Endoglin is expressed in the chicken vasculature and is involved in angiogenesis.

Endoglin is a component of the transforming growth factor beta (TGF-beta) receptor complex, highly expressed by endothelial cells. Mutations in the endoglin gene are responsible for hereditary hemorrhagic telangiectasia type 1 (HHT1), an autosomal dominant vascular disorder caused by a haploinsufficiency mechanism. Vascular lesions (telangiectasia and arteriovenous malformations) in HHT1 are associated with loss of the capillary network, suggesting the involvement of endoglin in vascular repair processes. Using the chick chorioallantoic membrane (CAM) as an angiogenic model, we have analyzed the expression and function of chicken endoglin. A pan-specific polyclonal antibody (pAb) recognized chicken endoglin as demonstrated by immunostaining and Western blot analysis. In ovo treatment of chicken embryos with this pAb resulted in a significantly increased area of CAM. This effect was likely mediated by modulation of the ligand binding to endoglin as this pAb was able to inhibit TGF-beta1 binding. These results support the involvement of endoglin in the angiogenic process.     

Home is where the heart is: via the FROUNT

In this issue of Cell Stem Cell, Belema-Bedada et al. (2008) describe a novel mechanism by which bone marrow-derived adult mesenchymal stem cells migrate to sites of damaged heart tissue. This process is dependent on the intracellular adaptor molecule FROUNT, which interacts with the chemokine receptor CCR2.     

DERA is the human deoxyribose phosphate aldolase and is involved in stress response

Deoxyribose-phosphate aldolase (EC 4.1.2.4), which converts 2-deoxy-d-ribose-5-phosphate into glyceraldehyde-3-phosphate and acetaldehyde, belongs to the core metabolism of living organisms. It was previously shown that human cells harbor deoxyribose phosphate aldolase activity but the protein responsible of this activity has never been formally identified. This study provides the first experimental evidence that DERA, which is mainly expressed in lung, liver and colon, is the human deoxyribose phosphate aldolase. Among human cell lines, the highest DERA mRNA level and deoxyribose phosphate aldolase activity were observed in liver-derived Huh-7 cells. DERA was shown to interact with the known stress granule component YBX1 and to be recruited to stress granules after oxidative or mitochondrial stress. In addition, cells in which DERA expression was down-regulated using shRNA formed fewer stress granules and were more prone to apoptosis after clotrimazole stress, suggesting the importance of DERA for stress granule formation. Furthermore, the expression of DERA was shown to permit cells in which mitochondrial ATP production was abolished to make use of extracellular deoxyinosine to maintain ATP levels. This study unraveled a previously undescribed pathway which may allow cells with high deoxyribose-phosphate aldolase activity, such as liver cells, to minimize or delay stress-induced damage by producing energy through deoxynucleoside degradation.     

ABCG2 is expressed in late spermatogenesis and is associated with the acrosome

An increasingly exploited strategy for the isolation of stem cells is based on the increased efflux of Hoechst 33342 lipophilic dye mediated by ABCG2, an ATP-binding cassette transporter which is highly expressed in various stem cells. We found ABCG2 expression to be present at later stages of spermatogenesis. Western blot analysis using an anti-ABCG2 antibody revealed expression of a 72 kDa band in mature sperm obtained from mice, rats, bulls or humans. Immunocytochemistry studies revealed acrosomal staining pattern of ABCG2 in spermatozoa. Experiments using the Hoechst 33342 ABCG2 substrate and the ABCG2-specific inhibitor FTC demonstrated efflux activity of ABCG2 in mature sperm. Incubation of sperm in capacitating medium in the presence of the ABCG2-inhibitor FTC resulted in decreased cholesterol depletion compared to sperm incubated in the absence of FTC. Our results demonstrate that ABCG2 is expressed at the acrosome in mature sperm. ABCG2 may thus serve to mediate cholesterol removal.     

CASK is in the mammalian sperm head and is processed during epididymal maturation

Upon adhesion to the zona pellucida or egg extracellular matrix, sperm undergo regulated exocytosis of the acrosomal vesicle. CASK is an adaptor protein that has been implicated in coupling neuronal cell adhesion to regulated exocytosis. In neurons, this scaffolding molecule is associated with several types of transmembrane receptor complexes and connects cell adhesion molecules with ion channels, the actin cytoskeleton, and the cell's exocytotic machinery. We hypothesized CASK might also be an important link between zona pellucida binding and the sperm acrosome reaction. RT-PCR experiments indicated CASK is transcribed in mouse testis. The full size (120 kDa) CASK protein was present in testis from mouse and pig. Immunoblots of mature porcine and murine sperm revealed that the 120 kDa molecule was much less abundant than in testis but the antibody also recognized a group of smaller proteins migrating at 55-65 kDa. Immunofluorescence experiments indicated both the full length and smaller CASK immunoreactive products were found only in the acrosomal region of spermatids and mature sperm and not in other testicular cell types. CASK immunofluorescence was lost following the acrosome reaction. During epididymal maturation, the abundance of the full size CASK decreased and the CASK fragments increased. These results suggest that CASK may be proteolytically processed during epididymal maturation. Because sperm acquire the ability to bind the zona pellucida, acrosome react, and fertilize eggs during epididymal maturation, CASK processing may play a role in the acquisition of these functions.     

美国古人类研究处于困境

近十多年来,美国的土著居民印第安人的组织,一再要求美国收藏骨骼标本的博物馆和大学的有关部门,归还他们祖先的遗骸,以便重新埋葬,从而双方发生了长期的争执。最近这个问题开始激化了。由于要求归还遗骸的压力增大,收藏骨骼的部门已陆续归还或答应归还,从而使美国的古人类研究处于困境。
美国的这种情况,也对其他一些国家如 澳大利亚等产生了巨大的影响。     

Glicentin is present in the pig pancreas

Specimens from porcine pancreas and ileal mucosa were extracted in acid/ethanol, subjected to gel permeation chromatography, ion-exchange chromatography, enzymatic peptide degradation, reverse-phase HPLC, and analysed for glucagon-like and glicentin-like immunoreactivity by region-specific radioimmunoassays. Results obtained with all methods were consistent with the hypothesis that glicentin is present in the pig pancreas in small amounts.     

Connective tissue growth factor is secreted through the Golgi and is degraded in the endosome.

Connective tissue growth factor (CTGF) is a cysteine-rich heparin-binding polypeptide that promotes proliferation, collagen synthesis, and chemotaxis in mesanchymal cells. When coinjected subcutaneously with transforming growth factor beta (TGFbeta), CTGF promotes sustained fibrosis in rats. However, little is known about the cell biology and structure/functional relationship of CTGF. In particular, no detailed characterization of the subcellular localization of CTGF has occurred, nor have sequences been identified within this protein required for this localization. In this report, using immunofluorescence and Western blot analysis, we show that CTGF is localized to the Golgi apparatus both in dermal fibroblasts and activated hepatic stellate cells. Using these methods, no CTGF was detected in endosomal, plasma membrane, cytosolic or nuclear fractions. Addition of brefeldin A, a drug that disrupts the Golgi, blocks the secretion of CTGF. We further show that the amino-terminal 37 amino acids of CTGF are sufficient to localize a heterologous protein (red fluorescent protein, RFP) to the Golgi. Although within this region of human CTGF is a N-glycosylation site, tunicamycin, which blocks N-linked glycosylation, has no significant effect on CTGF secretion. Surprisingly, mutation of a single amino acid residue, CYS-34, to alanine prevents localization of a CTGF-RFP fusion protein to the Golgi. These results are the first proof that endogenous CTGF is localized to the Golgi apparatus. Furthermore, using exogenously added (125)I-labeled CTGF, we show that CTGF is internalized and rapidly degraded in the endosome. That is, CTGF is quantitatively secreted through the golgi and is degraded in the endosome.