Immunolocalization of c‐myc‐positive cells in lizard tail after amputation suggests cell activation and proliferation for tail regeneration

After tail amputation in lizard, a regenerative response is elicited leading to the formation of a new tail. The stimulation of the proliferation process may involve the proto‐oncogene c‐myc. The immunocytochemical analysis detects the c‐myc protein few days after wound in free cells accumulating over the injured tissues of the tail stump. Western blot detects a protein band at 68–70 kDa that is more intense in the regenerating blastema than in normal tail tissues. Nuclei positive for the c‐myc protein are seen in mesenchymal‐like cells located among muscles, connectives and fat tissues of the tail stump 4 days postamputation. Proliferating cells labelled for 5BrdU are seen at 4 days postamputation and are sparse in the mesenchyme of the regenerating blastema formed at 12 days postamputation. Fine immunolocalization of the c‐myc protein shows it is mainly located over euchromatin or poorly condensed chromatin to indicate gene activation. The study correlates the detection of the c‐myc protein with activation of cell division in the injured tissues leading to the formation of the regenerative blastema. The lizard c‐myc protein probably activates a controlled proliferation process through a mechanism that can give information on the uncontrolled process occurring in cancer.     

Endoplasmin regulates differentiation of tonsil-derived mesenchymal stem cells into chondrocytes through ERK signaling

It is well-known that some species of lizard have an exceptional ability known as caudal autotomy (voluntary self-amputation of the tail) as an anti-predation mechanism. After amputation occurs, they can regenerate their new tails in a few days. The new tail section is generally shorter than the original one and is composed of cartilage rather than vertebrae bone. In addition, the skin of the regenerated tail distinctly differs from its original appearance. We performed a proteomics analysis for extracts derived from regenerating lizard tail tissues after amputation and found that endoplasmin (ENPL) was the main factor among proteins up-regulated in expression during regeneration. Thus, we performed further experiments to determine whether ENPL could induce chondrogenesis of tonsil-derived mesenchymal stem cells (T-MSCs). In this study, we found that chondrogenic differentiation was associated with an increase of ENPL expression by ER stress. We also found that ENPL was involved in chondrogenic differentiation of T-MSCs by suppressing extracellular signal-regulated kinase (ERK) phosphorylation.     

Pathogenic stimulation of intestinal stem cell response in drosophila

Stem cell‐mediated tissue repair is a promising approach for many diseases. Mammalian intestine is an actively regenerating tissue such that epithelial cells are constantly shedding and underlying precursor cells are constantly replenishing the loss of cells. An imbalance of these processes will lead to intestinal diseases including inflammation and cancer. Mammalian intestinal stem cells (ISCs) are located in bases of crypts but at least two groups of cells have been cited as stem cells. Moreover, precursor cells in the transit amplifying zone can also proliferate. The involvement of multiple cell types makes it more difficult to examine tissue damage response in mammalian intestine. In adult Drosophila midgut, the ISCs are the only cells that can go through mitosis. By feeding pathogenic bacteria and stress inducing chemicals to adult flies, we demonstrate that Drosophila ISCs in the midgut can respond by increasing their division. The resulting enteroblasts, precursor cells for enterocytes and enteroendocrine cells, also differentiate faster to become cells resembling enterocyte lineage. These results are consistent with the idea that Drosophila midgut stem cells can respond to tissue damage induced by pathogens and initiate tissue repair. This system should allow molecular and genetic analyses of stem cell‐mediated tissue repair. J. Cell. Physiol. 220: 664–671, 2009. © 2009 Wiley‐Liss, Inc.     

Immunohistochemical distribution of sulfhydryl oxidase in the human testis

Summary Sulfhydryl oxidase (SOx) is an enzyme that catalyzes the oxidation of sulfhydryl compounds. It is present in mitochondria of certain testicular cells at specific stages of functional activation. In the mature human testis moderate SOx immunoreactivity is found in Leydig cells, and lacking in Sertoli and in peritubular cells. The A_dark spermatogonia usually contain immuno-reactive mitochondria, while in A_pale spermatogonia immunoreactivity is mostly low. In stage V of spermatogenesis, A_pale spermatogonia were found containing immunoreactive material. Leptotene (stages IV and V) and zygotene (stage VI) primary spermatocytes display a moderate immunoreaction. It is strongest in pachytene spermatocytes of stages I–IV, decreases in stage V, and is low during diakinesis and in secondary spermatocytes. Late spermatids usually show a stronger immunoreactivity than early spermatids. At stage V of spermatogenesis the late spermatids contain only few immunoreactive particles. Spermatozoa are free of SOx-immunoreactive mitochondria. In residual bodies small amounts of SOx-immunoreactive particles are seen. Compared to rat and hamster testis, SOx immunoreactivity of the human testis is less clearly stage-dependent and it is not confined to certain germ cell stages. As deduced from the findings in patients with spermatogenic disorders, the SOx immunoreactivity of spermatogonia in human testis seems to be of diagnostic relevance.     

c-fos和c-myc在北方山溪鲵精子发生中的表达

用免疫组织化学方法检测原癌基因cf-os和c-myc蛋白在北方山溪鲵(Batrachuperus tibetanus)精子发生中的表达定位。结果显示,在精原细胞缓慢增殖期,8、9月,FOS阳性反应物出现在精原细胞的胞质及核膜外,10、11月,FOS在少量精原细胞的胞核中表达。在精原细胞快速增殖期,即翌年4月,FOS定位在精原细胞的胞质中;5月,FOS在大量的胞核中强阳性表达;6月,FOS定位于部分精母细胞核质和核膜下;7月,FOS在一些精子细胞的核质和核膜下表达。MYC在8、9月的部分精原细胞胞质中表达较弱,在101、1月阳性反应出现在个别精原细胞的核质中。翌年4月,MYC在精原细胞核周围的胞质中表达;5月在大量的精原细胞核膜下有强表达;6月,MYC在一些精母细胞核膜下表达;7月,MYC在部分精子细胞的核膜下弱表达。结果表明,北方山溪鲵的原癌基因cf-os和c-myc表达大强度在生精细胞发育中呈阶段性,表达的强度和细胞数量与细胞增殖的速度相一致。FOS和MYC在精原细胞内从胞质向胞核的转移与细胞快速增殖的时期相吻合。说明cf-os和c-myc对精原细胞有丝分裂有促进作用,并参与精母细胞成熟分裂的调控。     

Immunolabelling for RhoV and actin in early regenerating tail of the lizard Podarcis muralis suggests involvement in epithelial and mesenchymal cell motility

Immunolabelling for RhoV and actin in early regenerating tail of the lizard Podarcis muralis suggests involvement in epithelial and mesenchymal cell motility. Acta Zoologica, Stockolm. Immunolabelling for RhoV and α‐smooth muscle actin, genes that are highly expressed in the regenerating tail of lizards, shows that a main protein band immunolabelled for RhoV is seen at 65–70 kDa and only a weak band at 22–24 kDa. This suggests that alteration occurred during extraction or is due to biochemical processing of the protein. RhoV immunolabelled cells are present in apical and proximal regenerating epidermis during scale neogenesis. The apical ependyma is labelled but labelling fades and disappears in medial‐proximal regions, near the original spinal cord. Differentiating muscles and cartilage show low labelling. Ultrastructural immunolocalization of RhoV in wound keratinocytes shows labelling in regions containing actin filaments that associate with tonofilaments and desmosomes while a low labelling is present in mesenchymal cells. Filamentous regions of the nucleus, nuclear membrane and the nucleolus are immune‐labelled for RhoV. Similar localization is seen for actin that is present along the perimeters of keratinocytes associated with tonofilaments, in elongations of mesenchymal cells, in muscle satellite cells, endothelial and pericytes of blood vessels. It is suggested that RhoV and actin are associated in the dynamic cytoskeleton needed for the movements of epidermal and mesenchymal cells and in endothelial cells forming new blood vessels.     

Molecular cloning and localization of a CEACAM2 isoform,CEACAM2‐L,expressed in spermatids in mouse testis

Carcinoembryonic antigen (CEA) family, a subgroup of the immunoglobulin (Ig) superfamily, is divided into two sub‐families: the CEA‐related cell adhesion molecules (CEACAM) and the pregnancy‐specific glycoproteins. The isoform CEACAM2 is expressed in mouse testis; in this study, we identified a novel isoform of Ceacam2, Ceacam2‐Long (Ceacam2‐L). CEACAM2‐L is different from CEACAM2 in that it has much longer cytoplasmic tail region. Ceacam2‐L starts to appear faintly in mouse testis after 3 weeks of postnatal development, and its expression level increased after 5 weeks. Immunoblot analysis confirmed the expression of CEACAM2‐L in the seminiferous epithelium of mouse testis. Immunohistochemical data showed that CEACAM2‐L was not observed on spermatogonia, spermatocytes, round spermatids, or Sertoli cells, but was seen at the plasma membrane of elongating spermatids in contact with extended cytoplasmic processes of Sertoli cells. CEACAM2‐L was not detected at the head region of elongating spermatids, where the apical ectoplasmic specialization is constructed. These data suggest that CEACAM2‐L might be a novel adhesion molecule contributing to cell‐to‐cell adhesion between elongating spermatids and Sertoli cells within the seminiferous epithelium. Mol. Reprod. Dev. 79: 843–852, 2012. © 2012 Wiley Periodicals, Inc.     

Telomere length in male germ cells is inversely correlated with telomerase activity

Telomeres, the noncoding sequences at the ends of chromosomes, progressively shorten with each cellular division. Spermatozoa have very long telomeres but they lack telomerase enzymatic activity that is necessary for de novo synthesis and addition of telomeres. We performed a telomere restriction fragment analysis to compare the telomere lengths in immature rat testis (containing type A spermatogonia) with adult rat testis (containing more differentiated germ cells). Mean telomere length in the immature testis was significantly shorter in comparison to adult testis, suggesting that type A spermatogonia probably have shorter telomeres than more differentiated germ cells. Then, we isolated type A spermatogonia from immature testis, and pachytene spermatocytes and round spermatids from adult testis. Pachytene spermatocytes exhibited longer telomeres compared to type A spermatogonia. Surprisingly, although statistically not significant, round spermatids showed a decrease in telomere length. Epididymal spermatozoa exhibited the longest mean telomere length. In marked contrast, telomerase activity, measured by the telomeric repeat amplification protocol was very high in type A spermatogonia, decreased in pachytene spermatocytes and round spermatids, and was totally absent in epididymal spermatozoa. In summary, these results indicate that telomere length increases during the development of male germ cells from spermatogonia to spermatozoa and is inversely correlated with the expression of telomerase activity.     

Temporal distribution of 5BrdU-labelled cells suggests that most injured tissues contribute proliferating cells for the regeneration of the tail and limb in lizard

After tail and limb amputation in lizard, injection of 5BrdU for 6 days produces immunolabelled cells in most tissues of tail and limb stumps. After further 8 and 16 days, and 14 and 22 days of regeneration, numerous 5BrdU-labelled cells are detected in regenerating tail and limb, derived from most stump tissues. In tail blastema cone at 14 days, sparse-labelled cells remain in proximal dermis, muscles, cartilaginous tube and external layers of wound epidermis but are numerous in the blastema. In apical regions at 22 days of regeneration, labelled mesenchymal cells are sparse, while the apical wound epidermis contains numerous labelled cells in suprabasal and external layers, indicating cell accumulation from more proximal epidermis. Cell proliferation dilutes the label, and keratinocytes take 8 days to migrate into corneous layers. In healing limbs, labelled cells remain sparse from 14 to 22 days of regeneration in wound epidermis and repairing tissues and little labelling dilution occurs indicating low cell proliferation for local tissue repair but not distal growth. Labelled cells are present in epidermis, intermuscle and peri-nerve connectives, bone periosteum, cartilaginous callus and sparse fibroblasts, leading to the formation of a scarring outgrowth. Resident stem cells and dedifferentiation occur when stump tissues are damaged.     

The regenerating tail of lizard transits through a tumour-like stage represented by the regenerative blastema

Review. The regenerating tail of lizard transits through a tumour-like stage represented by the regenerative blastema. Acta Zoologica (Stockolm). Molecular studies on lizard tail regeneration indicate that the blastema stage is a tumour-like outgrowth capable of self-regulate to produce a new tail. Various oncogenes and tumour suppressors are expressed, and their proteins are localized in specific regions of the growing blastema. SnoRNAs are exclusively overexpressed in the tail blastema suggesting changes in ribosome translation efficiency in blastema cells, like in cancer. Blastema cells secrete high levels of hyaluronate and adopt an anaerobic metabolism (Warburg effect). These studies indicate that the lizard blastema represents a unique case among terrestrial vertebrates of physiological tumour remission. Mesenchymal cells and fibroblasts forming the blastema are turned within 1–2 months into a functional organ, the tail. In vitro studies on isolated mesenchymal cells from the regenerative blastema shows that these cells do not undergo contact inhibition but continue proliferation after confluence, and contain nestin, vimentin and K17. After 2–3 weeks they stratify into 5–7 layers forming a pellicle of loose connective tissue. Future molecular studies on genes and proteins that allow the control of growth in the lizard blastema may help to determine how lizards turn a tumour into a new organ with numerous differentiated and functional tissues, providing clues on cancer growth regulation.     

Calcium-dependent actin filament-severing protein scinderin levels and localization in bovine testis, epididymis, and spermatozoa

We assessed the levels and localization of the actin filament-severing protein scinderin, in fetal and adult bovine testes, and in spermatozoa during and following the epididymal transit. We performed immunoblots on seminiferous tubules and interstitial cells isolated by enzymatic digestion, and on bovine chromaffin cells, spermatozoa, aorta, and vena cava. Immunoperoxidase labeling was done on Bouin's perfusion-fixed testes and epididymis tissue sections, and on spermatozoa. In addition, immunofluorescence labeling was done on spermatozoa. Immunoblots showed one 80-kDa band in chromaffin cells, fetal and adult tubules, interstitial cells, spermatozoa, aorta, and vena cava. Scinderin levels were higher in fetal than in adult seminiferous tubules but showed no difference between fetal and adult interstitial cells. Scinderin levels were higher in epididymal than in ejaculated spermatozoa. Scinderin was detected in a region corresponding with the subacrosomal space in the round spermatids and with the acrosome in the elongated spermatids. In epididymal spermatozoa, scinderin was localized to the anterior acrosome and the equatorial segment, but in ejaculated spermatozoa, the protein appeared in the acrosome and the post-equatorial segment of the head. In Sertoli cells, scinderin was detected near the cell surface and within the cytoplasm, where it accumulated near the base in a stage-specific manner. In the epididymis, scinderin was localized next to the surface of the cells; in the tail, it collected near the base of the principal cells. In Sertoli cells and epididymal cells, scinderin may contribute to the regulation of tight junctional permeability and to the release of the elongated spermatids by controlling the state of perijunctional actin. In germ cells, scinderin may assist in the shaping of the developing acrosome and influence the fertility of the spermatozoa.     

Spermatogonial stem cells in the testis of an endangered bovid: Indian black buck (Antilope cervicapra L.)

Numerous wild bovids are facing threat of extinction owing to the loss of habitat and various other reasons. Spermatogonial stem cells (SSCs) represent the only germline stem cells in adult body that are capable of self-renewal and that can undergo differentiation to produce haploid germ cells. SSCs can, therefore, serve as a useful resource for preservation of germplasm of threatened and endangered mammals. The Indian black buck (Antilope cervicapra L.) is a small Indian antelope that is listed as endangered by the Indian Wildlife Protection Act, 1972. Immunohistochemical analysis of testes tissues of black buck revealed the presence of spermatogonia that were specifically stained by lectin-Dolichos biflorus agglutinin (DBA). The expression of pluripotent cell-specific markers, NANOG and stage-specific embryonic antigen-1 (SSEA-1), was detected in spermatogonia. Interestingly, the expression of POU5F1 (OCT3/4) was absent from spermatogonia, however, it was detected in differentiating cells such as spermatocytes and round spermatids but not in elongated spermatids. The expression of NANOG protein was also present in spermatocytes but absent in round and elongated spermatids. Using the testis transplantation assay, stem cell potential of black buck spermatogonia was confirmed as indicated by the presence of colonized DBA-stained cells in the basal membrane of seminiferous tubules of xenotransplanted mice testis. The findings from this study suggest the presence of SSCs in the testis of an endangered bovid for the first time and open new possibility to explore the use of SSCs in conservation.     

Fine observation on nerves colonizing the regenerating tail of the lizard Podarcis sicula

During the regeneration of lizard tail, nerves sprouting from ganglia and the spinal cord invade the blastema as far as the apical epidermis. Electron microscopical observations reveal axons storing dense granules (dg) and dense core vesicles (dcv) which are concentrated in nerve terminals or in axoplasmatic regions. In the regenerating spinal cord (SC) these terminals resemble aminergic-peptidergic endings and grow as far as the distal portion of the SC, which is made up of irregularly arranged ependymal cells. Some axons storing dcv contact blastematic cells and other nerve terminals show a plasma membrane incomplete or broken. Whether this latter aspect is due to fixation artifacts or physiological rupture is unknown. Nerves containing dcv and a few dg also originate from spinal ganglia innervating the regenerating tail. The accumulation of material into these endings is probably slow and a possible trophic influence on the regeneration of lizard tail is discussed.     

Immunohistochemical localization of a proto-cadherin fat tumour-suppressor homolog in the regenerating tail of lizard suggests a role in apical growth control

The present immunohistochemical and western blotting study evaluates the localization of a proto-cadherin which gene is overexpressed in the regenerating blastema of the lizard Podarcis muralis. Bioinformatic analysis suggests that the antibody recognizes FAT1/2 proteins. Western blot indicates a main band around 50 kDa, a likely fragment derived from the original membrane-bound large protein. Immunofluorescence shows main labelling in differentiating wound keratinocytes, lower in ependyma, mesenchyme and extracellular matrix of the blastema. The apical epidermal peg contains keratinocytes with labelled peripheral cytoplasm, as confirmed using ultrastructural immunogold that also reveals most labelling located along the cell surface of mesenchymal cells. Myoblasts and differentiating myotubes of regenerating muscles are less intensely labelled. The regenerating cartilaginous tube contains sparse labelled chondroblasts, especially in external and internal perichondria. In regenerating scales, differentiating beta-cells appear immunofluorescent mainly along the cell perimeter. In more differentiated muscle, cartilage and connective tissues of the new tail, the labelling lowers or disappears. The observations indicate that FAT1/2 proto-cadherins are present in the apical blastema where an intense remodelling takes place for the growth of the new tail but where also a tight control of cell division and migration is active and may regulate potential tumorigenic process.