梅花鹿(Cervus nippon hortulorum)茸角生长发育各阶段血浆睾酮、雌二醇的含量变化

本文用放射免疫测定法对3个不同年龄组的雄性东北梅花鹿茸角生长发育各阶段外周血中的睾酮、雌二醇含量进行了测定。茸期两种激素差异很大,睾酮含量低,雌二醇高,骨化期二者增高很快。对这两种激素含量的变化与茸角发育各阶段的关系进行了讨论。认为只有在二种激素同时增加时,鹿角才能骨化。     

生长滞缓与正常罗氏沼虾转录组差异分析

旨在利用浙江地区生长正常和生长滞缓两种生长状态下的罗氏沼虾,通过转录组测序技术,比对基因表达量的差异,探究生长滞缓的原因.本研究采用IlluminaHiSeqTM4000测序平台,对存在生长差异的罗氏沼虾的鳃、肝胰腺、肌肉三种组织共18个样本进行了转录组测序分析,将得到的基因片段组装后与NR、GO、KEGG、eggNO...     

基于转录组测序分析甜菜夜蛾卵巢细胞离体培养成系进程

【目的】本研究旨在分析甜菜夜蛾Spodoptera exigua蛹卵巢细胞建立细胞系的整个过程,探究细胞由体内到体外培养过程中其基因表达在转录水平的变化,为昆虫体外培养模型的建立提供理论基础。【方法】利用Illumina Hiseq测序平台对甜菜夜蛾蛹卵巢细胞离体培养过程中各阶段的细胞分别进行转录组测序,对获得注释的差异表达基因及其相关信号通路进行分析;通过荧光定量PCR对部分细胞周期相关基因(cycd和cdk4)、调控基因(cdc20,apc1,skp2和mad1)、增殖相关分子标志物(mcm4和pcna)在甜菜夜蛾卵巢细胞离体培养过程中的转录进行验证。【结果】甜菜夜蛾蛹卵巢细胞离体培养过程包括5个阶段:解剖获得离体的卵巢组织,卵巢组织贴壁培养后游离出原代细胞,细胞转化重新具备增殖能力,成功首次传代,以及能够连续传代15代以上建立细胞系。上述5个阶段的细胞经转录组测序、数据组装后共获得46 796条unigenes序列,组装得到序列长度完整性好;转录本unigenes序列拼接长度分布合理,样本碱基Q30均在94%以上。通过KEGG数据库获得注释的unigenes有1 473条,参与细胞过程紧密相关的20条信号通路,其中有92条unigenes在细胞周期信号通路中获得注释。聚类分析表明,在体内处于快速发育状态的卵巢细胞与同样处于增殖状态的细胞系基因表达模式非常接近。原代细胞由短暂停滞生长至成簇细胞的转化关键期,筛选到差异表达基因619个,cdk4在离体培养期表达量显著降低,cycd在细胞转化关键期之后表达量显著升高,cdc20,apc1,skp2和mad1在卵巢组织和细胞系的表达量显著高于原代细胞、转化关键期细胞和首次传代细胞的。从原代细胞至传代后,cycd的表达显著升高8.7倍,显著高于mcm4和pcna的变化水平。【结论】甜菜夜蛾卵巢细胞离体培养过程中5个阶段的细胞转录组测序获得的序列质量符合数据分析的基本要求。筛选获得了甜菜夜蛾蛹卵巢细胞经离体培养过程中的差异表达基因。原代细胞逆转增殖可能与cdk4,cycd,skp2和mad1等细胞周期调控基因表达有关。另外,cycd可作为原代细胞具备传代能力的标志物。     

日粮蛋白质水平对贵州省梅花鹿鹿茸生长的影响

为寻找贵州省梅花鹿在生茸期的最适日粮蛋白质添加水平,在梅花鹿生茸期对其饲喂不同蛋白质水平日粮,日粮蛋白质水平分别为(Ⅰ:28%;Ⅱ:24%;Ⅲ:20%)。选出4岁梅花鹿27头,随机分配到3个不同组别中(Ⅰ组为9头,Ⅱ组为10头,Ⅲ组为8头)。试验结果表明:在日粮蛋白质水平对鹿茸产量上的影响,Ⅲ组鲜茸重与其他两组存在显著差异(p0.05);在日粮蛋白质水平对鹿茸品质的影响方面,Ⅲ组茸直径、茸干长、茸基围、茸头围、茸干围最高,鹿茸的茸直径、茸干长、茸干围等方面存在显著差异(p0.05);而在鹿茸血重、盘直径、茸基围、茸头围等方面的差异并不显著(p0.05)。     

卵巢成熟期和退化期星斑川鲽脑垂体和下丘脑组织的转录组比较分析

为了解星斑川鲽（Starry Flounder,Platichthys stellatus）脑组织基因表达与卵巢发育调控的关系,发掘相关功能基因,研究提取卵巢成熟期和退化期星斑川鲽雌鱼脑垂体和下丘脑组织总RNA,运用HiSeq 2000高通量测序技术进行转录组测序分析。测序结果经拼接组装后共获得30640条Unigenes,Blast同源性比对显示,其中24128条Unigenes获得注释;经eggNog功能注释后29137条Unigenes序列分为26类,分别涉及信号转导、翻译机制等生理生化过程。KEGG pathway数据比对显示,卵巢成熟期涉及98种代谢途径,135条序列表达上调;卵巢退化期涉及192种代谢途径,648条序列表达上调。Unigenes表达量及表达差异分析表明在卵巢成熟期334条序列表达上调,卵巢退化期987条序列表达上调。获得功能注释的Unigene中,408条涉及生殖调控和内分泌调控,参与生殖调控的信号分子有1508条。试验采用实时定量PCR研究了涉及生殖调控和内分泌调控基因促性腺激素释放激素（GnRH）、神经激肽B（NKB）、促性腺激素（GtH）、促滤泡激素（FSH）、肿瘤转移抑制因子（Kiss）以及催乳素释放肽受体（PrRPR）在卵巢两个不同发育时期脑垂体和下丘脑的表达情况,结果表明除FSH外,其余均在卵巢退化期时期脑组织中表达升高,与转录组测序结果趋势一致。     

茶树种子发育过程的转录组分析

该研究以‘铁观音’茶树品种的种子为试验材料,采用转录组测序技术分析种子发育的3个时期(幼果期、膨大期、成熟期)的表达差异,探究茶树种子油脂代谢的分子机制。结果表明:(1)经转录组测序、组装后共获得30 940 581个clean reads,经数据合并拼接最终得到36 951条非冗余Unigene序列,其中28 476个Unigene可得到功能注释;在转录本中能够被注释到GO分类的Unigene有11 201条(30.3%),KEGG分析发现共有17 172个基因参与了127个代谢通路。(2)经KEGG通路筛选出14条与脂肪酸代谢相关的通路,且随着茶籽的发育,大部分脂肪酸调控途径相关基因呈下调趋势,其中上调基因数最多的有α-亚麻酸代谢途径和脂肪酸降解途径(有17个基因表达量上调),下调基因数最多的是甘油磷脂代谢途径(有58个基因表达量下调);在茶籽发育幼果期α-亚麻酸代谢途径中表达量上调的基因数超过表达量下调的基因数。(3)研究发现茶籽脂肪酸合成相关的基因涉及14个脂类调控途径,共409条差异基因;随着茶树种子发育到成熟期,上调的差异表达基因数量在减少,下调的差异表达基因数量增加,其中α-亚麻酸途径中的基因PLA2G16、DAD1、pldA、FabF、FabI表达量上调显著,随后表达量下调。(4)qRT-PCR检测结果表明,7个茶树FAD和1个ACP差异表达基因的水平与转录组测序结果基本一致;随着茶籽的发育,基因CsFAD7和Δ6-CsFAD从幼果期、果实膨大期至果实成熟期都为差异下调表达,CsFAD2、CsFAD6和Δ7-CsFAD为差异上调表达,CsFAD8、Δ8-CsFAD和CsACP在幼果期至果实膨大期差异上调表达,在果实膨大期至果实成熟期差异下调表达。     

野生中国大鲵Sox基因的克隆与序列分析

Sox基因家族是一类编码转录因子的基因家族,其产物具有一个HMG-box基序保守区,调节动物的性别决定与分化过程,并参与多种器官的发育。参照人SRY基因HMG-box保守区序列及有关文献,设计一对简并引物,PCR扩增了野生雌性中国大鲵（Andrias davidianus）基因组DNA,结果得到了一条长约220 bp的产物片段;菌落PCR扩增结果表明,克隆后的白色菌落中90%以上都是阳性克隆;通过SSCP技术筛选到3种有差异的阳性克隆,进行测序,获得了3个Sox基因：Sox4a、Sox4b与Sox14。对所得序列进行序列比对和聚类分析,结果显示该基因在分子进化上具有高度的保守性。对中国大鲵Sox基因的研究,目前国内外尚未见报道。为研究中国大鲵性别决定机制以及Sox基因进化提供了分子遗传学资料。     

下一代测序技术在干细胞转录调控研究中的应用

基因转录调控及其机制分析是后基因组时代生物学研究的重点之一。随着高通量测序技术的发展,人们可以从不同层面研究基因的转录调控行为,从转录组、转录因子结合,到染色质局部结构和整体空间构象,可系统分析转录调控的分子机制。干细胞分化过程的转录调控分析对研究再生医学和理解细胞癌变机制等具有重要意义。本文综述了下一代测序技术在干细胞转录调控研究中的应用,包括：(1)基于基因芯片或RNA测序的转录组分析;(2)基于染色体免疫共沉淀(chromatin immunoprecipitation, ChIP)测序的表观基因组和转录因子结合信息的分析;(3)基于DNase 酶切测序(DNase-Seq)的染色质开放性分析;(4)基于高通量染色质构象捕获(high-throughput chromosome conformation capture, Hi-C)技术的染色体远程相互作用分析。从基因表达谱、转录因子结合和基因组三维结构等层面展开介绍,重点关注了一些多能性转录因子(Oct4、Sox2和Nanog等)在维持干细胞干性和分化中的调控作用,以期为干细胞转录调控的研究提供借鉴和参考。     

利用全基因组重测序分析鹿茸重量相关基因

茸角是鹿科动物特有的器官,具有重要的生物学意义。鹿茸生长是一个复杂的生物代谢过程,其重量与遗传因素有一定关联。本研究对饲养条件基本一致的5个梅花鹿(Cervus nippon)群体进行调查,获得高产和低产梅花鹿个体共100只,利用全基因组重测序分析这些个体与鹿茸重量相关的遗传变异。结果表明,共得到94个与鹿茸重量可能相关的遗传变异,其中有2个变异位点分别定位于OAS2和ALYREF/THOC4基因的外显子区,且ALYREF/THOC4基因在鹿茸中表达量很高。功能富集分析发现,这些遗传变异与鹿茸生长发育密切相关,可作为潜在的鹿茸重量相关遗传变异。本研究首次通过全基因组重测序直接筛选与鹿茸重量相关的遗传变异,并分析关联基因的生物学功能,对揭示鹿茸生长发育和鹿茸重量差异形成的遗传机制具有重要意义。     

基于转录组分析酸枣仁斯皮诺素生物合成途径的相关基因

采用转录组测序技术分析酸枣仁(Ziziphi spinosae semen)不同发育时期基因表达差异,识别酸枣仁黄酮生物合成途径的相关基因,为进一步分析酸枣仁中黄酮类成分生物合成相关酶基因提供研究基础.以3个不同生长发育时期的酸枣仁样本为供试材料,采用Illumina Hiseq 4000进行转录组测序,并从头拼接,对转录本进行功能注释和差异性分析.经StringTie软件组装拼接得到74472个转录本,其中有26.83％在NR、Swiss-Prot、Pfam、GO、KOG、KEGG数据库中得到注释;代谢通路分析结果发现,在酸枣仁转录组中与黄酮类合成途径相关的11条差异表达基因可能编码斯皮诺素合成途径的一些酶类.酸枣仁中黄酮类成分斯皮诺素相关转录本信息为阐明斯皮诺素在生长期的积累提供重要依据,为提高酸枣仁品质研究提供参考.     

Antler development and coupled osteoporosis in the skeleton of red deer Cervus elaphus: expression dynamics for regulatory and effector genes

Antlers of deer display the fastest and most robust bone development in the animal kingdom. Deposition of the minerals in the cartilage preceding ossification is a specific feature of the developing antler. We have cloned 28 genes which are upregulated in the cartilaginous section (called mineralized cartilage) of the developing (“velvet”) antler of red deer stags, compared to their levels in the fetal cartilage. Fifteen of these genes were further characterized by their expression pattern along the tissue zones (i.e., antler mesenchyme, precartilage, cartilage, bone), and by in situ hybridization of the gene activities at the cellular level. Expression dynamics of genes col1A1, col1A2, col3A1, ibsp, mgp, sparc, runx2, and osteocalcin were monitored and compared in the ossified part of the velvet antler and in the skeleton (in ribs and vertebrae). Expression levels of these genes in the ossified part of the velvet antler exceeded the skeletal levels 10–30-fold or more. Gene expression and comparative sequence analyses of cDNAs and the cognate 5′ cis-regulatory regions in deer, cattle, and human suggested that the genes runx2 and osx have a master regulatory role. GC–MS metabolite analyses of glucose, phosphate, ethanolamine-phosphate, and hydroxyproline utilizations confirmed the high activity of mineralization genes in governing the flow of the minerals from the skeleton to the antler bone. Gene expression patterns and quantitative metabolite data for the robust bone development in the antler are discussed in an integrated manner. We also discuss the potential implication of our findings on the deer genes in human osteoporosis research.     

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.     

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 α-tropomyosine (tpm1), transgelin (tagln), annexin 2 (anxa2), phosphatidylethanolamine-binding protein (pebp) and apolipoprotein D (apoD) in intense but still controlled tissue proliferation are discussed.     

Effects of insulin-like growth factor 1 and testosterone on the proliferation of antlerogenic cells in vitro.

Androgen hormones and growth factors are implicated in pedicle formation and antler transformation in deer. The potential to form a pedicle and an antler is only found in the antlerogenic periosteum (AP) overlying the presumptive antler growth region. Histological studies (Li and Suttie, '94) showed that AP consists of an inner cellular layer and an outer fibrous layer. Pedicle and antler are mainly derived from the cellular layer cells of the AP. Ossification takes place in four stages: intramembranous (IMO), transitional (OPC), pedicle endochondral (pECO) and antler endochondral (aECO). However, the precise mechanism whereby androgen hormones and growth factors control pedicle and antler formation is unknown. The aim of this study was to use cell culture techniques to investigate how testosterone and IGF1 affects the proliferation of antlerogenic cells from the four ossification stages of pedicle/antler in vitro. The results showed that in serum-free medium IGF1 stimulated the proliferation of antlerogenic cells from all four ossification stages in a dose-dependent manner. In contrast, testosterone alone did not show any mitogenic effects on these antlerogenic cells. However, in the presence of IGF1, testosterone increased proliferation of the antlerogenic cells from the IMO and the OPC stages (pedicle tissue), and reduced proliferation of the antlerogenic cells from transformation point (TP) and aECO stages (antler tissue). Therefore, the results from the present in vitro study support the in vivo findings that androgen hormones stimulate pedicle formation but inhibit antler growth. The change in the mitogenic effects of testosterone on antlerogenic cells from positive to negative occurs approximately at the change in ossification type from OPC to pECO. Therefore, these results reinforce the hypothesis that the transformation from a pedicle to an antler takes place at the time when the ossification type changes from OPC to pECO rather than at the time when the pedicle grows to its full species-specific height.     

Sox9 neural crest determinant gene controls patterning and closure of the posterior frontal cranial suture

Cranial suture development involves a complex interaction of genes and tissues derived from neural crest cells (NCC) and paraxial mesoderm. In mice, the posterior frontal (PF) suture closes during the first month of life while other sutures remain patent throughout the life of the animal. Given the unique NCC origin of PF suture complex (analogous to metopic suture in humans), we performed quantitative real-time PCR and immunohistochemistry to study the expression pattern of the NCC determinant gene Sox9 and select markers of extracellular matrix. Our results indicated a unique up-regulated expression of Sox9, a regulator of chondrogenesis, during initiation of PF suture closure, along with the expression of specific cartilage markers (Type II Collagen and Type X Collagen), as well as cartilage tissue formation in the PF suture. This process was followed by expression of bone markers (Type I Collagen and Osteocalcin), suggesting endochondral ossification. Moreover, we studied the effect of haploinsufficiency of the NCC determinant gene Sox9 in the NCC derived PF suture complex. A decrease in dosage of Sox9 by haploinsufficiency in NCC-derived tissues resulted in delayed PF suture closure. These results demonstrate a unique development of the PF suture complex and the role of Sox9 as an important contributor to timely and proper closure of the PF suture through endochondral ossification.     

梅花鹿鹿茸不同产品中氨基酸含量的比较

通过对二杠鹿茸、三杈鹿茸、鹿茸片、鹿茸血、鹿角、鹿角盘等鹿茸产品中氨基酸含量的测定研究,结果表明:鹿茸血中氨基酸含量最高,鹿茸片中的氨基酸含量次之,三杈鹿茸中的氨基酸含量高于二杠鹿茸中氨基酸含量,鹿花盘中的含量高于鹿角中的氨基酸含量,从而为鹿茸这一动物性中药材资源的功能评价、药理作用提供科学理论依据。     

Distribution of EGF and its receptor in growing red deer antler

Autografts of the osteogenic part of early antler buds placed elsewhere on the skull have been shown by others to give rise to an antler at the site of grafting. This antler becomes covered in velvet skin, is shed at the end of the growing season and will regrow the following year. Thus, it can be concluded that the nature of antler velvet skin is primarily determined by the underlying osteogenic antler tissue to which it is attached. We hypothesise that a paracrine mechanism operates here and is central to communication between the antler osseous compartment and the integument. A signalling system comprising epidermal growth factor (EGF) and its receptor (EGFR) is known to be expressed in osteogenic cells and to play an important role in skin development and growth. This system may therefore play a significant role in determining the nature and speed of growth of velvet skin via paracrine signalling from osteogenic tissue. We have used bright-field microscope immunohistochemistry to determine the distribution of EGF and its receptor in developing red deer antler osseous compartment and integument. EGF was localized throughout the epidermis and epidermal appendages, in cells of the mesenchyme, in chondrocytes, and in cells of the osteoblastic lineage, including osteoprogenitor cells, osteoblasts and osteocytes. There was strong evidence supporting nuclear and nucleolar staining in sebaceous glands and in keratinocytes. The EGFR was similarly expressed in mesenchyme, chondrocytes and osteoblasts. In skin, the distribution of the EGFR was more localized, being expressed strongly in the deeper cells of the epidermis but not in superficial layers, and was absent from nuclei of cells of the epidermis and its appendages. We conclude that this signalling system is widely distributed in growing antler in a manner which suggests it is predominantly autocrine. No clear-cut evidence for paracrine signalling pathways for this system in either integument or osseous compartments was found. The pattern of distribution of the EGFR in the integument was similar to that seen by others in adult human skin. By contrast, in developing antler osseocartilage, the patterns of distribution were similar to those seen in rodent fetal bone. We conclude that antler consists of rapidly growing fetal osseocartilage overlayed by mature velvet.