©1995 by The American Society for Biochemistry and Molecular Biology, Inc.
The Mitogenic Effects of the B Chain of Fibrinogen Are Mediated through Cell Surface Calreticulin (*)

(Received for publication, May 24, 1995; and in revised form, September 4, 1995)

Andrew J. Gray (1)(§) Pyong Woo Park (2) Thomas J. Broekelmann (2) Geoffrey J. Laurent (1) John T. Reeves Kurt R. Stenmark Robert P. Mecham (2)

From the  (1)University College London Medical School, Division of Cardiopulmonary Biochemistry, London WC1E 6JJ, United Kingdom, the (2)Department of Cell Biology and Physiology, Washington University, St. Louis, Missouri 63110, and the University of Colorado Health Science Center, Division of Critical Care and Developmental Lung Biology, Department of Pediatrics, Denver, Colorado 80262

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

We have previously shown that soluble partially degraded fibrin(ogen) remains in solution after fibrin clot formation and is a potent fibroblast mitogen (Gray, A. J., Bishop, J. E., Reeves, J. T., Mecham, R. P., and Laurent, G. J.(1995) Am. J. Cell Mol. Biol. 12, 684-690). Mitogenic sites within the fibrin(ogen) molecule are located on the Aalpha and Bbeta chains of the protein (Gray, A. J., Bishop, J. E., Reeves, J. T., and Laurent, G. J.(1993) J. Cell Sci. 104, 409-413). However, receptor pathways [Abstract] through which mitogenic effects are mediated are unknown. The present study sought to determine the nature of fibrin (ogen) receptors expressed on human fibroblasts which interact with the fibrinogen Bbeta chain. Receptor complexes were isolated from I-surface-labeled fibroblasts and purified on a fibrinogen Bbeta chain affinity column. Subsequent high performance liquid chromatography and SDS-polyacrylamide gel electrophoresis analysis indicated fibrinogen Bbeta chain bound specifically to a 60-kDa surface protein. Sequence analysis of the amino terminus of this protein indicated 100% homology to human calreticulin. Immunoprecipitation experiments employing a polyclonal anti-calreticulin antibody provided further evidence that the 60-kDa protein isolated in this study was calreticulin. Further, polyclonal antibodies to human calreticulin significantly inhibited the mitogenic activity of fibrinogen Bbeta chain on human fibroblasts. The present study has shown that cell surface calreticulin binds to the Bbeta chain of fibrinogen mediating its mitogenic activity.


INTRODUCTION

Blood coagulation at the site of tissue injury is a process central to wound healing. The deposition of an insoluble fibrin matrix provides both a hemostatic plug preventing leakage of plasma components and a matrix over which cells can spread and proliferate(3) . We have previously shown that the action of thrombin on fibrinogen (in addition to the formation of insoluble fibrin) generates soluble partially degraded forms of fibrin(ogen) which are potent fibroblast mitogens (1, 4) and may further facilitate wound healing. Mitogenic sites within the fibrinogen molecule have been investigated, and we have shown both the Aalpha and Bbeta chains of fibrinogen are mitogens for human fibroblasts (2) .

The cell surface components responsible for binding Aalpha and Bbeta chains of fibrinogen are unknown. The present study sought to determine the nature of fibroblast receptor(s) involved in binding and subsequently mediating the mitogenic action of partially degraded fibrin(ogen). Our approach utilized human fetal fibroblasts which were surface-labeled with I. Membrane proteins were extracted with a mild neutral detergent, and plasma membrane components were purified on a fibrinogen Bbeta chain affinity column. Protein moieties eluted from the column were further purified by HPLC and visualized by SDS-PAGE. A 60-kDa surface protein which binds specifically to the Bbeta chain of fibrinogen was identified. Sequence analysis of the first 13 amino acids of this protein showed 100% homology with human calreticulin. Further, polyclonal antibodies to human calreticulin significantly inhibited the mitogenic activity of the fibrinogen Bbeta chain on human fetal fibroblasts.


EXPERIMENTAL PROCEDURES

Fibroblast Replication Assay

Fibroblast replication was assessed using a dye binding assay based on the uptake and subsequent release of methylene blue as described previously by Oliver et al.(5) . Human fetal lung fibroblasts (HFL-1) were plated at 5 times 10^3 cells/well in 50 µl of serum-free DMEM in 96-well plates, either 24 h before the test solutions were added or concurrently with test solutions. A 50-µl sample of test solution in serum-free medium was serially diluted across the plate; 50 µl of serum-free medium was added to 3 columns representing media controls. Plates were incubated for 48 h at 37 °C in 10% CO(2) and 100% humidity. Each assay was validated as a means of determining cell replication by direct cell counting. Counts were performed on cells stained with methylene blue prior to elution of the dye.

I Cell Surface Labeling and Extraction of Plasma Membrane Proteins

Human fetal fibroblasts (HFL-1 and IMR-90, American Tissue Type Culture Collection) were grown to confluence in roller bottles over a period of 14 to 20 days. Serum-containing cell culture media were removed, and each bottle was rinsed 5 times with 10 ml of PBS containing 1 mM Ca and 1 mM Mg. After discarding the last rinse, an additional 5 ml of PBS containing protease inhibitors was added to the cells. Cells were scraped from the bottles with a cell scraper and spun for 10 min at 100 times g. The cell pellet was reconstituted in 1 ml of PBS + protease inhibitors and placed on ice. It was important in the context of the present study to ensure that only cell surface proteins were labeled with I. To ensure that the cells remained intact prior to radiolabeling all washes were performed in PBS, pH 7.4. Additionally, cells were observed under a light microscope prior to radiolabeling, and cell membranes were found to be intact.

Glass tubes were coated with IODOGEN, and 1 ml of cell suspension was added to each tube. 500 µCi of NaI (ICN) was added, and the mixture was incubated on ice for 12 min with occasional mixing. Finally, cells were washed several times to remove free I.

Plasma membrane proteins were extracted from human fibroblasts which were grown to confluence in roller bottles and harvested as described above. The same procedure was employed for both Ilabeled cells and unlabeled cells. Cell pellets were resuspended in the neutral detergent octyl-beta-glucopyranoside + protease inhibitors (Sigma), and membrane-bound proteins were extracted overnight at 4 °C. The resulting solution was spun at 20,000 times g, and the supernatant either was used immediately in the affinity chromatography assay or stored at -70 °C.

Biotinylation of Surface Proteins

Cell surface proteins were biotinylated using a ImmunoPure Sulfo-NHS-Biotinylation Kit (Pierce).

Affinity Chromatography

Affinity chromatography was performed employing purified fibrinogen Bbeta chain (2) coupled through the carboxyl terminus to an Affi-Gel 102 matrix (Bio-Rad). 10 mg of purified Bbeta chain was dissolved in 2 ml of 8 M urea, mixed 1:1 with Affi-Gel 102, the pH was adjusted to between 4.7 and 5.0, and the mixture was stirred gently for several minutes. 5 mg of 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide coupling reagent was subsequently added, and the pH was readjusted to between 4.7 and 5.0. The reaction was allowed to proceed overnight at 4 °C with continuous stirring. The resulting complex was packed into a Bio-Rad column support and washed extensively with 50 ml of octyl-beta-glucopyranoside + PBS, pH 7.4. Plasma membrane extract was applied to the column, and bound proteins were eluted with a series of washes: 40 mM EDTA, 2 M KCl, and 8 M urea. Each fraction was concentrated in an Amicon Centricon-10 and dried in a Speed Vac.

HPLC Protein Purification

Protein fractions collected by affinity chromatography were further purified on a C4 reverse phase HPLC column. Dried samples were reconstituted in trifluoroacetic acid/water, and 100 µl were injected onto the top of the column. Proteins were eluted with 20-50% acetonitrile gradient. Fractions were subsequently collected from the column in 250-µl aliquots, and several column runs were performed on each protein sample resulting in a final fraction volume of between 1 and 2 ml. Each fraction was dried and counted in a counter. Fractions containing counts were further purified on 12.5% SDS-PAGE gels. Finally, gels were dried and signal-visualized with autoradiography. Samples which were not labeled with I were purified in an identical manner to labeled samples with the exception that 12.5% SDS-PAGE gels were blotted onto nitrocellulose and stained with Coomassie Blue.

Protein Sequence Analysis

Protein sequence analysis was performed using an ABI 473A protein Sequencer. Proteins to be sequenced were separated by SDS-PAGE, transferred to a Problot polyvinylidene difluoride membrane, and visualized with Coomassie Blue staining. Bands were excised, and the amino-terminal sequence was determined using an ABI model 473A protein Sequencer equipped with a model 610 data acquisition system.

Immunoprecipitation

Immunoprecipitation experiments were performed employing a polyclonal antibody to human calreticulin (Affinity BioReagents). Protein preparations were precleared with normal rabbit sera. Supernatant was collected and incubated on ice for 1 h with a 1:100 dilution of polyclonal calreticulin antibody. 8 mg of protein A-Sepharose (Sigma) was added to the antibody-antigen complex, and the mixture was incubated on ice for an additional 30 min. Protein A-Sepharose was pelleted and washed three times in lysis buffer. 50 µl of Laemmli sample buffer was added to the pellet, the sample was heated at 100 °C for 3 min, and the resulting supernatant was run on a 12.5% SDS-PAGE gel. Finally, the gel was dried and signal-visualized with autoradiography film.

Immunohistochemistry

Human fetal fibroblasts were plated onto 8-well chamber slides (Nunc) and left for 24 h to allow cells to adhere. Polyclonal anti-calreticulin antibodies and nonimmune controls were incubated with cells at 37 °C in DMEM for 20 min. Cells were subsequently fixed with 2% formal saline and signal-visualized with a fluorescein-conjugated secondary antibody.


RESULTS

Mitogenic Activity of Isolated Fibrinogen Bbeta Chain on Human Lung Fibroblasts

Purified fibrinogen Bbeta chain stimulated fibroblast replication in vitro (Fig. 1). Maximum simulation of fibroblasts by isolated fibrinogen Bbeta chain was about 30% above media control at a protein concentration of 1.1 times 10M. Activity returned to control levels with serial dilution. For comparison, the well characterized mitogen thrombin elicited a maximal mitogenic response of 20-30% above media control assayed under the same conditions as isolated fibrinogen Bbeta chain. Fetal calf serum (5%) elicited a mitogenic response of about 100%-150% above media control.


Figure 1: Fibroblast mitogenic activity in response to the Bbeta chain of fibrinogen. Assays were performed in serum-free conditions for 48 h. Bbeta chain was serially diluted across a 96-well tissue culture plate. The starting concentration (1) of Bbeta chain was 1.1 times 10M.



Isolation and Characterization of Cell Surface Proteins Which Bind to the Bbeta Chain of Fibrinogen

To examine the cell surface receptors which bind fibrinogen Bbeta chain, fibroblasts were surface-labeled with I, and surface proteins were extracted and passed over a fibrinogen Bbeta chain affinity column. Proteins were collected from the affinity column with a series of washes. More than 90% of bound proteins eluted with 5 ml of 40 mM EDTA. The EDTA-eluted fraction was then further purified on a C4 reverse phase HPLC column. Each fraction collected from the column was dried and counted. The bulk of I-labeled proteins eluted from the C4 column in a single radioactive peak at an elution gradient of 40% acetonitrile. Fig. 2A, tracks a-e, shows an autoradiograph of radiolabeled proteins contained in this fraction separated by SDS-PAGE. The radioactive peak collected from the HPLC column contained predominantly a single protein moiety with an apparent molecular mass of about 60 kDa.


Figure 2: I-surface-labeled 60-kDa protein eluted from a fibrinogen Bbeta chain affinity column and further purified by reverse phase HPLC. A, tracks a-e, I-surface-labeled proteins constituting the radioactive peak eluted from a C4 reverse phase HPLC column after initial purification over a fibrinogen Bbeta chain affinity column. Proteins were eluted with a 20-50% acetonitrile gradient. Tracks a-e eluted from the column with 40% acetonitrile. Fractions were dried, reconstituted in Laemmli buffer, and run on a 12.5% SDS-PAGE gel. I signal was visualized after a 48-h exposure of the dried gel to autoradiography film. B, track a shows a large scale (cold) preparation of protein visualized in track c of A. Protein moieties eluting with 40% acetonitrile were collected, dried, and further separated on a 12.5% SDS-PAGE gel. Proteins were blotted onto Problot and visualized with Coomassie Blue stain. A 60-kDa protein was observed that corresponded with the 60-kDa protein seen in A, tracks a-e. Finally, the 60-kDa protein band was cut out, and the protein sequence was determined employing a ABI protein Sequencer.



To identify the nature of the 60-kDa protein, a large scale preparation of unlabeled plasma membrane proteins was prepared using the affinity procedure described above. Purification of the 60-kDa protein was confirmed by Coomassie Blue staining of the isolated protein transferred to Problot (Fig. 2B, track a). The stained 60-kDa band was cut out and sequenced using a ABI protein Sequencer. Sequence analysis of the 60-kDa protein indicated an amino-terminal sequence which read: EPAVYFKEQFLDG. These experiments were performed on three separate preparations, and the same sequence was recorded on each occasion. A comparison of the sequence with sequences in the protein data base found 100% homology with human calreticulin.

Further experiments were performed to determine binding specificity of fibrinogen Bbeta chain to the 60-kDa protein, identified as calreticulin. Fig. 3, track a, shows the ability of CNBr fragments of fibrinogen Bbeta chain to elute calreticulin from a Bbeta chain affinity column. For comparison, also shown in Fig. 3, track b, is the 60-kDa protein eluted with 40 mM EDTA.


Figure 3: Elution of I-labeled 60-kDa protein from a Bbeta chain affinity column with fibrinogen Bbeta chain fragments and EDTA. Track a shows I-labeled 60-kDa protein eluted from a fibrinogen Bbeta chain affinity column with fibrinogen Bbeta chain fragments generated by CNBr digest. Track b shows I-labeled 60-kDa protein eluted from a fibrinogen Bbeta chain affinity column with 40 mM EDTA.



Calreticulin has previously been reported as a calcium binding protein found predominantly on the luminal side of the endoplasmic reticulum. It was therefore important for the present study to determine that calreticulin was also found on the extracellular side of the plasma membrane. Fig. 4, track a, shows an autoradiograph of I-labeled calreticulin purified from cells scraped from a tissue culture dish in the presence of protease inhibitors prior to I labeling; a clear 60-kDa band can be observed. In contrast, Fig. 4, track b, shows proteins purified in an fashion identical with those shown in Fig. 4, track a, with the exception that cells were trypsinized from tissue culture plates prior to I labeling. I-Labeled 60-kDa protein was not isolated from cells which were harvested with the serine protease trypsin.


Figure 4: Purification of 60-kDa protein from cells trypsinized from cell culture dishes prior to I labeling. Track a shows I-surface-labeled 60-kDa protein after purification over a fibrinogen Bbeta chain affinity column and a C4 reverse phase HPLC column. Cells were harvested prior to I labeling by gently scraping a subconfluent monolayer of cells from a roller bottle in the presence of protease inhibitors. Track b shows a repetition of the method used to purify the 60-kDa protein visualized in track a, with the exception that a subconfluent monolayer of cells was trypsinized from a roller bottle prior to I surface labeling. Molecular mass markers are shown along the left-hand side of the gel.



Additional experiments were performed to confirm the identity of the 60-kDa protein and to further determine its presence as a cell surface protein capable of binding to fibrinogen Bbeta chain. Fig. 5, track a, shows an autoradiograph of I-surface-labeled proteins immunoprecipitated with a polyclonal anti-calreticulin antibody. Fig. 5, track b, shows a repetition of the immunoprecipitation experiment in Fig. 5, track a, with the exception that cells were trypsinized prior to radiolabeling. The presence of a clear 60-kDa band (visualized in Fig. 5, track a) confirms that the protein isolated from plasma membranes and purified on a fibrinogen Bbeta chain affinity column is a cell surface form of calreticulin. Further, the low intensity of the 60-kDa band visualized in Fig. 5, track b, provides additional evidence that the 60-kDa protein is present on the cell surface and is thus sensitive to trypsin degradation. Tracks c and d of Fig. 5show IgG controls for both scraped and trypsinized cells, respectively.


Figure 5: Immunoprecipitation of surface-labeled calreticulin. Immunoprecipitation of surface-labeled proteins with a polyclonal anti-calreticulin antibody. Track a, immunoprecipitation with calreticulin antibodies of I-surface-labeled proteins isolated from cells scraped from a tissue culture flask in the presence of protease inhibitors prior to surface labeling. Track b, immunoprecipitation with calreticulin antibody of I-surface-labeled proteins from cells trypsinized prior to I surface labeling. Tracks c and d show normal IgG controls for tracks a and b, respectively.



In addition to surface-labeling cells with I, cells were also surface-biotinylated. Fig. 6, track b, shows biotinylated surface calreticulin immunoprecipitated with anti-calreticulin antibodies. Finally, calreticulin was visualized by immunostaining of the cell surface with polyclonal anti-calreticulin antibodies. Fig. 7A shows human fetal fibroblasts after incubation with anti-calreticulin antibodies. In contrast, Fig. 7B shows cells incubated with nonimmune IgG. Calreticulin is clearly visualized in A, and no signal was visualized with nonimmune IgG controls (B). Surface biotinylation and immunostaining provided further evidence, using two alternative surface-labeling technique, that calreticulin is present on the surface of the plasma membrane.


Figure 6: Immunoprecipitation of biotinylated calreticulin. Track b, immunoprecipitation with calreticulin antibodies of biotinylated cell surface calreticulin (surface proteins were extracted employing the methods described for Fig. 5, track a). Shown along the left-hand side of the figure are molecular mass markers (track a).




Figure 7: Immunostaining of human fetal fibroblasts for surface calreticulin. Human fetal fibroblasts were incubated with polyclonal anti-calreticulin antibodies or nonimmune IgG controls for 20 min at 37 °C in DMEM. Cells were subsequently fixed and signal-visualized with a fluorescein isothiocyanate-conjugated secondary antibody. A and B show fibroblasts incubated with polyclonal anti-calreticulin antibodies and nonimmune IgG controls, respectively.



Antibody Blocking Studies

In an attempt to determine the function of the calreticulin/fibrinogen Bbeta chain interaction, immune IgG raised against human calreticulin was employed to block the mitogenic activity of the fibrinogen Bbeta chain (Fig. 8). In this series of experiments, the Bbeta chain elicited a mitogenic response of between 63 and 42% above control. Polyclonal calreticulin antibodies significantly reduced the mitogenic activity of the Bbeta chain from 63% above media control to 33% above media control at a 1:500 dilution and from 44% above media control to 31% above media control at a dilution of 1:1000. A 1:5000 dilution of antibodies neither stimulated nor inhibited fibrinogen Bbeta chain activity. IgG controls tested over a comparable range of concentrations to those employed to test the effects of anti-calreticulin antibodies on Bbeta chain activity neither stimulated nor inhibited the mitogenic effect of the fibrinogen Bbeta chain.


Figure 8: Effects of polyclonal calreticulin antibody on the ability of fibrinogen Bbeta chain to stimulate fibroblast proliferation. Mitogenic effects on human fetal fibroblasts of fibrinogen Bbeta chain (Bbeta), Bbeta chain + anti-calreticulin IgG (c) and Bbeta chain + IgG control (i). Antibody dilutions ranged between 1:500 and 1:5000, Bbeta chain was assayed at a concentration of 2.5 times 10M in each of the three studies. Mitogenic activity was assessed with a colorimetric assay based on the uptake and subsequent release of methylene blue (see ``Experimental Procedures''). Inhibition of Bbeta chain activity by immune IgG raised against human calreticulin was significant at antibody dilutions of 1:500 and 1:1000 as determined by Duncan's New Multiple Range Test and Scheffe's S test (*, p < 0.05). Control IgG did not significantly inhibit Bbeta chain activity at any of the dilutions tested.




DISCUSSION

It is well established that partially degraded fibrin(ogen) is a fibroblast mitogen(1) , an action which is mediated in part by sites within the Bbeta chains of the molecule(2) . It remains to characterize receptors expressed by fibroblasts which interact with fibrinogen Bbeta chain and possibly mediate its biological functions. The present study isolated a membrane-bound protein which specifically bound to the Bbeta chain of fibrinogen. The purified protein displayed an apparent molecular mass of about 60 kDa as determined by SDS-PAGE analysis. Sequence analysis of the purified 60-kDa protein has shown it to have an amino-terminal sequence identical with that of calreticulin. The 60-kDa protein was further identified through immunoprecipitation experiments and immunohistochemistry employing polyclonal anti-calreticulin antibodies.

Calreticulin has been described by several independent groups as a calcium-binding protein with a molecular mass of 46 kDa(6) . The apparent anomaly between the molecular size determined by SDS-PAGE analysis and molecular size determined from cDNA is thought to be a consequence of the low isoelectric point of calreticulin which may result in its slow migration through SDS-PAGE gels(7) . In addition to the well characterized role of calreticulin as a major calcium storage protein of the endoplasmic reticulum(8) , calreticulin also displays a number of diverse activities which have direct effects on cell function. For example, a recent study by Burns et al.(9) showed that calreticulin binds to the DNA-binding domain of the glucocorticoid receptor; an event that prevented receptor-ligand interaction. These results suggest that calreticulin may play a direct role in gene transcription by regulating receptor activity. Additionally, calreticulin binds the highly conserved KXGFFKR sequence found in the cytoplasmic domain of all alpha-integrin subunits(10) , thus mediating cell attachment to the extra cellular matrix(11) . The KXGFFKR sequence found as a component structure of alpha-integrin subunits is similar to the sequence found in the DNA-binding domain of the glucocorticoid receptor. It has been speculated that these two binding events are coordinated and that calreticulin may mediate the transduction of signals from integrins to the nucleus(11) .

Calreticulin was originally thought to be confined to the endoplasmic reticulum (ER) on account of its carboxyl-terminal KDEL sequence; a sequence known to play a role in the retention of proteins within the ER(12) . It has become apparent over the last few years that, although a large proportion of intercellular calreticulin is retained within the ER, it is also found in several other locations. For example, calreticulin is found as a component of the nuclear envelope(13) , it is also associated with component proteins on the cytosolic side of the plasma membrane. Additionally, calreticulin has been identified on the cell surface of human leukocytes, platelets, and endothelial cells(14, 15) . Release of cell surface calreticulin from stimulated neutrophils is thought to play a role in some autoimmune disorders(16) .

Although there have been reports of extracellular calreticulin (14, 15, 16, 17) , it was considered important to determine that the calreticulin described in the present study was expressed on the extracellular side of the plasma membrane. The first question considered was as follows. Did the I-cell surface-labeling procedure label only surface proteins? The efficiency of cell surface labeling was verified using the protease trypsin. I-labeled 60-kDa protein was not eluted from a fibrinogen Bbeta chain affinity column when cells had been incubated with trypsin prior to I labeling. This observation suggested that iodination experiments performed in the present study labeled exclusively proteins expressed on the cell surface. Additionally, I-labeled and biotinylated surface calreticulin was immunoprecipitated with a polyclonal antibody, and a clear 60-kDa band was observed. However, immunoprecipitation of calreticulin from cells trypsinized prior to I-labeling yielded only a very small quantity of I-labeled calreticulin.

Immunostaining of cultured fibroblasts for calreticulin provided further evidence that calreticulin was present as a surface component. In this series of experiments, antibodies were incubated with live cells to ensure that cell membranes were intact and, thus, that only surface calreticulin was labeled.

Finally, polyclonal antibodies to calreticulin inhibited the mitogenic activity of fibrinogen Bbeta chain on human fetal fibroblasts. These results suggest the antibody interacts with an epitope on the cell surface, thus inhibiting cellular proliferation.

Binding specificity of the Bbeta chain of fibrinogen to calreticulin was also considered in the present study. Calreticulin was eluted from the Bbeta chain affinity column with EDTA, suggesting a cation-dependent binding event. A similar requirement for divalent cations has also been described for the interaction of calreticulin with the alpha-integrin subunit(11) . In the present study, we found that calreticulin was also eluted from a fibrinogen Bbeta chain affinity column with soluble Bbeta chain fragments indicating a competitive interaction between bound and free ligand.

The function of fibrinogen Bbeta chain/calreticulin interactions were investigated with purified IgG raised against human calreticulin. Incorporation of anti-calreticulin antibodies into the methylene blue cell replication assay significantly inhibited the mitogenic activity of the fibrinogen Bbeta chain. Further, IgG controls neither stimulated nor inhibited the mitogenic effects of the Bbeta chain.

It is becoming apparent that the role of calreticulin is more than simply one of calcium storage. The observation that a form of calreticulin is expressed on the cell surface and has the ability to trigger cell replication is in its self interesting. In the light of the present findings, it is also of interest to note that calreticulin contains a sequence which has the potential for phosphorylation by a number of kinases(18) . It has recently been observed that a simian homologue of human calreticulin is phosphorylated, a function which facilitates its binding to viral RNA(19) . It is now important to determine whether the cell surface form of calreticulin described in this study is in fact phosphorylated or is capable of phosphorylating other protein components.


FOOTNOTES

*
This work was funded by The Wellcome Trust. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
To whom correspondence should be addressed: The Division of Cardiopulmonary Biochemistry, The Rayne Institute, University College London Medical School, 5 University St., London WC1E 6JJ, UK. Tel.: 0171-380-7975; Fax: 0171-380-7973.

(^1)
The abbreviations used are: HPLC, high performance liquid chromatography; PAGE, polyacrylamide gel electrophoresis; DMEM, Dulbecco's modified Eagle's medium; PBS, phosphate-buffered saline; ER, endoplasmic reticulum.


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©1995 by The American Society for Biochemistry and Molecular Biology, Inc.