Investigating the Elusive Mechanism of Glycosaminoglycan Biosynthesis

Glycosaminoglycan (GAG) biosynthesis requires numerous biosynthetic enzymes and activated sulfate and sugar donors. Although the sequence of biosynthetic events is resolved using reconstituted systems, little is known about the emergence of cell-specific GAG chains (heparan sulfate, chondroitin sulfate, and dermatan sulfate) with distinct sulfation patterns. We have utilized a library of click-xylosides that have various aglycones to decipher the mechanism of GAG biosynthesis in a cellular system. Earlier studies have shown that both the concentration of the primers and the structure of the aglycone moieties can affect the composition of the newly synthesized GAG chains. However, it is largely unknown whether structural features of aglycone affect the extent of sulfation, sulfation pattern, disaccharide composition, and chain length of GAG chains. In this study, we show that aglycones can switch not only the type of GAG chains, but also their fine structures. Our findings provide suggestive evidence for the presence of GAGOSOMES that have different combinations of enzymes and their isoforms regulating the synthesis of cell-specific combinatorial structures. We surmise that click-xylosides are differentially recognized by the GAGOSOMES to generate distinct GAG structures as observed in this study. These novel click-xylosides offer new avenues to profile the cell-specific GAG chains, elucidate the mechanism of GAG biosynthesis, and to decipher the biological actions of GAG chains in model organisms.Proteoglycans play a major role in various cellular/physiological processes, including blood clotting, growth factor signaling, embryogenesis, axon growth and guidance, angiogenesis, and others (1–4). Proteoglycans consists of a core protein and glycosaminoglycan (GAG)² chains. GAG chains account for >50% of the total molecular weight and are primarily responsible for physiological activity of the proteoglycans (5, 6). GAG chains are composed of repeating disaccharide units of a hexosamine residue and a hexuronic acid residue. The three major types of GAG chains found in the proteoglycans are heparan sulfate (HS), chondroitin sulfate (CS) and dermatan sulfate (DS). These GAG chains are differentiated by the type of hexosamine (glucosamine/galactosamine), the percentage of uronic acid epimers (glucuronic/iduronic acid), the extent of sulfation, and the nature of glycosidic linkage (α-/β-). One of the key steps in the proteoglycan biosynthesis is the xylosylation of certain specific serine residues of the core protein (7–10), which occurs in the late endoplasmic reticulum and/or cis-Golgi compartments (11–13). This key event is an essential prelude for the construction of the proteoglycan linkage region (14) that is followed by sequence of events resulting in the assembly of mature GAG chains by alternative addition of hexosamine and glucuronic acid residues. The maturation of GAG chains occurs in the medial and trans-Golgi compartments and involves the following events: N-sulfation of glucosamine units by N-deacetylase-N-sulfotransferases (for HS only), epimerization of glucuronic acids to iduronic acids by C-5 epimerase, and sulfation of the repeating disaccharide units by a variety of sulfotransferases and their isoforms.The position, extent, and pattern of sulfation attribute enormous diversity to GAG chains, which confer specificity in binding to a vast array of proteins. These diverse structural features are very tightly regulated in a spatio-temporal manner during and beyond the development of an organism, and these features dictate differential interactions with various growth factors and receptors, and numerous protein targets leading to an array of physiological functions (15, 16).The presence of free GAG chains has been known to disrupt the interaction of endogenous GAG components of proteoglycans with protein ligands thereby altering the physiological activities. Consequently, they have been used as molecular tools in the elucidation of the role of GAG chains in the activation of cellular events (17–19). Free GAG chains can be synthesized in vitro in cell culture by providing exogenous xylosides containing various hydrophobic aglycone moieties. Thus, the xylosides can act as false acceptors for initiation of linkage region and the subsequent elongation of GAG chains. Xylosides have been used for over three decades both in vitro (20–28) and in vivo (25, 29–31) to probe the functional significance of GAG chains in various dynamic systems under different conditions. The quantity and type of GAG chains synthesized depends on the system where it was tested and on the structure of the aglycone moiety of the xylosides (32–34). Most of these studies have utilized a few O-xylosides that are inherently less stable. Furthermore, synthesis of O-xylosides requires very stringent reaction conditions, toxic Lewis acids, and at times leads to inseparable α and β mixtures with unpredictable yields. As a result, it is tedious to generate diverse xylosides in a rapid fashion and utilize them in biological systems. We envisioned that synthesis of metabolically stable xylosides will advance our knowledge of glycosaminoglycan biosynthesis and how they regulate various pathophysiological processes.In our earlier communication, we outlined a simple strategy, utilizing click chemical methodology that addresses the above limitations of O-xylosides, to generate a library of xylosides in a robust manner (35). Several studies have shown that the concentration of the primers and the aglycone moieties influence the composition of GAG chains produced (32). In the current study, we show that the aglycone moieties of click-xylosides may not only influence the composition and quantity of GAG chains but also the extent of sulfation, sulfation pattern, disaccharide composition, and chain length using pgsA-745 Chinese hamster ovary (CHO) cell line as a model cellular system. Our findings provide new insights in to the mechanism of GAG biosynthesis and offer new avenues to decipher the biological actions of GAG chains in model organisms.     

Numb Expression and Asymmetric versus Symmetric Cell Division in Distal Embryonic Lung Epithelium

Proper balance between self-renewal and differentiation of lung-specific progenitors is absolutely required for normal lung morphogenesis/regeneration. Therefore, understanding the behavior of lung epithelial stem/progenitor cells could identify innovative solutions for restoring normal lung morphogenesis and/or regeneration. The Notch inhibitor Numb is a key determinant of asymmetric or symmetric cell division and hence cell fate. Yet Numb proximal-distal expression pattern and symmetric versus asymmetric division are uncharacterized during lung epithelial development. Herein, the authors find that the cell fate determinant Numb is highly expressed and asymmetrically distributed at the apical side of distal epithelial progenitors and segregated to one daughter cell in most mitotic cells. Knocking down Numb in MLE15 epithelial cells significantly increased the number of cells expressing the progenitor cell markers Sox9/Id2. Furthermore, cadherin hole analysis revealed that most distal epithelial stem/progenitor cells in embryonic lungs divide asymmetrically; with their cleavage, planes are predicted to bypass the cadherin hole, resulting in asymmetric distribution of the cadherin hole to the daughter cells. These novel findings provide evidence for asymmetric cell division in distal epithelial stem/progenitor cells of embryonic lungs and a framework for future translationally oriented studies in this area.     

A Cell Kinetic and Cytological Study on the Asymmetric Cell Division of Thymic Lymphoblasts of the Embryonic Rat

Cell division of thymus lymphoid cells from embrynonic and young rats was investigated cytologically on cell smears, focusing attention on asymmetric cell division. Some of thymic lymphoblasts displayed features implicating asymmetric cell division. At the telophase of such cells, two immature daughter cells looked dissimilar: one of them was smaller in size and possessed a more condensed nucleus, compared with the counterpart cell. Furthrmore, in most cases the cytoplasm of the smaller daughter cell was stained with Giemsa more deeply. It was suggested that the asymmetry of the nucleus emerges at anaphase and telophase probably due to some polarized situation of the cytoplasm. Asymmetrically-dividing cells were relatively frequently observed during the developmental period when large lymphoblasts actively transform into smaller lymphocytes :16% to 17% of whole dividing cells were under asymmetric cell division on days 16 and 17 of gestation, while less than 5% on day 19 or thereafter. In correlation with this observation, asymmetrically-dividing cells were more frequently observed among large lymphoblasts than among other smaller cell fractions. These results support the view that the asymmetric cell division may play some essential role in the transformation of large lymphoblasts into smaller lymphocytes.     

小鼠体外受精、胚胎培养及胚胎快速冷冻的研究

目的　为扩大胚胎来源并获取特定胚龄胚胎 ,建立小鼠冷冻胚胎库。方法　运用超数排卵、体外受精与胚胎培养及胚胎冷冻技术系统研究了小鼠受精卵的体内发育与运行规律。卵母细胞的体外成熟与受精、单细胞胚胎培养及胚胎快速冷冻。结果　 (1)注射hCG后 12～ 2 0h受精卵发育至原核期 ,4 2～ 4 8h为 2 细胞期 ,4 8～ 6 0h为 4 细胞期 ,6 0～ 6 8h为 8 细胞期 ,以上各期受精卵均处于输卵管中 ;75～ 78h为桑椹胚 ,78～ 80h为致密桑椹胚 ,90～ 92h为早期囊胚 ,92～ 96h为囊胚 ,以上各期均处于子宫角中。 (2 )培养液中添加促性腺激素 (FSH与hCG) ,能显著提高卵母细胞的体外受精率 ,添加FCS和激素组的体外受精率又显著高于单独添加激素组 ,FCS还能显著提高胚胎发育。 (3)在培养液中添加EDTA ,能有效克服小鼠胚胎的 2 细胞阻断 ,其 2 细胞胚的发育率达 10 0 % ,8 细胞胚发育率达 5 5 %以上 ;牛、羊上皮细胞培养液上清也能有效克服 2 细胞阻断。添加乳酸钠和丙酮酸钠可使 2细胞与 8细胞期胚的发育率显著提高。 (4)以D PBS +甘油 +蔗糖为冷冻液 ,以D PBS +蔗糖为稀释液 ,对小鼠胚胎进行快速冷冻 ,桑椹胚的存活率为 6 9 3% ,早期囊胚的存活率为 6 0 4 %。结论　研究为将生物技术应用于小鼠 ,扩大卵子和胚胎来源     

鸡胚胎生殖细胞在鼠胚成纤维细胞饲养层上的生长

目的:探讨以鼠胚成纤维细胞为饲养层分离、培养鸡胚胎生殖细胞的方法和条件。方法:分离、培养12.5～13.5d鼠胚成纤维细胞。分离孵化5.5d鸡胚原始生殖细胞,原代培养时不使用饲养层,与性腺基质细胞共培养;继代培养时将其置于鼠胚成纤维细胞饲养层上,在含生长因子、分化抑制因子的培养体系中培养胚胎生殖细胞。结果:鼠胚成纤维细胞可连续传代18代以上(4个月),3～15代细胞可以用作饲养层细胞。分离的鸡胚胎生殖细胞在饲养层上可增殖形成典型胚胎生殖细胞集落,并能连续在体外培养超过9代。集落未分化标志高碘酸希夫反应(PAS)呈强阳性,体外分化实验表明胚胎生殖细胞具有多能性。结论:用鼠胚成纤维细胞作为饲养层能获得可连续增殖的胚胎生殖细胞。     

存活蛋白与细胞分裂

凋亡抑制蛋白家族的新成员存活蛋白(survivin)在肿瘤细胞中特异性地表达,它不仅具有抗凋亡的功能,而且它在细胞分裂中的重要作用也越来越受到人们关注,这一方面的研究取得了新的进展。深入研究存活蛋白在细胞分裂中的作用,将拓展人们对于这一分子新的认识。     

Structural Basis for the Initiation of Glycosaminoglycan Biosynthesis by Human Xylosyltransferase 1

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Cell Division in Tetraspora

Cell division in Tetraspora sp. is described. The cell becomesimmotile some while before mitosis and the basal bodies withdrawfrom the cell surface. The preprophase nucleus migrates to thebasal body complex, around which increasing numbers of microtubulesgather. The spindle is closed with open polar fenestrae; a basalbody complex is always closely associated with at least onepole. No spindles were observed to have basal bodies at bothpoles, and the spindle may possibly be unicentric. During anaphase,spindle microtubules penetrate through the fenestrae. Aftertelophase, the nuclei come together as a phycoplast forms betweenthem; cytokinesis is effected by furrowing. Forming basal bodiesare frequently encountered in late telophase and cleaving cells;no evidence was obtained that the basal bodies replicated beforemitosis. The protoplast rotates inside the cell wall duringcleavage. Cell division is compared with that of other greenalgae, and in particular, Chlamydomonas.     

Cell Division in Tetraedron

Mitosis and cytokinesis in Tetraedron are described. Persistentcentrioles replicate before division and the pairs separateto define the future poles of the spindle whilst increasingnumbers of microtubules become associated with them. By prophase,the centrioles and most extranuclear microtubules have becomeenclosed within a 'perinuclear envelope' of endoplasmic reticulum.The nuclear envelope near the centrioles then becomes indentedand finally ruptures to form polar fenestrae during prometaphase;the extranuclear microtubules soon vanish and appear to movethrough the fenestrae into the forming spindle. Metaphase, anaphase,and telophase follow as usual. After mitosis, arrays of 'phycoplast'microtubules proliferate between nuclei. The cytoplasm is cleavedby membrane furrows coplanar with and growing through the phycoplasttubules. However, this cleavage is delayed until the cells havebecome multinucleate, and it appears to be irregular in extentand disposition in the cell until after a final set of synchronousmitoses. Then cytokinesis cuts up the cytoplasm into numeroussmall autospores which secrete their own wall; they are laterreleased following rupture of the parental wall. Some autosporesare binucleate which indicates that this cleavage apparatusdoes not necessarily cut up all the cytoplasm into uninucleatesegments. Vegetative reproduction in these organisms is comparedto that of other members of the Chlorococcales.     

Polarity in Stem Cell Division: Asymmetric Stem Cell Division in Tissue Homeostasis

Many adult stem cells divide asymmetrically to balance self-renewal and differentiation, thereby maintaining tissue homeostasis. Asymmetric stem cell divisions depend on asymmetric cell architecture (i.e., cell polarity) within the cell and/or the cellular environment. In particular, as residents of the tissues they sustain, stem cells are inevitably placed in the context of the tissue architecture. Indeed, many stem cells are polarized within their microenvironment, or the stem cell niche, and their asymmetric division relies on their relationship with the microenvironment. Here, we review asymmetric stem cell divisions in the context of the stem cell niche with a focus on Drosophila germ line stem cells, where the nature of niche-dependent asymmetric stem cell division is well characterized.Asymmetric cell division allows stem cells to self-renew and produce another cell that undergoes differentiation, thus providing a simple method for tissue homeostasis. Stem cell self-renewal refers to the daughter(s) of stem cell division maintaining all stem cell characteristics, including proliferation capacity, maintenance of the undifferentiated state, and the capability to produce daughter cells that undergo differentiation. A failure to maintain the correct stem cell number has been speculated to lead to tumorigenesis/tissue hyperplasia via stem cell hyperproliferation or tissue degeneration/aging via a reduction in stem cell number or activity (Morrison and Kimble 2006; Rando 2006). This necessity changes during development. The stem cell pool requires expansion earlier in development, whereas maintenance is needed later to sustain tissue homeostasis.There are two major mechanisms to sustain a fixed number of adult stem cells: stem cell niche and asymmetric stem cell division, which are not mutually exclusive. Stem cell niche is a microenvironment in which stem cells reside, and provides essential signals required for stem cell identity (Fig. 1A). Physical limitation of niche “space” can therefore define stem cell number within a tissue. Within such a niche, many stem cells divide asymmetrically, giving rise to one stem cell and one differentiating cell, by placing one daughter inside and another outside of the niche, respectively (Fig. 1A). Nevertheless, some stem cells divide asymmetrically, apparently without the niche. For example, in Drosophila neuroblasts, cell-intrinsic fate determinants are polarized within a dividing cell, and subsequent partitioning of such fate determinants into daughter cells in an asymmetric manner results in asymmetric stem cell division (Fig. 1B) (see Fig. 3A and Prehoda 2009).Open in a separate windowFigure 1.Mechanisms of asymmetric stem cell division. (A) Asymmetric stem cell division by extrinsic fate determinants (i.e., the stem cell niche). The two daughters of stem cell division will be placed in distinct cellular environments either inside or outside the stem cell niche, leading to asymmetric fate choice. (B) Asymmetric stem cell division by intrinsic fate determinants. Fate determinants are polarized in the dividing stem cells, which are subsequently partitioned into two daughter cells unequally, thus making the division asymmetrical. Self-renewing (red line) and/or differentiation promoting (green line) factors may be involved.In this review, we focus primarily on asymmetric stem cell divisions in the Drosophila germ line as the most intensively studied examples of niche-dependent asymmetric stem cell division. We also discuss some examples of stem cell division outside Drosophila, where stem cells are known to divide asymmetrically or in a niche-dependent manner.     

胚胎干细胞技术的研究进展

干细胞可以分为成体干细胞和胚胎干细胞两类,是当前生物医学领域的一个热点。由于干细胞在医学领域有巨大应用前景,世界各国都对此给予了相当的重视;投入大量资金支持本国的科学家从事干细胞的科学研究。目前,干细胞的研究还处于试验室阶段,很多技术难题还没有解决,尤其是胚胎干细胞的不定向分化问题,以及一些伦理方面的争议。宗教界人士和社会论理学方面的人士对于干细胞的研究还有异议。集中论述了胚胎干细胞的研究进展和医学功用。     

Embryonic Heart and Skin Defects in Mice Lacking Plakoglobin

Plakoglobin is the only component common to both the desmosomal plaque and the cadherin–catenin cell adhesion complex in the adherens junction. It is highly homologous to vertebrate β-catenin and toDrosophilaarmadillo protein and may—like these proteins—be also involved in signaling pathways. To analyze the role of plakoglobin during mouse development we inactivated theplakoglobingene by homologous recombination in embryonic stem cells and generated transgenic mice.Plakoglobinnull-mutant embryos died from Embryonic Day 10.5 onward, due to severe heart defects. Some mutant embryos developed further, especially on a C57BL/6 genetic background, and died around birth, presumably due to cardiac dysfunction, and with skin blistering and subcorneal acantholysis. Ultrastructural analysis revealed that here desmosomes were greatly reduced in number and structurally altered. Thus, using reversed genetics we demonstrate that plakoglobin is an essential structural component for desmosome function. The skin phenotype in plakoglobin-deficient mice is reminiscent of the human blistering disease, epidermolytic hyperkeratosis.     

Dihydroartemisinin (DHA) Treatment Causes an Arrest of Cell Division and Apoptosis in Rat Embryonic Erythroblasts in Whole Embryo Culture

Within 24 hr after oral administration of the antimalarial artesunate to rats on Day 10 or 11 postcoitum (pc), there is depletion of embryonic erythroblasts (EEbs), leading to embryo malformation and death. The proximate agent is dihydroartemisinin (DHA), the primary metabolite. We investigated the causes of EEb depletion by evaluating effects of DHA on EEbs in whole embryo culture (WEC). Rat embryos cultured starting on Day 9 pc were treated with 1 or 7 μM DHA for 24 hr starting after 19 hr of culture (～Day 10 pc) and for 2 to 12 hr starting after 43 hr of culture (～Day 11 pc). DHA effects indicating the depletion of EEbs were paling of the visceral yolk sac and reductions in visible blood cells, H&E‐stained normal (Type II or III) EEbs, and dividing (BrdU‐stained) EEbs. DHA‐induced abnormal cell division was indicated by increases in symmetric and asymmetric binuclear cells. DHA‐induced apoptosis was indicated by increases in TUNEL‐ and Caspase‐3‐positive cells and EEbs with fragmented nuclei. In addition, although the overall number of EEbs was decreasing, DHA caused increases in the numbers of circulating early‐stage (Type I or earlier) EEbs that could not be accounted for by cell division, suggesting the release of new, less sensitive erythroblasts from the yolk sac. In summary, treatment of Day 10 or 11 pc rat embryos with DHA in WEC resulted in defective and arrested cell division in EEbs followed by apoptosis, suggesting a mechanism for their depletion after artesunate treatment in vivo.     

MicroRNAs与胚胎干细胞研究

MicroRNAs(miRNAs)是一种大小约20～25个碱基的非编码小分子RNA,一般通过特异性抑制靶蛋白翻译或降解靶基因mRNA发挥负调控基因表达的作用.胚胎干细胞(embryonic stem cells,ES细胞)是从植入前早期胚胎内细胞团或原始生殖细胞中分离得到并能在体外长期培养的高度未分化的多能细胞系,在揭示胚胎早期发育机理、药物筛选、临床再生医学等领域具有广泛的应用前景.最近研究发现miRNAs在ES细胞自我更新和分化过程中均发挥着重要的调控作用,但具体调控机制尚未完全阐明.进一步深入研究miRNAs在ES细胞中的作用,全面了解ES细胞自我更新和定向分化的机制是实现ES细胞广阔临床应用前景的基础.     

从C57BL/6J小鼠胚胎中分离ES细胞系(英文)

ＥＳ细胞（ＥｍｂｒｙｏｎｉｃＳｔｅｍＣｅｌｓ）是来源于小鼠早期胚胎的细胞系,它可以在体外大量培养而不失去其发育的多潜能性。ＥＳ细胞不仅可以用来制作转基因动物,而且能够作为载体进行基因打靶等多种研究。目前,国际上常用的胚胎干细胞系都是来源于１２９小鼠的胚胎。因而,有必要探讨用其它品系小鼠建立ＥＳ系。１９９１年,Ｌｅｄｅｒｍａｎｎ等人首次报道从Ｃ５７ＢＬ／６Ｊ小鼠胚胎中建成了ＥＳ细胞系,但是没有对建立的细胞系进行特性分析。国内柴桂萱等人虽然做了特性分析,但是他们所建细胞系的细胞直径较大,生长速度较慢,不同于常见的ＥＳ细胞系。我们从Ｃ５７ＢＬ／６Ｊ品系小鼠胚胎中共分离了四个ＥＳ细胞系,分别命名为ＣＥ１、ＣＥ２、ＣＥ３、ＣＥ４（Ｆｉｇ．１ａ＆ｂ）。这四个细胞系核型正常率均达到７０％以上。我们检查了ＣＥ２细胞的分化能力,当将ＣＥ２细胞注入同基因型小鼠的皮下后,获得的畸胎瘤（Ｆｉｇ．３）组织切片检查的结果表明：该细胞能够分化成多种组织（Ｆｉｇ．２）。我们也研究了ＥＳ细胞的嵌合能力,用ＩＣＲ小鼠胚胎作为受体胚胎,采用囊胚显微注射法构建嵌合鼠。在幸存的幼鼠中我们获得了来源于ＣＥ２细胞的嵌合鼠（Ｔａｂｌｅ１,Ｆｉｇ．４）。综