The relationship between cell proliferation and differentiation and mapping of putative dental pulp stem/progenitor cells during mouse molar development by chasing BrdU-labeling

Human dental pulp contains adult stem cells. Our recent study demonstrated the localization of putative dental pulp stem/progenitor cells in the rat developing molar by chasing 5-bromo-2’-deoxyuridine (BrdU)-labeling. However, there are no available data on the localization of putative dental pulp stem/progenitor cells in the mouse molar. This study focuses on the mapping of putative dental pulp stem/progenitor cells in addition to the relationship between cell proliferation and differentiation in the developing molar using BrdU-labeling. Numerous proliferating cells appeared in the tooth germ and the most active cell proliferation in the mesenchymal cells occurred in the prenatal stages, especially on embryonic Day 15 (E15). Cell proliferation in the pulp tissue dramatically decreased in number by postnatal Day 3 (P3) when nestin-positive odontoblasts were arranged in the cusped areas and disappeared after postnatal Week 1 (P1W). Root dental papilla included numerous proliferating cells during P5 to P2W. Three to four intraperitoneal injections of BrdU were given to pregnant ICR mice and revealed slow-cycling long-term label-retaining cells (LRCs) in the mature tissues of postnatal animals. Numerous dense LRCs postnatally decreased in number and reached a plateau after P1W when they mainly resided in the center of the dental pulp, associating with blood vessels. Furthermore, numerous dense LRCs co-expressed mesenchymal stem cell markers such as STRO-1 and CD146. Thus, dense LRCs in mature pulp tissues were believed to be dental pulp stem/progenitor cells harboring in the perivascular niche surrounding the endothelium.     

Presence of cartilage stem/progenitor cells in adult mice auricular perichondrium

Background

Based on evidence from several other tissues, cartilage stem/progenitor cells in the auricular cartilage presumably contribute to tissue development or homeostasis of the auricle. However, no definitive studies have identified or characterized a stem/progenitor population in mice auricle.

Methodology/Principal Findings

The 5-bromo-2′-deoxyuridine (BrdU) label-retaining technique was used to label dividing cells in fetal mice. Observations one year following the labeling revealed that label-retaining cells (LRCs) were present specifically in auricular perichondrium at a rate of 0.08±0.06%, but LRCs were not present in chondrium. Furthermore, LRCs were successfully isolated and cultivated from auricular cartilage. Immunocytochemical analyses showed that LRCs express CD44 and integrin-α₅. These LRCs, putative stem/progenitor cells, possess clonogenicity and chondrogenic capability in vitro.

Conclusions/Significance

We have identified a population of putative cartilage stem/progenitor cells in the auricular perichondrium of mice. Further characterization and utilization of the cell population should improve our understanding of basic cartilage biology and lead to advances in cartilage tissue engineering and novel therapeutic strategies for patients with craniofacial defects, including long-term tissue restoration.     

Allogenic tooth transplantation inhibits the maintenance of dental pulp stem/progenitor cells in mice

Our recent study suggested that allogenic tooth transplantation may affect the maintenance of dental pulp stem/progenitor cells. This study aims to elucidate the influence of allograft on the maintenance of dental pulp stem/progenitor cells following tooth replantation and allo- or auto-genic tooth transplantation in mice using BrdU chasing, immunohistochemistry for BrdU, nestin and Ki67, in situ hybridization for Dspp, transmission electron microscopy and TUNEL assay. Following extraction of the maxillary first molar in BrdU-labeled animals, the tooth was immediately repositioned in the original socket, or the roots were resected and immediately allo- or auto-grafted into the sublingual region in non-labeled or the same animals. In the control group, two types of BrdU label-retaining cells (LRCs) were distributed throughout the dental pulp: those with dense or those with granular reaction for BrdU. In the replants and autogenic transplants, dense LRCs remained in the center of dental pulp associating with the perivascular environment throughout the experimental period and possessed a proliferative capacity and maintained the differentiation capacity into the odontoblast-like cells or fibroblasts. In contrast, LRCs disappeared in the center of the pulp tissue by postoperative week 4 in the allografts. The disappearance of LRCs was attributed to the extensive apoptosis occurring significantly in LRCs except for the newly-differentiated odontoblast-like cells even in cases without immunological rejection. The results suggest that the host and recipient interaction in the allografts disturbs the maintenance of dense LRCs, presumably stem/progenitor cells, resulting in the disappearance of these cell types.     

Responses of BrdU label-retaining dental pulp cells to allogenic tooth transplantation into mouse maxilla

Recently, we demonstrated that a pulse of BrdU given to prenatal animals reveals the existence of slow-cycling long-term label-retaining cells (LRCs), putative adult stem or progenitor cells, which reside in the dental pulp. This study aims to clarify responses of LRCs to allogenic tooth transplantation into mouse maxilla using prenatal BrdU-labeling, in situ hybridization for osteopontin and periostin, and immunohistochemistry for BrdU, nestin, and osteopontin. The upper-right first molars were allografted in the original socket between BrdU-labeled and non-labeled mice or between GFP transgenic and wild-type mice. Tooth transplantation caused degeneration of the odontoblast layer, resulting in the disappearance of nestin-positive reactions in the dental pulp. On postoperative days 5–7, tertiary dentin formation commenced next to the preexisting dentin where nestin-positive odontoblast-like cells were arranged in the successful cases. In BrdU-labeled transplanted teeth, dense LRCs were maintained in the center of the dental pulp beneath the odontoblast-like cells including LRCs, whereas LRCs disappeared in the area surrounding the bone-like tissue. In contrast, LRCs were not recognized in the pulp chamber of non-labeled transplants through the experimental period. Tooth transplantation using GFP mice demonstrated that the donor cells constituted the dental pulp of the transplant except for endothelial cells and some migrated cells, and the periodontal tissue was replaced by host-derived cells except for epithelial cell rests of Malassez. These results suggest that the maintenance of BrdU label-retaining dental pulp cells play a role in the regeneration of odontoblast-like cells in the process of pulpal healing following tooth transplantation.     

Identification of label-retaining cells in nasopharyngeal epithelia and nasopharyngeal carcinoma tissues

Adult stem cells can be identified by label-retaining cell (LRC) approach based on their ability to retain nucleoside analog, such as bromodeoxyuridine (BrdU). We hypothesized that mouse nasopharynx contains a small population of epithelial stem/progenitor cells that may be detected by the LRC technique. To identify LRCs in mice nasopharyngeal epithelia, neonatal mice were intraperitoneally injected with BrdU twice daily for 3 consecutive days. After an 8-week chase, long-term BrdU-labeled LRCs (∼2% of cells) were detected in the adult mice nasopharyngeal epithelia by immunostaining with BrdU antibody and some of LRCs (∼12% of cells) were found to be recruited into the S phase of cell cycle with an additional radioactive thymidine-labeling technique, indicating that the stem cells also divide, most likely asymmetrically. To further investigate whether the LRCs existed in human nasopharyngeal carcinoma (NPC) tissues, three NPC cell lines (5-8F, 6-10B and TMNE) were labeled with BrdU in vitro and then individually engrafted into the back of nude mice, which developed tumors. Again, label-retaining stem cells were found in all the three kinds of NPC xenograft tumors (∼0.3% of cells), around 16% of which were also labeled with radioactive thymidine. Thus, this study has demonstrated for the first time the presence of epithelial LRCs in mouse nasopharyngx and human NPC tissues and these stem-like LRCs are not completely quiescent, as they will be recruited into the cell cycle to participate physiological or pathological process at any moment. More importantly, our data showed that NPC also contained stem cells, which are most likely the cause for NPC spread, metastasis and recurrence.     

Long-term label retaining cells localize to distinct regions within the female reproductive epithelium

The uterus is an extremely plastic organ that undergoes cyclical remodeling including endometrial regeneration during the menstrual cycle. Endometrial remodeling and regeneration also occur during pregnancy and following parturition, particularly in hemochorial implanting species. The mechanisms of endometrial regeneration are not well understood. Endometrial stem/progenitor cells are proposed to contribute to endometrial regeneration in both humans and mice. BrdU label retention has been used to identify potential stem/progenitor cells in mouse endometrium. However, methods are not available to isolate BrdU label-retaining cells (LRC) for functional analyses. Therefore, we employed a transgenic mouse model to identify H2B-GFP LRCs throughout the female reproductive tract with particular interest on the endometrium. We hypothesized that the female reproductive tract contains a population of long-term LRCs that persist even following pregnancy and endometrial regeneration. Endometrial cells were labeled (pulsed) either transplacentally/translactationally or peripubertally. When mice were pulsed transplacentally/translactationally, the label was not retained in the uterus. However, LRCs were concentrated to the distal oviduct and endocervical transition zone (TZ) following natural (i.e., pregnancy/parturition induced) and mechanically induced endometrial regeneration. LRCs in the distal oviduct and endocervical TZ expressed stem cell markers and did not express ERα or PGR, implying the undifferentiated phenotype of these cells. Oviduct and endocervical TZ LRCs did not proliferate during endometrial re-epithelialization, suggesting that they do not contribute to the endometrium in a stem/progenitor cell capacity. In contrast, when mice were pulsed peripubertally long-term LRCs were identified in the endometrial glandular compartment in mice as far out as 9 months post-pulse. These findings suggest that epithelial tissue of the female reproductive tract contains 3 distinct populations of epithelial cells that exhibit stem/progenitor cell qualities. Distinct stem/progenitor-like cells localize to the oviduct, endometrium, and cervix.     

Identification and characterization of label-retaining cells in mouse pancreas

Pancreatic stem cells (PSCs) may play an important role in maintaining and repairing pancreatic tissues. However, both the existence and localization of PSCs in adult mammalian pancreas still remain elusive. In order to locate the potential pancreatic progenitor/stem cells, we used the tracing label-retaining cells (LRCs) method and identified slow-cycling cells in mouse pancreas. Characterization of the LRCs revealed that the differentiation marker-negative LRCs were located not only within and around the islets but also around the acini and ducts. About 30% of the LRCs around the acini and ducts expressed c-Met, which is a putative pancreatic progenitor/stem cell marker. Moreover, the LRCs around the acini could be activated to form duct-like structures in response to pancreatic damage, and the involvement of these LRCs in the neogenesis of islets and focal areas could also be observed in acini. Our data suggest that the LRCs located around the acini and ducts may represent potential pancreatic progenitor/stem cells, and characterization of these cells may aid in further identification of the specific markers of pancreatic progenitor/stem cells.     

Mapping of BrdU label-retaining dental pulp cells in growing teeth and their regenerative capacity after injuries

Recent studies have demonstrated that human dental pulp contains adult stem cells. A pulse of the thymidine analog BrdU given to young animals at the optimal time could clarify where slow-cycling long-term label-retaining cells (LRCs), putative adult stem cells, reside in the pulp tissue. This study focuses on the mapping of LRCs in growing teeth and their regenerative capacity after tooth injuries. Two to seven peritoneal injections of BrdU into pregnant Wistar rats revealed slow-cycling long-term dense LRCs in the mature tissues of born animals. Numerous dense LRCs were postnatally decreased in number and reached a plateau at 4 weeks after birth when they mainly resided in the center of the dental pulp, associating with blood vessels. Mature dental pulp cells were stained with Hoechst 33342 and sorted into (<0.76%) side population cells using FACS, which included dense LRCs. Some dense LRCs co-expressed mesenchymal stem cell markers such as STRO-1 or CD146. Tooth injuries caused degeneration of the odontoblast layer, and newly differentiated odontoblast-like cells contained LRCs. Thus, dense LRCs in mature pulp tissues were supposed to be dental pulp stem cells possessing regenerative capacity for forming newly differentiated odontoblast-like cells. The present study proposes the new hypothesis that both granular and dense LRCs are equipped in the dental pulp and that the dense LRCs with proliferative capacity play crucial roles in the pulpal healing process following exogenous stimuli in cooperation with the granular LRCs.     

Isolation of nuclei from label-retaining cells and measurement of their turnover rates in rat colon

We describe here a new technique for isolating nuclei from long-term label-retaining cells (LRCs), a subpopulation enriched with stem cells from colon, and for measuring their proliferation rates in vivo. A double-label approach was developed, combining the use of bromodeoxyuridine (BrdU) and ²H₂O. Male Fisher 344 rats were administered BrdU in drinking water continuously for 2–8 wk. BrdU was then discontinued (BrdU washout), and animals (n = 33) were switched to ²H₂O in drinking water and killed after 2, 4, and 8 wk. Nuclei from BrdU-positive cells (LRCs) were collected by flow cytometry. The percentages of LRCs were 7 and 3.8% after 4 and 8 wk of BrdU washout, respectively. Turnover rates of LRCs were measured on the basis of deuterium incorporation from ²H₂O into DNA of LRC nuclei, as determined by mass spectrometry. The proliferation rate of the LRCs collected was 0.33–0.90% per day (half-life of 77–210 days). Significant contamination from other potentially long-lived colon cells was excluded. In conclusion, this double-labeling method allows both physical isolation of nuclei from colon epithelial LRCs and measurement of their in vivo proliferation rates. Use of this approach may allow better understanding of mechanisms by which agents induce or protect against colon carcinogenesis. carcinogenesis; deuterated water; long-term label-retaining cells; stable isotopes     

Label-retaining cells in the rat submandibular gland.

To identify stem cells in salivary glands, label-retaining cells (LRCs) were established in rat submandibular glands. Developing and regenerating glands were labeled with bromodeoxyuridine (BrdU). To cause gland regeneration, the glands were injured by duct obstruction. BrdU LRCs were observed in all the parenchymal structures except for the acinus of the glands labeled during regeneration. Among these LRCs, a few, but not many, expressed neither keratin18 (K18; an acinar/duct cell marker) nor alpha-smooth muscle actin (alphaSMA; a myoepithelial cell marker), and thus were putative stem cells. These (K18 and alphaSMA)(neg) LRCs were invariably observed in the intercalated duct and the excretory duct. In the intercalated duct, they were at the proximal end bordering the acinus (the neck of the intercalated duct). Next, to test the above identification, gland extirpation experiments were performed. LRCs were established by labeling developing glands with iododeoxyuridine (IdU) in place of BrdU. Removal of one submandibular gland forced the IdU-LRCs in the remaining gland to divide. They were labeled with chlorodeoxyuridine (CldU). The (K18 and alphaSMA)(neg) LRCs in the neck of the intercalated duct and in the excretory duct did not change in number or in IdU label. The CldU label appeared in these cells and then disappeared. These results indicate that the (K18 and alphaSMA)(neg) LRCs have divided asymmetrically and are thus considered salivary gland stem cells.     

Kinetics of Label Retaining Cells in the Developing Rat Kidneys

Background

The kidney is a specialized low-regenerative organ with several different types of cellular lineages. The BrdU label-retaining cell (LRCs) approach has been used as part of a strategy to identify tissue-specific stem cells in the kidney; however, because the complementary base pairing in double-stranded DNA blocks the access of the anti-BrdU antibody to BrdU subunits, the stem cell marker expression in BrdU-labeled cells are often difficult to detect. In this study, we introduced a new cell labeling and detection method in which BrdU was replaced with 5-ethynyl-2-deoxyuridine (EdU) and examined the time-dependent dynamic changes of EdU-labeled cells and potential stem/progenitor markers in the development of kidney.

Methods

Newborn rats were intraperitoneally injected with EdU, and their kidneys were harvested respectively at different time points at 1 day, 3 days, 1 week, 2 weeks, and 6 weeks post-injection. The kidney tissues were processed for EdU and cellular markers by immunofluorescence staining.

Results

At the early stage, LRCs labeled by EdU were 2176.0 ± 355.6 cells at day one in each renal tissue section, but dropped to 168 ± 48.4 cells by week 6. As time increased, the numbers of LRCs were differentially expressed in the renal cortex and papilla. At the postnatal day one, nearly twice as many cells in the cortex were EdU-labeled as compared to the papilla (28.6 ± 3.6% vs. 15.6 ± 3.4%, P<0.05), while there were more LRCs within the renal papilla since the postnatal week one, and at the postnatal week 6, one third as many cells in the cortex were EdU-labeled as compared to the papilla (2.5 ± 0.1% vs. 7.7 ± 2.7%, P<0.05). The long-term LRCs at 6-week time point were associated exclusively with the glomeruli in the cortex and the renal tubules in the papilla. At 6 weeks, the EdU-labeled LRCs combined with expression of CD34, RECA-1, Nestin, and Synaptopodin were discretely but widely distributed within the glomeruli; Stro-1 around the glomeruli; and α-smooth muscle actin (SMA) in arteries. Conversely, co-expression of CD34, RECA-1, and Nestin with the long term EdU-labeled LRCs was significantly lower in renal tubules (P<0.01), while Stro-1 and Synaptopodin were not detected.

Conclusion

Our data found that at 6-week time point, EdU-labeled LRCs existing in the glomeruli expressed undifferentiated podocyte and endothelial markers at high rates, while those in the renal tubules expressed Nestin and vascular markers at low rates. To understand the characterization and localization of these EdU-LRCs, further studies will be needed to test cell lineage tracing, clonogenicity and differentiation potency, and the contributions to the regeneration of the kidney in response to renal injury/repair.     

Flow cytometry-based characterization of label-retaining stem cells following transplacental BrdU labelling

A method to characterize and culture stem cells from neonate mouse epidermis after transplacental BrdU (bromo-deoxyuridine) administration is described. We have characterized stem cells by their properties viz. to retain BrdU label, adhere rapidly onto collagen-fibronectin substratum and express a specific biomarker beta-1-integrin. BrdU-labelled cells (detected using monoclonal antibody) constituted a sum of 18% of the total number of cells. The ability of freshly isolated keratinocytes [LRCs (label-retaining cells)] to bind to primary BrdU antibody or to pick up PI (propidium iodide) stain was distinguishable. Viable LRCs did not retain PI. Such cells, termed EpSC (epidermis stem cell), were PI negative and BrdU positive. EpSC constituted 6% of the total cell yield. Culture in low Ca2+ medium and susceptibility to differentiation in the presence of high Ca2+ levels further characterized the stem cells. This protocol is useful for studying transplacental carcinogenesis.     

Establishment of in vitro culture system for evaluating dentin–pulp complex regeneration with special reference to the differentiation capacity of BrdU label-retaining dental pulp cells

We have proposed the new hypothesis that dental pulp stem cells play crucial roles in the pulpal healing process following exogenous stimuli in cooperation with progenitors. This study aimed to establish an in vitro culture system for evaluating dentin–pulp complex regeneration with special reference to the differentiation capacity of slow-cycling long-term label-retaining cells (LRCs). Three intraperitoneal injections of BrdU were given to pregnant ICR mice to map LRCs in the mature tissues of born animals. The upper bilateral first molars of 3-week-old mice were extracted and divided into two pieces and cultured for 0, 1, 3, 5 and 7 days using the Trowel’s method. We succeeded in establishing an in vitro culture system for evaluating dentin–pulp complex regeneration, where most odontoblasts were occasionally degenerated and lost nestin immunoreactivity because of the separation of cell bodies from cellular processes in the dentin matrix by the beginning of in vitro culture. Numerous dense LRCs mainly resided in the center of the dental pulp associating with blood vessels throughout the experimental periods. On postoperative days 1–3, the periphery of the pulp tissue including the odontoblast layer showed degenerative features. By Day 7, nestin-positive odontoblast-like cells were arranged along the pulp–dentin border and dense LRCs were committed in the odontoblast-like cells. These results suggest that dense LRCs in the center of the dental pulp associating with blood vessels were supposed to be dental pulp stem/progenitor cells possessing regenerative capacity for forming newly differentiated odontoblast-like cells.     

Bone marrow long label-retaining cells reside in the sinusoidal hypoxic niche

In response to changing signals, quiescent hematopoietic stem cells (HSCs) can be induced to an activated cycling state and provide multi-lineage hematopoietic cells to the whole body via blood vessels. However, the precise localization of quiescent HSCs in bone marrow microenvironment is not fully characterized. Here, we performed whole-mount immunostaining of bone marrow and found that BrdU label-retaining cells (LRCs) definitively reside in the sinusoidal hypoxic zone distant from the “vascular niche”. Although LRCs expressed very low level of a well-known HSC marker, c-kit in normal circumstances, myeloablation by 5-FU treatment caused LRCs to abundantly express c-kit and proliferate actively. These results demonstrate that bone marrow LRCs reside in the sinusoidal hypoxic niche, and function as a regenerative cell pool of HSCs.     

Identification of a distinct side population of cancer cells in the Cal-51 human breast carcinoma cell line

“Side population” (SP) cells, which pump out the fluorescent dye H33342 via the ABCG2 transporter, define a putative stem/progenitor cell population in the mammary gland. Breast cancer SP cells recently isolated from the MCF-7 cell line possess similar properties and may represent stem cell-like cancer cells. This study extends SP cell analysis to a broad panel of human breast cancer cell lines and investigates the expression of differentiation-associated markers in isolated cancer SP cells. Expression of ABCG2 was determined in 16 breast cancer cell lines by quantitative RT-PCR, Western blotting and immunohistochemistry. Subsequently, all cell lines were screened for the presence of SP cells. Human breast cancer cell lines commonly express ABCG2. ABCG2-immunoreactivity was clearly restricted to rare cancer cells in several cell lines including Cal-51. Analysis of H33342-labeled Cal-51 cells revealed a small fraction of putative SP cells accounting for one percent of all cells. The genuine nature of Cal-51 SP cells was unambiguously verified by demonstrating a 30-fold increased ABCG2-expression in isolated Cal-51 SP cells. During in vitro expansion, Cal-51 SP cells generated heterologous non-SP (NSP) cells and ABCG2-expression declined dramatically. In contrast, NSP cells failed to sustain proliferation. Freshly isolated Cal-51 SP cells also exhibited increased expression of Muc1 and CALLA. Noteworthy, non-malignant mammary epithelial SP cells lack these differentiation markers, highlighting fundamental differences between non-malignant and breast cancer-derived SP cells. In summary, we established Cal-51 SP cells as a novel in vitro model to study differential gene expression in breast cancer-derived SP and NSP cells.     

Differential expression of proliferative, cytoskeletal, and adhesive proteins during postnatal development of the hamster submandibular gland

 Although the submandibular gland (SMG) plays important exocrine and endocrine roles, little is known about the molecular details underlying its development. Previously, we reported that in the postnatally developing hamster SMG, GPT, the protein product of the first N-glycosylation gene, ALG7, was an in vivo marker for salivary cell proliferation. Here we investigated the proliferative, cytoskeletal, and adhesive changes during SMG postnatal development. The cellular localization and abundance of GPT, filamentous actin, and β1 integrin receptor were examined using confocal microscopy and immunoblotting. In neonatal glands, high GPT levels marked extensive cell proliferation throughout the tissue. The apical regions of immature salivary cells displayed intense actin staining, while most of the β1 integrin was diffusely distributed throughout the tissue. As development proceeded, discrete regions of the gland expressed attenuated levels of GPT, an increased organization of actin to the cell cortex, and β1 integrin to the basal lamina. In the adult SMG, differentiated salivary cells displayed low levels of GPT and actin. While the abundance of β1 integrin remained unchanged throughout development, in the adult, it was found exclusively in regions where cells contact the basal lamina. These data indicate that SMG development entails regionalized cell proliferation and polarization, and that these processes are temporally and spatially coordinated with the establishment of stable cell-substratum interactions. Accepted: 26 October 1998     

Sca-1(pos) cells in the mouse mammary gland represent an enriched progenitor cell population

Mammary epithelium can functionally regenerate upon transplantation. This renewal capacity has been classically ascribed to the function of a multipotent mammary gland stem cell population, which has been hypothesized to be a primary target in the etiology of breast cancer. Several complementary approaches were employed in this study to identify and enrich mammary epithelial cells that retain stem cell characteristics. Using long-term BrdU labeling, a population of label retaining cells (LRCs) that lack expression of differentiation markers has been identified. LRCs isolated from mammary primary cultures were enriched for stem cell antigen-1 (Sca-1) and Hoechst dye-effluxing "side population" properties. Sca-1(pos) cells in the mammary gland were localized to the luminal epithelia by using Sca-1(+/GFP) mice, were progesterone receptor-negative, and did not bind peanut lectin. Finally, the Sca-1(pos) population is enriched for functional stem/progenitor cells, as demonstrated by its increased regenerative potential compared with Sca-1(neg) cells when transplanted into the cleared mammary fat pads of host mice.     

Age-related decline in label-retaining tubular cells: implication for reduced regenerative capacity after injury in the aging kidney

Recovery after acute kidney injury is impaired in the elderly, but the precise mechanism for such age-related incompetence remains unclear. By in vivo bromodeoxyuridine (BrdU) labeling, renal progenitor cells (label-retaining cells; LRCs) were identified in tubules of normal rat kidney and were shown to be the origin of proliferating cells after injury. In the present study, the involvement of LRCs in the age-related decline of tubular recovery after injury was examined. After 1 wk of BrdU labeling followed by a 2-wk chase period, ischemia-reperfusion injury was induced in 7-wk-, 7-mo-, and 12-mo-old rats. Age-related decreases in DNA synthesis and cell proliferation in renal tubules after injury were found. The number of LRCs also significantly declined with age. At 24 h after reperfusion, the number of LRCs significantly increased in all ages of rats tested. There was no significant difference in the ratio of LRC division among rats of different ages. The area of the rat endothelial cell antigen (RECA)-1-positive capillary network declined with age. When renal tubules isolated from rats treated with BrdU label were cocultured with human umbilical vein endothelial cells (HUVEC), the number of LRCs significantly increased compared with tubules cultured without HUVEC. These data suggest that the reduced capacity of tubular regeneration in the aging kidney is partly explained by the shortage of LRC reserves. The size of the LRC pool might be regulated by the surrounding peritubular capillary network.     

Permanence of proliferating cells in developing,juvenile and adult knee epiphyses of lizards in relation to bone growth and regeneration

The distribution of long‐labelling‐retaining cells, putative progenitor or stem cells, in the developing knees of embryo, juvenile and adult lizards has been analysed using H3‐thymidine autoradiography and 5BrdU immunohistochemistry. Proliferating cells are present in developing cartilaginous femur and tibia, especially in the epiphyses where a higher cell multiplication likely determines their typical enlarged shape in comparison with the diaphyses where chondroblast proliferation is low to absent. Sparse 5BrdU‐labelled cells remain in the articular and growth plate cartilages of the epiphyses in older stages of development and are still detected in developing epiphyses 13 days after injection of 5BrdU. This indicates they are slow‐cycling cells, a typical characteristic for progenitor or stem cells. Long retaining 5BrdU‐labelled cells remain in the articular surface also during adult life where they likely sustain the growth of long bones. Adult epiphyses show secondary ossification centres where the articular cartilage is partially or largely replaced by bone trabeculae. The damage in the epiphysis of lizards stimulates the proliferation of progenitor cells for the regeneration of new cartilaginous epiphyses. The localization of cells capable of proliferation in the epiphyses of adult femur and tibia pre‐adapts these lizards to cartilage regeneration in case of injury.