Anti-tumour activity of deer growing antlers and its potential applications in the treatment of malignant gliomas.

A recent study showed that antlers have evolved a high rate of growth due to the expression of proto-oncogenes and that they have also evolved to express several tumour suppressor genes to control the risk of cancer. This may explain why deer antler velvet (DAV) extract shows anti-tumour activity. The fast growth of antler innervation through the velvet in close association to blood vessels provides a unique environment to study the fast but non-cancerous proliferation of heterogeneous cell populations. We set out to study the anti-cancer effect of DAV in glioblastoma (GB) cell lines in comparison with temozolomide, a chemotherapeutic drug used to treat high-grade brain tumours. Here we report, for the first time, that DAV extract from the tip, but not from mid-parts of the antler, exhibits an anti-tumour effect in GB cell lines (T98G and A172) while being non-toxic in non-cancerous cell lines (HEK293 and HACAT). In T98G cells, DAV treatment showed reduced proliferation (37.5%) and colony-formation capacity (84%), inhibited migration (39%), induced changes in cell cycle progression, and promoted apoptosis. The anticancer activity of DAV extract as demonstrated by these results may provide a new therapeutic strategy for GB treatment.

Novel insights into Dhh signaling in antler chondrocyte proliferation and differentiation: Involvement of Foxa.

The desert hedgehog (Dhh) is crucial for spermatogenesis and Leydig cell differentiation, but little is known regarding its physiological function in cartilage. In this study, Dhh mRNA was abundant in antler chondrocytes, where it advanced cell proliferation concomitant with accelerated transition from the G1 to the S phase and induced elevation of the hypertrophic chondrocyte markers, Col X and Runx2. Silencing of Ptch1 resulted in appreciable Smo accumulation and enhanced rDhh stimulation of Smo, whose impediment by cyclopamine obscured the proliferative function of Dhh and alleviated its guidance of chondrocyte differentiation. Further analysis evidenced the noteworthy positive action of Smo in the bridging between Dhh and Gli transcription factors. Obstruction of Gli1 by GANT58 caused the failed stimulation of Col X and Runx2 by rDhh. Analogously, siRNA against Gli1-3 hindered chondrocyte differentiation in the context of rDhh. Simultaneously, Gli transcription factors mediated the regulation of Dhh on Foxa1, Foxa2, and Foxa3, whose knockdown impaired chondrocyte differentiation. Attenuation of Foxa antagonized the augmentation of Col X and Runx2 generated by rDhh. Collectively, Dhh signaling through its target Foxa appears to induce antler chondrocyte proliferation and differentiation.

Biological adaptations in the Arctic cervid, the reindeer (Rangifer tarandus).

The reindeer is an Arctic species that exhibits distinctive biological characteristics, for which the underlying genetic basis remains largely unknown. We compared the genomes of reindeer against those of other ruminants and nonruminant mammals to reveal the genetic basis of light arrhythmicity, high vitamin D metabolic efficiency, the antler growth trait of females, and docility. We validate that two reindeer vitamin D metabolic genes (CYP27B1 and POR) show signs of positive selection and exhibit higher catalytic activity than those of other ruminants. A mutation upstream of the reindeer CCND1 gene endows an extra functional binding motif of the androgen receptor and thereby may result in female antlers. Furthermore, a mutation (proline-1172→threonine) in reindeer PER2 results in loss of binding ability with CRY1, which may explain circadian arrhythmicity in reindeer.

Antler extracts stimulate chondrocyte proliferation and possess potent anti-oxidative, anti-inflammatory, and immune-modulatory properties.

The Sika deer antler is well known for its unique ability to regenerate repeatedly and grow rapidly. Furthermore, it is a precious traditional Chinese medicine and has been widely used for more than 20 centuries. The major bioactive components within the antlers are water-soluble proteins, polypeptides, and free amino acids. Many studies have shown that water-soluble antler extracts play pivotal roles in wound healing, immune system modulation, anti-oxidation, and anti-inflammation. However, the exact effects on chondrocytes are still largely unknown. In this study, we prepared fresh, aqueous extracts from growing deer antlers in a rapid growth stage. We isolated the chondrocytes from neonatal mouse rib cartilage and investigated the effects of antler extracts on chondrocyte viability. We also used the RNA-Seq method to analyze the gene expression pattern under antler extract treatment. We demonstrated that fresh extracts from Sika deer antlers in a rapid growth stage significantly promoted chondrocyte viability and kept chondrocytes proliferating continuously, while blocking maturation and further differentiation. Additionally, our results indicated that antler extracts might serve as a potent anti-oxidant, anti-inflammatory agent, and immune modulator to boost the abilities of chondrocytes against oxidative, inflammatory, and immune stresses. Thus, this study has greatly deepened our current knowledge of the molecular control of antler extracts on chondrocytes. It has also shed light on possible new strategies to further prevent and treat diseases of cartilage and other related diseases.

Expression and Functional Analysis of Tumor-Related Factor S100A4 in Antler Stem Cells.

Annual antler renewal is a stem cell-based epimorphic process driven by antler stem cells (ASCs) resident in antlerogenic periosteum (AP). Antlerogenic periosteal cells express a high level of S100A4, a metastasis-associated protein, which intrigued us to explore what role S100A4 could play in antler regeneration. The present study set out to investigate expression and effects of S100A4 in the ASCs and their progeny. The results showed that not only did cells from the AP express a high level of S100A4, but also the pedicle periosteum and the antler growth center. In the antler growth center, we found S100A4-positive cells were specifically located in blood vessel walls and in vascularized areas. In vitro, recombinant deer S100A4 protein stimulated the proliferation of the AP cells, promoted proliferation, migration and tube formation of human vascular endothelial cells, and enhanced migration of Hela cells, but not AP cells. These findings demonstrated that S100A4 in the ASCs may play a significant role in stimulating angiogenesis, proliferation, but not motility, of ASCs. Deer antlers offer a unique model to explore how rapid cell proliferation with a high level of S100A4 expression is elegantly regulated without becoming cancerous.

CONTROLLING ANTLER GROWTH IN A CASTRATED INDOCHINESE SIKA DEER CERVUS NIPPON PSEUDAXIS USING A COMMERCIALLY AVAILABLE TRENBOLONE ACETATE AND ESTRADIOL IMPLANT.

A captive Indochinese sika deer (Cervus nippon pseudaxis) was castrated at the age of 5 yr. The resultant abnormal antler growth over the next few years became difficult to manage from both the veterinary and husbandry standpoints. Using a commercially available trenbolone acetate and estradiol implant marketed for domestic cattle heifers, normal mineralization of the abnormal antlers was achieved along with the expected normal casting. The deer was then maintained for 6 yr using an annual implant regimen.

Direct localisation of molecules in tissue sections of growing antler tips using MALDI imaging.

The astonishing growth rate of deer antlers offers a valuable model for the discovery of novel factors and regulatory systems controlling rapid tissue growth. Numerous molecules have been identified in growing antlers using a variety of techniques. However, little is known about the spatial distribution of these molecules in situ. A technique that has the potential to help in this regard is direct proteomic analysis of tissue sections by matrix-assisted laser desorption/ionization imaging mass spectrometry (MALDI-IMS). The present study applied this technique to spatially map molecules in antler tissue sections. Two protonated molecular ions were selected: m/z 6679 and m/z 6200 corresponding to VEGF and thymosin beta-10, respectively. Superimposition of the respective ion images on to histologically stained samples showed distinct spatial distribution across the antler tissue sections which were consistent with the previous reports using in situ hybridization. Two other molecular ions specifically m/z 8100 and m/z 11,800 were also selected, corresponding to reported masses of urocortin precursor and thioredoxin, respectively. As the spatial distribution of these proteins is not specifically known, MALDI-IMS was used as a potential technique to obtain information on their distribution on antler tips. The presence of all these molecules in deer antlers were further confirmed using LC-MS/MS data. The present study also demonstrated that MALDI-IMS could be further used to image antler sections with an extended ion mass range of up to m/z 45,000, thus potentially increasing the ability to discover the distribution of a larger set of molecules that may play an important role in antler growth. We have thus demonstrated that MALDI-IMS is a promising technique for generating molecular maps with high spatial resolution which can aid in evaluating the function of novel molecules during antler growth.

Characteristics of MIC-1 antlerogenic stem cells and their effect on hair growth in rabbits.

AIM: We characterized growth factors produced by MIC-1 antlerogenic stem cells and attempted to apply those cells to stimulate hair growth in rabbits. MATERIALS AND METHODS: We evaluated the gene and protein expression of growth factors by immunocytochemical and molecular biology techniques in MIC-1 cells. An animal model was used to assess the effects of xenogenous stem cells on hair growth. In the experimental group, rabbits were intradermally injected with MIC-1 stem cells, whereas the control group rabbits were given vehicle-only. After 1, 2 and 4 weeks, skin specimen were collected for histological and immunohistochemical tests. RESULTS: MIC-1 antlerogenic stem cells express growth factors, as confirmed at the mRNA and protein levels. Histological and immunohistochemical analysis demonstrated an increase in the number of hair follicles, as well as the amount of secondary hair in the follicles, without an immune response in animals injected intradermally with MIC-1 cells, compared to animals receiving vehicle-alone. CONCLUSION: MIC-1 cells accelerated hair growth in rabbits due to the activation of cells responsible for the regulation of the hair growth cycle through growth factors. Additionally, the xenogenous cell implant did not induce immune response.

Antler development was inhibited or stimulated by cryosurgery to periosteum or skin in a central antlerogenic region respectively.

Antler development is triggered by interactions between antler stem cells resident in the antlerogenic periosteum (AP) and the niche cells in the upper portion of overlying skin mediated by diffusible molecules. These interactive cell populations are interposed by the lower portion of the skin and the subcutaneous loose connective tissue (SLCT). It is known that mechanical deletion of just the central AP (having an area equivalent to the size of a pedicle base) by cutting through the skin and SLCT effectively stimulates the marginal AP to initiate antler development. This study was designed to investigate whether the SLCT layer plays a role in antler development by acting as a physical barrier. The results showed that the marginal AP failed to give rise to an antler after the central AP was cryosurgically destroyed with the preservation of the collagen structure of the SLCT. Furthermore, antler development was significantly advanced when the collagen structures of the skin and SLCT layers were substantially attenuated by repeated sprays with liquid nitrogen while keeping the central AP intact. Therefore, we conclude that the interposing SLCT layer acts as a physical barrier between antler stem cells and the niche cell types, and that timing of antler development is primarily controlled by the permeability of the SLCT layer to the putative interactive diffusible molecules.

Gene expression of axon growth promoting factors in the deer antler.

The annual regeneration cycle of deer (Cervidae, Artiodactyla) antlers represents a unique model of epimorphic regeneration and rapid growth in adult mammals. Regenerating antlers are innervated by trigeminal sensory axons growing through the velvet, the modified form of skin that envelopes the antler, at elongation velocities that reach one centimetre per day in the common deer (Cervus elaphus). Several axon growth promoters like NT-3, NGF or IGF-1 have been described in the antler. To increase the knowledge on the axon growth environment, we have combined different gene-expression techniques to identify and characterize the expression of promoting molecules not previously described in the antler velvet. Cross-species microarray analyses of deer samples on human arrays allowed us to build up a list of 90 extracellular or membrane molecules involved in axon growth that were potentially being expressed in the antler. Fifteen of these genes were analysed using PCR and sequencing techniques to confirm their expression in the velvet and to compare it with the expression in other antler and skin samples. Expression of 8 axon growth promoters was confirmed in the velvet, 5 of them not previously described in the antler. In conclusion, our work shows that antler velvet provides growing axons with a variety of promoters of axon growth, sharing many of them with deer's normal and pedicle skin.

Antler transformation is advanced by inversion of antlerogenic periosteum implants in sika deer (Cervus nippon).

Deer antlers offer a unique model for the study of tissue-specific stem cells and organogenesis, as antler stem cells are confined to the antlerogenic periosteum (AP), a tissue that can be readily located (overlying a frontal crest) and experimentally manipulated. AP consists of an upper fibrous layer and a lower cellular layer. Tissue transplantation and membrane insertion experiments demonstrated that antler formation is triggered by the interactions between AP and the overlying skin. Interestingly, fairly normal antlers can be induced to grow by an inverted AP implant (the AP cellular layer facing the skin) at an ectopic site, raising the question whether the initial inductive signal is derived from the fibrous layer or cellular layer or both. To answer this question, in this study we used eight sika deer stag calves and selected one side of future antler growth region for implanting inverted AP and the contralateral side for noninverted AP as the control. The results showed that implantation of the AP discs in an inverted orientation generated pedicles with final height (17 ± 5.1 mm), less than half the height of those formed from the noninverted AP implants (45 ± 11.7 mm). Critically, antler transformation was initiated from a shorter pedicle, which was formed from the region where the AP cellular layer was brought in close proximity to the overlying skin. Therefore, the AP cellular layer, as opposed to the AP fibrous layer, is likely to be the main source of the initial inductive molecules for antlerogenesis.

Stem cells responsible for deer antler regeneration are unable to recapitulate the process of first antler development-revealed through intradermal and subcutaneous tissue transplantation.

Antlers offer a unique model for the study of whether regeneration recapitulates development in a mammalian organ. Research, to date, supports the full recapitulation in antler, but a recent report that subcutaneously transplanted (ST) pedicle periosteum (PP) failed to induce that ectopic antler formation could argue against recapitulation, as antlerogenic periosteum (AP) can readily do so. However, it was not clear in that study whether the result was caused by inability of the PP to interact with the skin or owing to failure to create the required close contact to it. This study was designed to clarify this uncertainty by adopting intradermal transplantation (IT) to achieve the required close contact without the need for significant mass expansion. The results showed that IT of 1/8 of the original AP mass or more was sufficient for antler induction, whereas ST of 1/4-AP or less could not do so within 2 years. The minimum amount of AP required for antler induction using the IT approach was somewhere between 1/8 and 1/12-AP (<30 mg). The results further demonstrated that IT of 62-84 mg PP failed to induce ectopic antler formation, even if the PP had fused with the surrounding skin. Because this mass of PP was 2-3 times the minimum amount of AP required for antler induction, we conclude that PP does not recapitulate AP in induction of ectopic antler development. It is likely that PP has been restricted for antler regeneration and lost the potential to initiate antler development.

Testosterone, but not IGF-1, LH, prolactin or cortisol, may serve as antler-stimulating hormone in red deer stags (Cervus elaphus).

The role of androgens and insulin-like growth factor 1 (IGF-1) in antler growth has been disputed. We predicted that the secretory of IGF-1 may be associated with an acceleration of body growth rather than with antler growth. Furthermore we anticipated a relationship between the increase of testosterone and the progress of antler growth. If IGF-1 is involved in the stimulation of antler growth, this should be more obvious in young than in mature stags. Eight two-year-old red deer stags (Cervus elaphus), and twelve adult red deer stags were blood sampled and the length of their velvet antlers was measured in one-week intervals during the period of antler growth. Concentrations of testosterone, cortisol, IGF-1, luteinizing hormone (LH), and prolactin were determined in plasma by enzyme immunoassay or radioimmunoassay. Antler growth per day was primarily dependent on changes in testosterone concentration per day in both groups of stags. As expected, only in two-year-old stags we detected a possible role of IGF-1 in the antler growth regulation, but that was not in agreement with previously published studies. Nevertheless, this effect was still utilized in interaction with testosterone. In addition to total antler length, only concentrations of testosterone and LH were significantly higher in adult males in comparison to two-year-old males. Our present results lead us to conclude that it is not IGF-1 but testosterone which is responsible for the intensity of antler growth in subadult and adult red deer stags.

Development of a nude mouse model for the study of antlerogenesis--mechanism of tissue interactions and ossification pathway.

In a previous study (Li et al., 2001. J Exp Zool 290:18-30) a nude mouse model was established to investigate deer antler development. In that study we found nude mice could support the singularly implanted antlerogenic periosteum (AP) to form pedicle-like, but not antler-like, bony protuberances. To further develop the model and at the same time to use the updated model for the investigation of antler formation, three experiments were carried out in this study. The results showed that (1) antler-like protuberances were successfully induced on the nude mouse heads via subcutaneous co-transplantation of AP and deer skin, and subsequent exposure through wounding of the deer xenografts; (2) deer skin epidermis and its attached half thickness of dermis were sufficient to interact with the AP, and the interactions were capable of transforming adult scalp skin into velvet; (3) the putative initial inductive molecules were primarily derived from the AP cellular layer, rather than fibrous layer; (4) initiation of the ossification center in the avascular cartilage of each mouse "antler" took place via metaplasia, rather than classical endochondral ossification. Further research is required to identify means for effective stimulation of calcification of the "mouse antlers" in order to create the opportunity to investigate antler regeneration using the nude mouse model. Overall, the nude mouse model, once further developed, has the potential to become a powerful tool to study underlying mechanism of antlerogenesis and organogenesis/regeneration in general.

Experimental application of xenogenous antlerogenic cells in replacement of auricular cartilage in rabbits.

BACKGROUND: Regenerative medicine in the recent years aims at explaining involvement of stem cells in regenerative processes and applying this knowledge in fulfilling human needs to find new, more efficient therapeutic methods. Growing antlers constitute a model organ for examining regeneration processes of tissues because they are the only mammalian appendages capable of regeneration. The rate of growth of deer antlers makes them one of the quickest growing structures in mammals. The cells taking part in this process have a considerable proliferating potential. The aim of the study was to analyze the possibility of using xenogenous antlerogenic cells (AC) in regeneration of cartilaginous tissues in non-immunosuppressed animals. METHODS: We undertook to use a xenogenous implant consisting of cultured antlerogenic mesenchymal cells suspended in hemostatic sponge in the reconstruction of lesions of ear cartilage in nine rabbits. A surgical site was prepared half-way up the outer, dorsal part of the right ear. About 1 cm from the free edge of the ear, a centrally peduncled flap of skin and perichondrium was prepared, measuring 1.5 cm x 1.5 cm. The exposed cartilage was excised in an area of about 1 cm x 1 cm. In the operated rabbits, in the prepared perichondrial pocket, we placed a flake of Spongostan saturated with the suspension of AC. Xenogenous cell survival and regeneration abilities were determined by histologic, immunohistochemical, and electron microscopy analysis of the grafts. RESULTS: In each case, healing occurred properly and neither local inflammation, necrosis nor implant rejection was observed. The hyaline cartilage lesion was replaced by new fibrous cartilage. This is similar to the histologic process occurring in growing deer antlers. The histologic, immunohistochemical, and electron microscopy analysis demonstrated the presence (and thus possible participation) of exogenous cells in the reconstructive process. At the same time, the immune response was very weak, which was confirmed by immunohistochemical reactions. CONCLUSION: Implanted antlerogenic cells were not rejected and possibly took part in the reconstruction of missing sections of the scaffolding of the rabbits' ear cartilages (although the mechanism is yet unknown). Low immunogenicity of AC, simplicity, efficiency, and low costs of production of implant material are the benefits of this method. Further research should unequivocally answer the question whether the MIC-1 cells are or are not the long-sought-after ideal material for the reconstruction of cartilaginous tissue lesions in various species, including human.

The distribution of the growth factors FGF-2 and VEGF, and their receptors, in growing red deer antler.

The cellular distributions of the growth factors FGF-2 and VEGF, and their receptors FGFR1, FGFR2 and FGFR3, and VEGFR-2 respectively, were visualized by immunohistochemistry and light microscopy in sections of growing red deer antler. Both of these signalling systems were widely expressed in the integument and osteocartilaginous compartments. FGF-2 was found in the same cells as all three FGFRs, indicating that FGF signalling may be principally autocrine. The patterns of labelling for VEGF and its receptor were similar to those seen for FGF-2 and FGFR-3, in both compartments. Our data are consistent with the findings of others in suggesting that FGF-2 induces expression of VEGF, to stimulate and maintain high rates of neovascularisation and angiogenesis, thereby providing nutrients to both velvet and bone as they rapidly grow and develop. The presence of FGF and VEGF and their receptors in epithelial cells suggests that these signalling systems play a role in skin development, raising the possibility that one or both may be involved in the close coupling of the coordinated growth of the integument and osteocartilage of antler, a process which is poorly understood at present.

Nerve growth factor mRNA expression in the regenerating antler tip of red deer (Cervus elaphus).

Deer antlers are the only mammalian organs that can fully regenerate each year. During their growth phase, antlers of red deer extend at a rate of approximately 10 mm/day, a growth rate matched by the antler nerves. It was demonstrated in a previous study that extracts from deer velvet antler can promote neurite outgrowth from neural explants, suggesting a possible role for Nerve Growth Factor (NGF) in antler innervation. Here we showed using the techniques of Northern blot analysis, denervation, immunohistochemistry and in situ hybridization that NGF mRNA was expressed in the regenerating antler, principally in the smooth muscle of the arteries and arterioles of the growing antler tip. Regenerating axons followed the route of the major blood vessels, located at the interface between the dermis and the reserve mesenchyme of the antler. Denervation experiments suggested a causal relationship exists between NGF mRNA expression in arterial smooth muscle and sensory axons in the antler tip. We hypothesize that NGF expressed in the smooth muscle of the arteries and arterioles promotes and maintains antler angiogenesis and this role positions NGF ahead of axons during antler growth. As a result, NGF can serve a second role, attracting sensory axons into the antler, and thus it can provide a guidance cue to define the nerve track. This would explain the phenomenon whereby re-innervation of the regenerating antler follows vascular ingrowth. The annual growth of deer antler presents a unique opportunity to better understand the factors involved in rapid nerve regeneration.

Identification of differentially expressed genes in the developing antler of red deer Cervus elaphus.

Understanding the molecular mechanisms underlying bone development is a fundamental and fascinating problem in developmental biology, with significant medical implications. Here, we have identified the expression patterns for 36 genes that were characteristic or dominant in the consecutive cell differentiation zones (mesenchyme, precartilage, cartilage) of the tip section of the developing velvet antler of red deer Cervus elaphus. Two major functional groups of these genes clearly outlined: six genes linked to high metabolic demand and other five to tumor biology. Our study demonstrates the advantages of the antler as a source of mesenchymal markers, for distinguishing precartilage and cartilage by different gene expression patterns and for identifying genes involved in the robust bone development, a striking feature of the growing antler. Putative roles for "antler" genes that encode alpha-tropomyosine (tpm1), transgelin (tagln), annexin 2 (anxa2), phosphatidylethanolamine-binding protein (pebp) and apolipoprotein D (apoD) in intense but still controlled tissue proliferation are discussed.

Expression of VEGF and pleiotrophin in deer antler.

Deer antlers represent a unique model of mammalian regeneration in that they cast and fully regenerate every year. The deer antler thus provides a fascinating model of both rapid angiogenesis and chondrogenesis and the opportunity to investigate unique growth regulatory processes. One such phenomenon is the presence of vascularized cartilage in the growing antler tip-unlike other cartilage, which is typically avascular. The mechanisms by which blood vessels grow in the cartilage as well as the factors that drive antler extension at approximately 1 cm a day have been hitherto largely unknown. The aim of this study was to determine the expression of VEGF and pleiotrophin within the growing antler tip. We isolated cervine VEGF121 and VEGF165 from deer antler and found that mRNA is produced for VEGF in the precartilage and cartilage regions. By in situ hybridization, we examined whether the VEGF receptors Flt-1 and KDR are present in deer antler and found only KDR mRNA within the endothelial cells of the precartilage region. This finding is compatible with VEGF having an angiogenic effect within antler. Pleiotrophin mRNA was found in the vascular smooth muscle cells of the dermis, thus supporting a possible role in vascular growth. High levels of pleiotrophin mRNA were also detected in the precartilage region with possible implications for both angiogenesis and chondrogenesis. This is the first report of cervine angiogenic growth factors within the growing antler tip.