Printer Friendly

Immunolocalization of CD 34 positive progenitor cells in healthy human gingiva- a pilot study.

Background & objectives: The gingiva is a tissue with a high turnover rate of both epithelial and connective tissue cells. In an attempt to identify the possible source of cells which maintain the tissue turnover, we used CD 34, a well established marker of peripheral blood stem cell in healthy human gingiva to determine the origin of progenitor cells in healthy gingiva.

Methods: Healthy human gingival samples (n=15) were collected from patients undergoing orthodontic extraction. Immunohistochemistry was done on 5 micron paraffin fixed section using the primary antibody CD34 and a universal secondary immunoperoxidase kit. The sections were examined for a golden brown stain indicative of a positive staining.

Results: Of the 15 samples 12 demonstrated a positive staining for the endothelial cells. Of these 12 samples, 11 demonstrated positive staining for stromal and paravascular cells and 10 a positive staining for the basal epithelium layers.

Interpretation & conclusions: The presence of CD 34 positive cells in gingiva in stromal, paravascular location, and basal layer of the gingival epithelium was demonstrated. We speculate that these could be fibroblastic progenitors originating from the peripheral blood stem cells and the positivity stained epithelial cells could be gingival epithelial stem cells.

Key words CD 34 expression--gingival--immunohistochemistry--progenitor cells


Healing of periodontal tissues destroyed by periodontal disease does not usually result in the regeneration of the periodontium. One of the often repeated reasons is the lack of progenitor cell populations capable of restoring the different tissues of the periodontium (1). The fibroblast is the predominant cell type in the soft connective tissue of the periodontium. These cells were described as the architect, builder and caretaker of the perodontum (2). It is not clear whether a single progenitor cell for fibroblasts, osteoblasts and cementoblasts exists in the adult periodontal tissue (3). Several early studies have focused on the identification of progenitor cell populations in the periodontal ligament of experimental animals (4,5). The lack of specific markers for the fibroblast progenitors has hampered the precise identification of the origin and location of these cells. It has been suggested (3) that the cells of fibroblastic series may resemble, other well described self renewal systems in mammals, such as the skin, liver, peripheral blood, etc. CD 34 is a surface glycophosphoprotein expressed on haemopoietic stem and progenitor cells, small vessel endothelial cells and embryonic fibroblasts (6). CD 34 positivity has been demonstrated for fibroblasts and stromal cells in tissues such as skin (7), thyroid gland (8), testicular stroma (9) and also in the oral tissues like sub mandibular gland (10), and oral mucosa (11). The gingiva is a highly vascular tissue. The progenitors in gingiva may be arising from the peripheral blood haemopoietic stem cells which are CD 34 positive. To test the above hypothesis, CD 34 was used as a marker in the present study to identify putative progenitor cells in the healthy human gingiva and their location. The objective was to determine the possible origin of progenitor cells in healthy human gingiva and its implications in regeneration of the periodontium.

Material & Methods

The subjects who gave informed consent were selected, the others were not included. A total of twenty patients were chosen based on inclusion and exclusion criteria. The small sample size is because the study is a pilot study. No special procedure was followed for randomization. All the subjects had visited the Out Patient Department of Oral Surgery, Sri Ramachandra Dental College, Porur, Chennai, during April to August 2005 for the purpose of extraction of teeth for orthodontic purposes. Healthy, non smoker individuals, who had not undergone any periodontal treatment in the past six months were selected. Among these patients, those who had healthy gingiva as determined by clinical findings such as colour, consistency, absence of bleeding on probing, absence of probing depth/loss of attachment were included in the study. Informed written consent was obtained from each patient prior to sample collection. The study has been approved by Institutional Ethics Committee of the Sri Ramachandra University. The healthy gingival samples were collected by surgical excision of a part of the papilla either distal or mesial to the tooth to be removed. The gingival samples were washed in sterile saline to remove the blood and fixed with 4 per cent buffered formalin for 24 h (12) following which these were embedded in paraffin wax. The embedding in paraffin wax and subsequent steps of tissue sectioning and staining were performed in the Pathology Division of Bharat Scans, Chennai. Two 5 [micro]m thick sections were taken on 3-aminopropyltriethoxysilane (APES) (Sigma, USA) coated slides, one of which was used for hematoxylin and eosin (H&E) (Merck, Germany) staining, the other used for immunohistochemistry. The sections were deparrafinized and re-hydrated and antigen retrieval (by microwave processing) was performed. The primary antibody used was the antibody to CD 34 class III epitope (Chemicon International, USA Catalog No- CBL 555). The primary antibody was diluted with phosphate buffered saline, pH 7.4 to obtain an end dilution of 1: 20 (13). A Universal Secondary lmmuno-peroxidase Kit was used (B-SAP Universal Staining Kit- Span Diagnostics). It contains the secondary antibody tagged with peroxidase and also the substrate for the enzyme. Following staining, the sections were examined under the microscope (Zeiss Microscope-Axiostar Pius with attached Samsung Photomicrography equipment, Romania) for a golden brown stain which is indicative of positive staining. A section of a pyogenic granuloma obtained from lip lesion was used as a positive control specimen for the antibody to CD 34. A drop of phosphate buffered saline (pH 7.4) was used instead of the primary antibody in the negative control specimens. Counting of cells in the positively stained sections was done under 100 X oil immersion. The results were expressed as the number of positively stained cells per 10 high power fields (modification of the method described by Mesa et al (12)). Basically, in the modified method, the counting was done for 10 consecutive high power fields.


Of the 15 healthy gingival samples, 12 exhibited a positive staining for the CD 34 antigen. Eleven of these 12 samples demonstrated the presence of positively stained stromal/paravascular cells in the connective tissue (Fig. 1), and ten demonstrated positive staining for the basal and parabasal layers of the epithelium (Fig. 2). All the 12 samples demonstrated a positive staining for the endothelial cells. Cell membrane positivity for the CD 34 antigen was detected in the basal and parabasal layers of the epithelium. Of the ten positive samples, four exhibited a focal positive staining, whereas six exhibited a uniform staining of the entire basal layer. Of the eleven samples that stained positive for the connective tissue cells, six demonstrated more number of stromal cells than paravascular cells, and four demonstrated more number of para-vascular cells, with one section showing equal distribution of cells in the paravascular and stromal locations. Some cells had a fibroblastic morphology, whereas the others had a round or oval shape.


The positive control sample (pyogenic granuloma) demonstrated a positive staining of the endothelial cells (Fig. 3) and the negative control sample was characterized by complete absence of the golden brown stain (Fig. 4).


Of the two prominent fibroblast populations in the periodontium- the gingival and periodontal ligament fibroblasts, the origin of gingival fibroblast is less clear. Tencate and co-workers (14) suggested that gingival fibroblasts may be derived from the dental follicle cells or from the non-odontogenic gingival connective tissue. However, the origin of these cells in the adult periodontium is not known. The gingival epithelium as well as connective tissue have a very high turnover rate and new cells are constantly produced to replace cells, which are lost through cell death or migration. Thus, existence of a lineage of cells, which constantly replenish the fibroblast population, cannot be doubted.

Krause and co-workers (15) have shown that a single donor haemopoietic stem cell (IISC) could do more than just repopulate the marrow and haemopoietic system in the recipient irradiated mice. They found epithelial cells derived from the donor stem cells in the lungs, gut, and skin of the recipient mice. The most well characterized marker for the peripheral blood stem cells in humans as well as other mammals has been the sialomucin CD 34. Berardi et al (16), found that CD 34 is expressed on a population of pluripotent progenitors that can be enriched from the human bone marrow. In another study Schmidt et al (17) determined that CD 34 positive fibrocytes in the peripheral blood were precursors of bronchial fibroblasts.

A paravascular location for the fibroblast progenitors has been described by Nemeth et al (18) in the gingiva of the cynomolgus monkey. An earlier work by Pender et al (19) did not describe any paravascular location but identified two distinct progenitor connective tissue cell populations in the rat gingiva; one population was located in the mid papilla region and the other close to the epithelial attachment and cementum. Our study showed that CD 34 positive cells were present in the healthy human gingiva; similar to lower species, some of these cells had a paravascular location whereas some demonstrated a stromal location. Three of the 15 gingival samples were not stained. This could possibly be due to technical errors in processing or these sections might not have contained the target cells.

CD 34 positive cells have been identified to be markers for stem cells in the epidermis of mouse skin (20,21). Song et al (22) studied the pathogenesis of Pterygium; a proliferative disease affecting the conjuctiva of humans. They hypothesized that adult stem cells from human bone marrow contributed to the development of Pterygium. They found that the basal layer epithelial cells were CD 34 positive in addition to being positive to a few other markers. In our study, we found cell membrane positivity for the CD 34 antigen in the basal and parabasal layers of the gingival epithelium.

The present study had certain limitations, such as the lack of use of negative markers (Thy-1, c-kit etc.) which would have more definitively established the presence of stem cells of haemopoietic origin.

In conclusion, in this pilot study, we demonstrated the presence of CD 34 positive cells in the healthy human gingiva. These cells in the paravascular location could be fibroblast progenitors and the possible precursors of these progenitors could be the peripheral blood stem cells. The results of this preliminary study warrant further investigation.

Received November 21, 2007


(1.) Pitaru S, Mc Culloch CAG, Narayanan S. Cellular origins and differentiation control mechanisms during periodontal development and wound healing. J Periodont Res 1994; 29 : 81-94.

(2.) Lekic P, Mc Culloch CAG. Periodontal ligament cell population: the central role of fibroblasts in creating role of fibroblasts in creating a unique tissue. Anat Rec 1996; 245 : 327-41.

(3.) Mc Culloch CAG, Bordin S. Role of fibroblast subpopulations in periodontal physiology and pathology. J Periodont Res 1991; 26 : 144-54.

(4.) Gould TRL, McIcher AM, Brunette SM. Migration and division of progenitor cells populations in the periodontal ligament after wounding. J Periodont Res 1980; 15 : 20-42.

(5.) Mc Culloch CAG. Progenitor cell populations in the periodontal ligament of mice. Anat Rec 1985; 211: 258-62.

(6.) Brown J, Greaves MF, Molgaard HV. The gene encoding the stem cell antigen CD 34 is conserved in mouse and expressed in hemopoietic progenitor cells lines, brain and embryonic fibroblasts. Int Immunol 1991; 3: 175-84.

(7.) Nickoloff BJ. The human progenitor cell antigen (CD34) is localized on endothelial cells, dermal dendritic cells and peri-follicular cells in formalin--fixed normal skin, and on poliferating endothelial cells and stromal spindle--shaped cells in Kaposi's Sarcoma. Arch Dermatol 1991; 127: 523-9.

(8.) Yamazaki K, Eyden BP. Interfollicular fibroblasts in the human thyroid gland, recognition of a CD 34 positive stromal cell network communicated by gap junctions and terminated by autonomic nerve endings. J Submicrosc Cytol Pathol 1997; 29 : 461-76.

(9.) Kuroda N, Toi M, Nakayama H, Miyazaki E, Yamamoto M, Hayashi Y, et al. The distribution and role of myofibroblasts and CD 34 -positive stromal cells in normal pancreas and various pancreatic lesions. Histol Histopathol 2004; 19 : 59-67.

(10.) Yamazaki K, Eyden BP. Ultrastructural and immunohistochemical studies of intralobular fibroblasts in human submandibular gland: the recognition of a " CD 34 positive reticular network connected by gap junctions. J Submicrosc Cytol Pathol 1996: 28 : 471-83.

(11.) Barth PJ. Schenck zu Schweinsberg T, Ramaswamy A, Molt R. CD 34+ fibrocytes, alpha- smooth muscle antigen-positive myofibroblasts, and CD 117 expression in the stroma of invasive squamous cell carcinomas of the oral cavity, pharynx, and larynx. Virchows Arch 2004; 444 : 231-4.

(12.) Mesa F, Aguilar M, Gonzalez-Moles MA, Guerrero A, Sanchez- Alvarez JC, Del Moral RGE, et al. Vigabatrin-induced modification of Ki-67 expression in gingival epithelium: immunohistochemical study of a short series. J Periodont Res 2004; 39 : 66-71.

(13.) Kuroda N, Nakayama H, Miyazaki E, Toi M, Hiroi M, Enzan H. The distribution of CD34 positive stromal cells and myofibroblasts in colorectal carcinoid tumors. Histol Histopathol 2005; 20 : 27-33.

(14.) Tencate AR, Mills C, Solomon G. The development of the periodontium. A transplantation and autoradiographic study. Anat Rec 1971; 170: 365-79.

(15.) Krause DS, Theise ND, Collector MI, Henegariu O, Hwang S, Gardner R, et al. Multi organ, multi lineage engraftment by a single bone marrow derived stem cell. Cell 2001; 105 : 369-77.

(16.) Berardi A, Wang A, Levine J, Lorez P, Scadden D. Functional isolation and characterization of human hemopoietic stem cells. Science 1995; 267 : 104-8.

(17.) Schmidt M, Sun G, Stacey MA, Mori L, Mattoli S. Identification of circulating fibrocytes as precursors of bronchial myofibroblasts in asthma. J Immunol 2003; 171 : 380-9.

(18.) Nemeth E, Kulkarni GV, Mc Culloch CAG. Disturbances of gingival fibroblast population homeostasis due to experimentally induced inflammation in the Cynomolgus monkey (Macaca fascicularis): potential mechanism of periodontal disease progresson. J Periodont Res 1993; 28 : 180-90.

(19.) Pender N, Heaney TG, Pycock D, West CR: Progenitor connective tissue cell populations in the gingival papilla of the rat. J Periodont Res 1988; 23 : 175-81.

(20.) Yano S, Ito S, Fujimoto M, Hamazaki TS, Tamachi K, Okochi H. Characterization and localization of side population cells in mouse skin. Stem Cells 2005; 23 : 834-41.

(21.) Amoh Y, Li L, Katsuoka K, Penman S, Hoffman RM. Multipotent nestin-positive, keratin-negative hair follicle bulge stem cells can form neurons. Proc Natl Acad Sci USA 2005; 102 : 5530-4.

(22.) Song YS, Ryu YH, Choi SR, Kim JC. The involvement of adult stem cells originated form the bone marrow in the pathogenesis of Pterygia. Yonsei Med J 2005; 46 : 687-92.

Reprint requests: Dr Suresh R. Rao, Principal, Professor & Head, Department of Periodontics, Sri Ramachandra Dental College Sri Ramachandra University, No-1, Ramachandra Nagar, Porur, Chennai 600 116, India e-mail:

Vamsi Lavu, Padmavathy R. * & Suresh R. Rao

Department of Periodontics, Sri Ramachandra Dental College, Sri Ramachandra University & * Department of Pathology, Royapettah Government Hospital, Chennai, India
COPYRIGHT 2009 Indian Council of Medical Research
No portion of this article can be reproduced without the express written permission from the copyright holder.
Copyright 2009 Gale, Cengage Learning. All rights reserved.

Article Details
Printer friendly Cite/link Email Feedback
Author:Lavu, Vamsi; Rao, Padmavathy R.; Rao, Suresh R.
Publication:Indian Journal of Medical Research
Article Type:Report
Date:Jun 1, 2009
Previous Article:Influence of dietary calcium content on intestinal permeability in rat.
Next Article:Gender differences in sexual behaviour among people living with HIV in Chennai, India.

Terms of use | Privacy policy | Copyright © 2021 Farlex, Inc. | Feedback | For webmasters |