN-CAM+ cells respond to bFGF with a quick and sustained pHi rise. In contrast, neither the cuboidal RPEN-CAM- cells in a colony centre nor single round RPEN-CAM- cells respond to bFGF with cytoplasmic alkalinization. RPE cells do not proliferate in response to bFGF, while NE cells respond to bFGF with a stimulation of growth. We conclude that bFGF acts not on the fully differentiated RPEN-CAM-, but only on those cells which have already started to transdifferentiate and changed their shape and (or) adhesive status.(ABSTRACT TRUNCATED AT 250 WORDS)

Calreticulin: not just another calcium-binding protein

In this paper we review some of the rapidly expanding information about calreticulin, a Ca(2+)-binding/storage protein of the endoplasmic reticulum. The emphasis is placed on the structure and function of calreticulin. We believe that calreticulin is a multifunctional Ca(2+)-binding protein and that distinct functional properties of the protein may be localized to each of the three structural domains of calreticulin. Most evidence indicates that calreticulin is a resident endoplasmic reticulum protein. However, it can also be found outside of the endoplasmic reticulum compartment, i.e. in the nuclear envelope, in the nucleus, in the cytotoxic granules in T-lymphocytes and in acrosomal vesicles of sperm cells. The evidence reviewed here clearly suggests that calreticulin has other functions in addition to its role as a Ca2+ storage protein in the endoplasmic reticulum.

Generation and characterization of antibodies to adhesion-related molecules of retinal pigment epithelial cells

We have generated antisera to pig retinal pigment epithelial (RPE) cells and to their fractionated membrane proteins. The antisera have been screened functionally by adhesion inhibition assays, and morphologically with immunofluorescence microscopy of cultured cells and frozen sections of the retina. From these sera, we have affinity purified five monospecific antibodies to the RPE surface molecules having molecular weights of 220, 180, 110, 85 and 70 kDa, which effectively inhibit cell-substratum attachment. The 220 and 85 kDa antigens are localized to focal contacts of the cultured cells and are seen in patches in the intact RPE layer in frozen sections of eye tissues. Immunofluorescence microscopy shows that the 180, 110 and 70 kDa antigens localize predominantly to cell-cell junctions. Hence, these antigens may participate in both cell-cell and cell-substratum adhesion in RPE cells. Staining patterns obtained with confocal microscopy of frozen sections of the retina demonstrate that these antibodies are RPE-specific. These adhesion-related molecules may play a role in maintenance of the morphological and functional integrity of RPE.

Involvement of non-receptor protein tyrosine kinases in expression of differentiated phenotype by cells of retinal origin

Regulation of phenotypic expression in epithelia in general, and of two epithelia of the retina, the neural retina and retinal pigment epithelium in particular, is dependent on interactions with extracellular environment. Extracellular environment may comprise acellular substrata as well as other cells. Non-receptor protein tyrosine kinases are involved in transmembrane transmission of signals from extracellular milieu, via the cytoskeleton to the nucleus. We describe distribution of these kinases in cells of retinal origin and show that two of them, pp125FAK and pp60c-src redistribute intracellularly in a differentiation-dependent manner. Next we discuss roles that adhesion-related non-receptor protein tyrosine kinases might play in phenotypic expression by the retinal epithelia.

Major retinal cell components recognized by onchocerciasis sera are associated with the cell surface and nucleoli

PURPOSE

Cellular localization of the components recognized by onchocerciasis autoantibodies has not been investigated in any detail in cultured retinal cells. This study sought to examine, in cultured retinal cells, the subcellular localization of major components that cross-react with onchocerciasis sera.

METHODS

Immunofluorescence confocal laser scanning microscopy and Western blot analysis were carried out on adult pig retinal cells.

RESULTS

The onchocerciasis sera contain antibodies cross-reacting strongly with components of the surface and nucleoli in both the cultured retinal pigment epithelial and neural retinal cells. These epitopes are not recognized by the control sera obtained from noninfected individuals residing in an onchocerciasis hyperendemic area, and from those with or without ocular disease who have never been in any of the onchocerciasis hyperendemic countries. Double-labeling immunofluorescence microscopy does not detect any colocalization of a putative onchocerciasis autoantigen, calreticulin, and those cellular components recognized by onchocerciasis sera in either cell type. Furthermore, none of the onchocerciasis sera tested recognized recombinant calreticulin by Western blot analysis.

CONCLUSIONS

Major epitopes for onchocerciasis anti-retinal autoantibodies are associated with the surface and nucleolus components of retinal cells. Interaction of the onchocerciasis antibodies with the retinal cell surface molecules may play an important role in the development of ocular diseases initiated by the damage of retinal cells. Furthermore, the finding that the cellular components recognized by onchocerciasis sera do not colocalize with calreticulin, taken together with the observation of lack of recognition of recombinant calreticulin by these sera on Western blots, suggests that calreticulin is not a major onchocerciasis autoantigen.

bFGF-induced transdifferentiation of RPE to neuronal progenitors is regulated by the mechanical properties of the substratum

The N-CAM-negative retinal pigment epithelium (RPE[N-CAM-]) can transdifferentiate into N-CAM-positive neural retina (NR[N-CAM+]) when stimulated by basic fibroblast growth factor (bFGF). In this report we examine whether the properties of the growth substrate affect the fate determination of the presumptive RPE. We used a system of biochemically related substrata with different mechanical properties, that is hydrated basement membrane gels (BM gels) and carpets of immobilized basement membrane proteins (BM carpets). We examined the effects of bFGF on RPE grown on either BM gels or BM carpets and compared them with the effects of bFGF on RPE cells grown on their native basement membrane. We show that bFGF provides the stimulus necessary to redirect the choice of fate of the presumptive RPE[N-CAM-] from the RPE pathway into the neural pathway. However, the mechanical properties of the substratum determine the extent to which a neural phenotype is expressed by the transdifferentiating cells. RPE[N-CAM-] transdifferentiates into a pleomorphic neuroepithelium[N-CAM+] on rigid, two-dimensional BM carpets, into a pseudostratified neuroepithelium[N-CAM+] on highly malleable BM gels, and into a stratified, NR[N-CAM+]-like neuroepithelium on its native basement membrane, which is of intermediate rigidity. The newly formed NR, except for the inverted polarity, has a morphology corresponding to, and expresses markers in a distribution appropriate for, the equivalent stage of retinal histodifferentiation in the embryo. We also show that bFGF is not a mitogen for the presumptive RPE cells, while it is a potent one for the presumptive NR.

Regulation of adhesion-related protein tyrosine kinases during in vitro differentiation of retinal pigment epithelial cells: translocation of pp60c-src to the nucleus is accompanied by downregulation of pp125FAK

In the present report we show that induction of expression of a differentiated phenotype in cultured retinal pigmented epithelium of chick embryo is accompanied by coordinate regulation of expression and distribution of two adhesion-related nonreceptor protein tyrosine kinases, pp60c-src and pp125FAK. pp60c-src translocates from the cell surface in flat undifferentiated cells to the nucleus in the packed differentiated cells. In contrast, pp125FAK, abundant in focal adhesions of flat undifferentiated cells, is downregulated in cells that have differentiated and packed into an epithelial sheet.

Adhesiveness and proliferation of epithelial cells are differentially modulated by activation and inhibition of protein kinase C in a substratum-dependent manner

In the present study, we have examined the regulation of attachment, onset of proliferation and the subsequent growth, in vitro, of chick retinal pigmented epithelial (RPE) cells as a function of the nature of the substratum and of either the activation or inhibition of protein kinase C (PKC). The RPE cells have an adhesive preference for protein carpets which contain laminin. This preference disappears gradually with time in culture. The adhesion of RPE cells to fibronectin is shown to be a receptor-mediated process which involves the RGD recognition signal. This study also demonstrates that a PKC activator, 12-O-tetradecanoyl-phorbol-13-acetate (TPA), affects RPE cell adhesion in a substratum-dependent manner. Exposure of RPE cells to TPA lowers the cell attachment efficacy to ECM protein substrata but does not affect cell attachment to plastic. The onset of cell proliferation is accelerated by TPA on all of the substrata tested. The minimal duration of an effective TPA pulse exerting a long-lasting influence on RPE cell proliferation is between 1.5 and 3.5 hr. Stimulation of cell proliferation by TPA in long-term cultures is independent of the nature of the growth substratum. The acceleration of the onset of cell proliferation by TPA is sensitive to 1-(5-isoquinolinesulfonyl)-2-methylpiperazine (H7), an inhibitor of conventional PKC, and thus appears to be dependent on the activation of conventional PKC. H7 also affects cell-cell contacts, causing an alteration in the shape ("squaring") of RPE cells packed into large colonies. Conversely, the effects of TPA on both the attachment and the long-term proliferation of RPE cells are not dependent a conventional PKC isotype, since H7 cannot abolish the influence of TPA on either process. We conclude that the effect of TPA on long-term proliferation of RPE cells is either dependent on a novel PKC isotype or independent of PKC.

Calcium storage in nonmuscle tissues: is the retina special?

It is now well established that calreticulin is a high capacity Ca(2+)-binding protein which is a major Ca2+ storage protein of the lumen of endoplasmic reticulum membranes in a wide variety of tissues with the exception of skeletal and cardiac muscles. However, in nervous tissue, confusion exists regarding the nature of the intracellular Ca2+ stores, as the organelle responsible for Ca2+ storage has been identified as the endoplasmic reticulum by some investigators and as the specialized organelle, calciosome by others. Calreticulin, calsequestrin, and calsequestrin-like proteins have all been, on different occasions, reported to be present in calciosomes. Cerebral and cerebellar tissues, moreover, have been shown to contain somewhat different systems of Ca(2+)-buffering proteins. In the present paper we discuss evidence that the Ca2+ storage systems of the retina may prove to be more complex than those of other neuronal tissues. Biochemical and immunocytochemical evidence indicates the presence of either an isoform of calreticulin or another protein that is antigenically similar to calreticulin, but of slightly higher molecular weight, in the endoplasmic reticulum of both neurons and Müller glia from rabbit neural retina. However, as retinal neurons express Purkinje cell markers, one may expect to observe the presence of calsequestrin in these cells as well. Secondly, antibodies against the onchocercal RAL-1 antigen recognize a protein sharing 62-65% amino acid sequence identity with calreticulin. The anti-RAL-1 antibodies show specificity for the retina. Whether or not the RAL-1 antigen is an active part of the Ca2+ storage systems of the retina remains to be verified.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of insulin and a tumour promoter, TPA, on glucose transport and metabolism in retinal pigmented epithelium in vitro

We have studied the effects of insulin, adenosine and 12-O-tetradecanoylphorbol-13-acetate (TPA) on glucose metabolism of the retinal pigmented epithelial (RPE) cells in vitro. Insulin stimulates glucose transport, glucose oxidation and lipogenesis in RPE cells. TPA at low concentrations of insulin increases the rates of glucose transport and glucose oxidation. Depletion of adenosine in RPE cells by adenosine deaminase increases the rate of both glucose transport and 14CO2 formation and improves insulin-sensitivity of both processes. The effects of TPA on RPE cells cannot be explained by the activation of protein kinase C. An alternative possibility is that the effects of TPA on insulin-stimulated glucose disposal in RPE cells is mediated by a change in adenosine concentration and/or the affinity/number of its receptors.

Calreticulin

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Widespread tissue distribution of rabbit calreticulin, a non-muscle functional analogue of calsequestrin

Calreticulin was identified in a variety of rabbit tissues by Western blot analysis. Indirect immunofluorescence studies on cultured cells or frozen sections from the corresponding tissues revealed that the protein was distributed to the endoplasmic reticulum or sarcoplasmic reticulum. Calreticulin was found to be an abundant calcium-binding protein in non-muscle and smooth muscle cells and a constituent calcium-binding protein in cardiac and skeletal muscle. From the immunoblot data, calreticulin may exist as an isoform in rabbit neural retina. The present study establishes the ubiquity of calreticulin in intracellular calcium binding.

Adhesion, spreading, and proliferation of cells on protein carpets: effects of stability of a carpet

In the present report we have investigated the role that the physical properties of substrata play in modulating the effects which components of extracellular matrix (ECM) exert on adhesion, spreading, and growth of retinal pigmented epithelial cells. By simple modifications of conditions for protein adsorption on glass we obtained a set of substrata all coated with proteins of ECM (protein carpets) but with different physical properties. Using these protein carpets we have shown that their stability (desorption rate) in tissue culture conditions varies according to the technique with which they were prepared. Both semiremovable and immobilized carpets are stable, whereas removable protein carpets desorb readily. Therefore, the protein concentration or composition or both may change with time in tissue culture depending on the technique used to prepare the carpet. In addition, efficacy of cell attachment to given protein may vary depending on whether a technique used to prepare the protein carpet involves denaturation of the protein. Adherent cells quickly remove (clear) weakly adsorbed protein carpets and it seems that the carpet removal is a mechanical process. During the carpet removal cells are rounded, which indicates that a spread cell phenotype normally associated with stress fibers and focal contacts occurs when the substratum is rigid enough to sustain cell traction. In addition, substrata lacking the rigidity to support the spread phenotype do not support cell proliferation either.

Identification and immunolocalization of calreticulin in pancreatic cells: no evidence for "calciosomes"

In the present study, we have shown that calreticulin is a major Ca(2+)-sequestering protein in pancreatic microsomes. This protein is a peripheral membrane protein and could be extracted from the microsomal membrane with carbonate buffer at pH 11.4. Calreticulin was identified in the membrane fractions by immunoblotting with a specific antibody, by a 45Ca2+ overlay technique, and by NH2-terminal amino acid analysis of the purified protein. Immunocytochemical localization of calreticulin in pancreatic acinar cells and pancreatic fibroblasts showed that the protein is localized to the ER membranes in these cells. We were unable to detect calsequestrin or any calsequestrin-like proteins in the pancreas and found no evidence for the existence of large numbers of specialized, calreticulin-containing vesicles which could be an equivalent of the calsequestrin-containing calciosomes previously reported in this tissue. Purified pancreatic calreticulin binds Ca2+ with both a low and a high capacity (approximately 1 mol of Ca2+/mol of protein and approximately 20-23 mol of Ca2+/mol of protein). The concentrations of Ca2+ required for half-maximal saturation of the low and high capacity sites were approximately 4-6 microM and approximately 1.5 mM, respectively. We conclude that calreticulin, which is confined to the lumen of the ER, plays a major role in Ca2+ storage in pancreatic cells.