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Distribution and Variable Expression of Secretory Pathway Protein Reticulocalbin in Normal Human Organs and Non-neoplastic Pathological Conditions

Takeaki Fukuda, Hiroshi Oyamada, Takuma Isshiki, Masahiro Maeda, Takashi Kusakabe, Ayumi Hozumi, Tomiko Yamaguchi, Toshihiko Igarashi, Hidehiro Hasegawa, Tsutomu Seidoh and Toshimitsu Suzuki

Second Department of Pathology, Fukushima Medical University School of Medicine, Fukushima, Japan (TF,KO,TIsshiki,TK,AH,TY,TSuzuki); Division of Histopathology, Central Hospital of Niigata Agriculture Association, Nagaoka, Japan (TIgarashi,HH); and Immunobiological Laboratories, Fujioka, Gunma, Japan (MM,TSeidoh)

Correspondence to: Takeaki Fukuda, MD, Second Department of Pathology, Fukushima Medical University School of Medicine, Hikarigaoka 1, 960-1245, Fukushima, Japan. E-mail: doraemon{at}fmu.ac.jp

	Summary

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Reticulocalbin (RCN) is one member of the Ca²⁺-binding proteins in the secretory pathway and is localized in the endoplasmic reticulum. RCN may play a role in the normal behavior and life of cells, although its detailed role remains unknown. Overexpression of RCN may also play a role in tumorigenesis, tumor invasion, and drug resistance. The new antibody for human RCN is used in the distribution of RCN in normal human organs of fetuses and adults with or without inflammation. Immunohistochemical examination demonstrated a broad distribution of RCN in various organs of fetuses and adults, predominantly in the endocrine and exocrine organs. However, RCN expression was heterogeneous in each constituent cell of some organs. Among non-epithelial organs, vascular endothelial cells, testicular germ cells, neurons, and follicular dendritic cells showed strong staining. Plasma cells were the only RCN-positive cells among hematopoietic and lymphoid cells. In inflammatory conditions, RCN expression was enhanced in both epithelial and non-epithelial cells. Heterogeneous expression of RCN indicates that the amount of RCN needed for cell behavior and life may be variable, depending on each cell type and, therefore, RCN may be helpful in establishing the cell origin of neoplasms in some organs. However, further study is needed to establish the significance of RCN in tumorigenesis and in some peculiar features of neoplasms. (J Histochem Cytochem 55:335–345, 2007)

Key Words: reticulocalbin • overexpression • cellular localization • secretory pathway • immunohistochemistry

	Introduction

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Ca²⁺ PLAYS A FUNDAMENTAL ROLE in cells as a secondary messenger in the regulation of many processes such as exocytosis, signal transduction, contraction, apoptosis, and gene expression. The proteins involved in Ca²⁺-regulated processes in the cytosol are mainly high-affinity Ca²⁺-binding proteins such as troponin C, calmodulin, parvalbumin, and intestinal Ca²⁺-binding protein (Strynadka and James 1989). In the endoplasmic reticulum (ER), Ca²⁺-binding proteins such as endoplasmin, calsequestrin, calnexin, and ERP72 are of low affinity with a high capacity (Meldolesi and Pozzan 1998).

A similar Ca²⁺-binding protein localized in the secretory pathway was initially found in the mouse teratocarcinoma cell line and was designated as reticulocalbin (RCN) (Ozawa and Muramatsu 1993). Subsequently, a human RCN gene was cloned from the human transitional cell carcinoma cell line (Ozawa 1995). RCN also possesses multiple EF-hand motifs and localizes strictly in the ER. At present, in addition to RCN, some RCN family proteins are identified in both vertebrates and invertebrates (Honore and Vorum 2000). Unfortunately, the fundamental properties of these RCN family proteins are still unknown, but they may play an important role in the maintenance of normal cell behavior and life because deletion of a region containing the RCN gene is lethal for mice (Kent et al. 1997).

To understand the pathophysiological roles of RCN, it is inevitably required to examine the expression of RCN in normal tissues and changes under various pathological conditions. We will describe the application of a recently established monoclonal antibody against RCN, demonstrating the heterogeneous cytoplasmic expression of RCN in various cell types of each organ and discuss the implication of RCN expression for pathophysiological roles.

	Materials and Methods

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Cell Lines and Tissues
The human lung adenocarcinoma cell line (LAC-1), human acute myelogenous leukemia cell line (KY-821), and human ovarian cancer cell line (FOC3) were maintained in our laboratory and used in the analysis of RCN mRNA and Western blotting. Ethical approval was obtained from the Fukushima Medical University local research ethics committee, and informed written consent was obtained from patients. Normal human tissues were obtained from autopsy cases and surgically resected organs. Elements from fetuses at 8 to 12 weeks gestation were obtained from uterine contents upon spontaneous abortion from unknown etiologic factors. All tissues were fixed with 10% buffered formalin and embedded in paraffin using routine methods.

Antibodies
The monoclonal antibody to RCN (clone 6A1; IBL, Takasaki, Japan) was used as described elsewhere (Hirano et al. 2005). The monoclonal antibody to Ki-67 was purchased from Immunotec (Marseille, France).

Extraction of RNA
Total RNA was extracted using the acid–phenol–chloroform method as described elsewhere. RT-PCR was carried out using Takara Ver. 2.1 RT-PCR kit (Takara Co.; Shiga, Japan). Primers used in this study were described by Liu et al. (1997) as follows: RCN, 5'-CCAGGACGGGAAGTTAGACAAAGACAAAGATGA-3', 5'-ATTACTGCCTCCCTCAACCCACTCACC-3', ß-actin, 5'-TGACGGGGTCACCCACACTGTGCCCATCTA-3', 5'-CTAGAAGCATTTGCGGTGGACGATGGAGGG-3'. These primers were all purchased from Bekkusu Co. (Tokyo, Japan). Cycling reactions were performed with an Astek DNA thermal cycler (Fukuoka, Japan). PCR reaction consisted of a denature time of 1 min at 94C, annealing time of 2 min at 50C, and an extension time of 2 min at 72C, with a final extension of 10 min at 72C at the end of 30 cycles. PCR products were applied to 1.2% agarose gel.

Western Blotting
Cells of each cell line were homogenized in a lysis buffer containing 0.1% SDS and protease inhibitors (Proteinase Inhibitors Set; Roche Applied Science, Tokyo, Japan). The supernatants were mixed with a sample buffer in a 2:1 ratio. Protein concentration was determined using the Bradford method, and 50 µg protein from each sample was subjected to SDS-PAGE and then blotted onto a PVFD membrane (Hybond P; Amersham Biosciences, Arlington, IL). The membrane was incubated with diluted anti-RCN antibody (1:2000 in PBS) overnight at 4C, followed by washing with PBS containing 1% NP40 twice, and subsequent washing with PBS containing 0.05% Tween 20 three times. Subsequently, the membrane was incubated with anti-mouse rabbit antibody coupled with horseradish peroxidase (Nichirei Co.; Tokyo, Japan). Peroxidase reaction products were visualized using the ECL Plus detection system (Amersham Biosciences).

Immunohistochemistry
Detailed immunohistochemical procedures have been described elsewhere (Kusakabe et al. 2000). In brief, 4-µm-thick sections were deparaffinized, rehydrated in graded ethanols, treated with 3% hydrogen peroxide in methanol for 30 min to block endogenous peroxidase, and then treated with 5% skim milk (Yukijirushi Co.; Sapporo, Japan) in PBS for 60 min to avoid nonspecific absorption of immunoglobulin. Concentration of the primary RCN antibody was 0.05 µg/ml, and diluted anti Ki-67 (1:100 with PBS) was used. Sections were incubated in an electronic oven for 15 min in 0.01 M citrate buffer, pH 6.0, to retrieve the antigen. All slides were incubated overnight with the antibody at 4C, followed by incubation with biotin-labeled anti-mouse IgG (Nichirei Co.) for 60 min, and then streptavidin-conjugated peroxidase (Histofine Kit; Nichirei Co.) for 60 min at room temperature. Localization of RCN was visualized with 5 mg diaminobenzidine (Dojin; Kyoto, Japan) of NaN₃/dl in 0.05% H₂O₂. Nuclei were counterstained with 1% hematoxylin.

Specificity of the primary antibody was confirmed by omission of the primary antibody and by use of preimmune mouse immunoglobulin for the first step of the immunostaining procedure. In addition, because full-length RCN DNA has been cloned (Hirano et al. 2005), recombinant RCN was purified and used for absorption of the primary antibody. Sections of lung cancer and breast cancer were used as positive controls (Liu et al. 1997; Hirano et al. 2005). In addition, because the FOC3 ovarian cancer cell line showed expression of RCN mRNA, a section obtained from serous papillary ovarian carcinoma was also used as a control.

	Results

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Specificity of Anti-RCN Antibodies and Validity of Immunoreaction
Results of RT-PCR demonstrated a 573-bp band in LAC-1 and FOC3 cell lines and a fainter similar band in the KY-821 cell line (Figure 1 ).

View larger version (16K): [in this window] [in a new window]   Figure 1 PCR products. Lane 1, marker; Lane 2, KY-821; Lane 3, LAC-1; Lane 4, FOC3. LAK-1 and FOC3 demonstrate strong expression of reticulocalbin (RCN) mRNA, and KY-821 does weakly.

View larger version (23K): [in this window] [in a new window]   Figure 2 Lane 1, marker; Lane 2, KY-821; Lane 3, LAC-1; Lane 4; FOC3; Lane 5, marker; Lane 6, colon; Lane 7, liver; Lane 8, testis; Lane 9, pancreas. Corresponding to PCR results, LAC-1 and FOC3 apparently express RCN, but KY-821 does not.

View larger version (81K): [in this window] [in a new window]   Figure 3 Adenocarcinoma of the lung (A), invasive breast cancer (B), and serous papillary adenocarcinoma of the ovary (C) show strong staining of RCN.

View larger version (128K): [in this window] [in a new window]   Figure 4 RCN is expressed in various fetal organs. Ependymal cells, neuroblasts, and glial cells in brain (A). Liver cells (B). Renal tubules (C). Adrenal cortical cells (D). Chondrocytes (E). Osteoblasts (F). Endocardium (G). Skeletal muscle cells (H). Hematopoietic cells in the liver (B), glomeruli (C), and adrenal medullary cells (D) are largely negative.

View larger version (124K): [in this window] [in a new window]   Figure 5 Cells of various endocrine organs with the exception of the thyroid gland show strong staining of RCN. (A) Pituitary gland. (B) Thyroid gland. (C) Parathyroid gland. (D) Adrenal gland. (E) Islet of the pancreas. (F) Corpus luteum. (G) Chorionic villi. (H) Seminiferous tubules of the testis.

View larger version (120K): [in this window] [in a new window]   Figure 6 Similarly, epithelial cells in various organs stain positive to various degrees. (A) Neck zone of gastric foveolar epithelium. (B) Duodenal epithelium. (C) Liver. (D) Alveolar epithelium. (E) Mammary gland. (F) Kidney. (G) Endometrial gland. However, mature foveolar epithelium (A), pyloric gland (A), duodenal gland (B), acini of the pancreas (Figure 5E), and proximal tubules of the kidney (F) are negative or weakly positive in a small number of these. A small number of adipocytes and fibroblasts and vascular endothelial cells are positive for RCN (H).

View larger version (112K): [in this window] [in a new window]   Figure 7 Sinus cells of the spleen also show strong staining (A). Reactive fibroblasts under inflammatory conditions display intense RCN expression (B). Smooth muscle cells are positive in a dotted pattern (C). Hematopoietic cells are largely negative, except for plasma cells that show strong positivity (D,E). In lymph nodes, follicular dendritic cells and sinus endothelial cells show strong and weak positive stains, respectively, but lymphocytes are entirely negative (F). In the central nervous system, most neurons and astrocytes, especially reactive astrocytes, are positive for RCN, but Purkinje cells and oligodendroglia are negative (G–I).

	Discussion

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RCN is a Ca²⁺-binding protein containing EF-hand motifs and is localized in the ER. Mammalian RCN was initially discovered in mice and detected in different types of cultured cells (Ozawa and Muramatsu 1993). Subsequent research in humans has demonstrated the ubiquitous expression of RCN mRNA in various organs (Ozawa 1995). Although the exact functions of RCN remain unknown, it may play important roles in the maintenance of normal cell behavior and cell life because homozygous deletion of the RCN gene is lethal for mice (Kent et al. 1997). However, the amount of RCN may be at low levels because most RCN family proteins were detected at low levels in various organs (Honore and Vorum 2000). Overexpression of RCN has been reported in human hepatocellular carcinoma cell lines (Yu et al. 2000), suggesting a close correlation between overexpression of RCN and malignant transformation. In addition, ERC55, one of the RCN family proteins, was reported to play an important role in the oncogenesis of human cervical carcinomas infected by the papilloma virus (Chen et al. 1995). Furthermore, Liu et al. (1997) reported that the mammary cancer cell line with an aggressive nature expressed RCN, but non-invasive lines did not. Hirano et al. (2005) reported decreased RCN expression in cisplatin-resistant human lung cancer. In this context, the study of RCN expression in each cell in normal organs is important to understand pathophysiological roles under various pathological conditions and its implications in oncogenesis of RCN.

In addition to RCN, the RCN family proteins include ERC55 (Weis et al. 1994), crocalbin (Hseu et al. 1999), Cab45 (Vorum et al. 1998), and calumenin (Koivu et al. 1997). RCN and ERC55 are strictly localized to the ER, Cab45 is localized to the Golgi complex, and calumenin is distributed throughout the whole secretory pathway. These proteins are all ubiquitously expressed in various human organs, as in the same manner of RCN. However, because heterogeneous expression of these proteins has been demonstrated by Northern blotting (Weis et al. 1994; Ozawa 1995; Koivu et al. 1997), it is possible that each of the RCN family proteins may be expressed at different levels among the various organs or cells. Unfortunately, because there is no report of the detailed study on the RCN family proteins in cell levels, the expression and amount of the RCN family proteins in each constituent cell of various organs remain obscure. We believe that the new monoclonal antibody for RCN used in this study recognizes RCN specifically because of complete absorption with recombinant RCN, different amino acid residues of immunogen from other RCN family proteins, and the positive expression in the cytoplasm of each cell but not in the Golgi complex.

Because RCN plays a role in the mechanism of normal cell behavior, it is reasonable that RCN mRNA be detected in various human organs. However, slight heterogeneity of RCN mRNA was demonstrated, i.e., there were lower levels in the brain and kidney when compared to other organs examined (Ozawa 1995). This finding prompts us to consider that expression of RCN may be different in cells from various organs. Because RCN is a specific protein localized in secretory pathways, strictly in ER, it is likely that cells with synthesis and/or secretion functions for various substances have more amounts of RCN compared with cells that are comparatively at rest. Indeed, cells from various endocrine organs are strongly positive for RCN, except for thyroid gland cells that showed no or extremely weak positive staining. Epithelial cells in a wide range of various organs also expressed RCN to various degrees, with the exception of squamous cells. These findings indicate that RCN plays an important role in synthesis and/or secretion functions in various types of epithelial cells. In addition, because epithelial cells with no or weak RCN expression under normal conditions, such as uterine cervical glands, showed enhanced expression of RCN under inflammatory conditions, RCN levels needed for cell behavior vary under normal conditions. Unexpectedly, epithelial cells from some types of organs, including those from the pancreatic acinus and from the fundic, pyloric, and duodenal glands, showed no or weak staining of RCN despite their active synthesis and secretion functions. This finding leads us to consider another possibility that other RCN family protein may function predominantly in some types of cells.

A positive immunoreaction for RCN in some types of non-epithelial cells provides us some new aspects on cell behavior. Vascular endothelial cells can produce some substances through various types of stimulation. However, strong expression of RCN indicates the active synthesis and secretion functions of vascular endothelial cells, even under normal conditions. The exact role of RCN in vascular endothelial cells remains obscure at the present time, but RCN may be useful as a marker for vascular endothelial cells such as CD34 or CD31. Although fibroblast and adipocyte are considered as relatively resting cells, a small number of fibroblasts and adipocytes are positive for RCN, probably reflecting their function of synthesis and secretion of collagen and fat to maintain normal architectures. In addition, diffuse and strong positive immunoreaction for RCN of activated fibroblasts, vascular endothelial cells in the inflammatory lesions, and fibrosis around cancer may reflect their active work in repairing destroyed tissues.

Strong staining of RCN in neurons in any brain and spinal cord sites is of particular interest because these lack endocrine and exocrine functions. However, because neurons can produce various substances including neurotransmitters, strong expression of RCN represents active synthesis functions. Nonetheless, medullary cells from the adrenal gland were entirely negative for RCN despite their evident synthesis and secretion of adrenalin and noradrenalin. Purkinje cells in the cerebellum and ganglion cells in sympathetic nerves were also negative for RCN. At this time, the significance of heterogeneous RCN expression in neurons from different sites remains obscure. On the other hand, the different expression of RCN in glial cells is available for a differential diagnosis of brain tumors.

We have initially speculated that hematopoietic cells may strongly express RCN because of their high proliferating activity. Unexpectedly, most hematopoietic and lymphoid cells, including immature hematopoietic cells of each cell line and transformed lymphocytes, are entirely negative for RCN. Indeed, KY-821 expressed a lower level of RCN mRNA, but Western blotting failed to show RCN bands, indicating an extremely small amount of RCN that could not be detected using these methods. Among hematopoietic cells, only plasma cells were positive for RCN, representing its synthesis and secretion functions for immunoglobulins. In the lymph nodes, follicular dendritic cells are strongly positive for RCN. Follicular dendritic cells are antigen-presenting cells for B cells and have a synthesis or secretion function for some substances such as cytokines (Park et al. 1999,2004), suggesting the role of RCN in secretion function. Despite high proliferating activity of lymphocytes in germinal centers, they are entirely negative for RCN. These findings indicate that RCN may be useful as a new marker for plasma and dendritic cells and for their neoplasms.

We have also speculated that cells with high proliferating activity also strongly express RCN because of active synthesis of various substances in such cells. Indeed, foveolar epithelial cells from the neck zone of the stomach, as well as testicular germ cells, are positive for RCN. However, immature hematopoietic cells and follicular transformed lymphocytes are completely negative for RCN, although they showed a high Ki-67 index. In addition, the Ki-67 index was very low in most cells that strongly expressed RCN. Thus, RCN expression is closely associated with synthesis and/or secretion functions but not with proliferating activities in each cell.

In conclusion, heterogeneity of RCN expression in constituent cells in some organs indicates that RCN expression may be related to functions of each cell and available for establishing cell origin and differential diagnoses of some types of tumors, although an extensive distribution of RCN has been demonstrated in various normal organs. Weis et al. (1994) proposed that the members of RCN family proteins might regulate Ca²⁺-dependent activities in the ER by modulating the function of other proteins. Indeed, it is reported that ERC55 interacts with the vitamin D receptor (Imai et al. 1997) and the transforming oncoprotein, E6, from papillomavirus (Chen et al. 1995). Research on the interaction between RCN and other proteins including other RCN family proteins is important to understand the role in malignant transformation. Furthermore, our preliminary examination demonstrates no correlation between RCN expression and invasiveness of breast cancers with or without stromal invasion (unpublished data), whereas the mammary cancer cell line with an aggressive nature expressed RCN but non-invasive lines did not (Liu et al. 1997). Further study is needed to establish a correlation between RCN expression and more special features of tumor cells, such as invasiveness or drug resistance.

	Footnotes

 
Received for publication February 6, 2006; accepted November 30, 2006

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This Article Abstract Full Text (PDF) All Versions of this Article: jhc.6A6943.2006v1 55/4/335    most recent Alert me when this article is cited Alert me if a correction is posted Citation Map Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Fukuda, T. Articles by Suzuki, T. Search for Related Content PubMed PubMed Citation Articles by Fukuda, T. Articles by Suzuki, T. Social Bookmarking                      What's this?

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