伪狂犬病病毒上海株gE-/gI-/GFP+缺失株的生物学特性初步研究

在构建了伪狂犬病病毒上海株的缺失载体pgEI-GFP基础上,将pgEI-GFP转染感染了PRV-SH株的BHK-21细胞,待出现80%以上的细胞病变时收获病毒,并以绿色荧光蛋白为标志,通过蚀斑法得到纯化重组病毒gE-/gI-/GFP+缺失株.研究了该缺失株的的安全性、在细胞上的生长特性以及对断奶仔猪的安全性、免疫原性等生物学特性.试验结果显示,缺失了gE-和gI-后,不影响其在RK细胞上的生长状况和病毒的滴度.该疫苗株对小鼠的半数致死量比亲本毒低且对家兔的致死性的时间延长了,这表明该疫苗的毒力比亲本毒有所下降.该缺失株对断奶仔猪安全,无不良接种反应,接种断奶仔猪能抵御高剂量PRV-SH株强毒的感染,攻毒后试验猪的发热期、散毒天数均低于对照组.该缺失株接种仔猪后在试验期间一直维持较高水平的中和抗体.     

伪狂犬病病毒上海株gE^-／gI^-／GFP^＋缺失株的生物学特性初步研究

在构建了伪狂犬病病毒上海株的缺失载体pgEI-GFP基础上,将pgEI-GFP转染感染了PRV-SH株的BHK-21细胞,待出现80％以上的细胞病变时收获病毒,并以绿色荧光蛋白为标志,通过蚀斑法得到纯化重组病毒gE^-／gI^-／GFP^ 缺失株。研究了该缺失株的的安全性、在细胞上的生长特性以及对断奶仔猪的安全性、免疫原性等生物学特性。试验结果显示,缺失了gE^-和gI^-后,不影响其在RK细胞上的生长状况和病毒的滴度。该疫苗株对小鼠的半数致死量比亲本毒低且对家兔的致死性的时间延长了,这表明该疫苗的毒力比亲本毒有所下降。该缺失株对断奶仔猪安全,无不良接种反应,接种断奶仔猪能抵御高剂量PRV-SH株强毒的感染,攻毒后试验猪的发热期、散毒天数均低于对照组。该缺失株接种仔猪后在试验期间一直维持较高水平的中和抗体。     

伪狂犬病病毒基因缺失疫苗制苗用毒种特性研究

本试验通过对PRV基因缺失株SA215(gE-/gI-/TK- )细胞培养特性、理化特性及形态发生过程进行研究,来确定gE、gI和TK 基因缺失对病毒特性的影响。结果表明,基因缺失对该毒株在培养细胞的吸附和穿入过程没有影响,但与亲本株相比,表现为生长掩蔽期延长,增殖速度减缓,但能达到相似的增殖滴度,并且基因缺失对病毒的理化特性影响很小。形态发生过程观察结果表明,PRV SA215 株在细胞培养上形态发生正常,能形成感染性病毒粒子,但在由核膜出芽和囊膜形成上受到一定程度的阻碍。本研究为疫苗研制和生产提供指导和依据。     

Ⅰ型牛疱疹病毒TK-/gE-基因双缺失突变株生物学特性

目的构建Ⅰ型牛疱疹病毒（BHV-1）的TK-/gE-双缺失突变株,检测其生物学功能,为治疗牛传染性鼻气管炎提供参考。方法构建了带有EGFP表达盒的BHV-1 TK-/gE-双缺失突变株。通过southern杂交、蛋白质斑点印迹、空斑试验、MDBK细胞增殖实验等技术方法,对重组基因所构成病毒突变株的生物学特性进行鉴定。结果 Southern杂交及蛋白斑点印迹表明,课题组成功构建了带有EGFP表达盒的双缺失突变株;该突变株具有与野生株相当的繁殖力,但TK-/gE-成功缺失,毒力大幅减弱;BHV-1 TK-/gE-遗传稳定,不会返强。结论本项目组成功构建了Ⅰ型牛疱疹病毒（BHV-1）的TK-/gE-双缺失突变株,该缺失株具有良好的安全性和稳定性,为该突变株进一步作为生物安全疫苗和多价病毒载体提供了依据,为预防和治疗牛传染性鼻气管炎提供了技术支持。     

伪狂犬病病毒上海株（PRV—SH）gE^—／gI^—／GFP^＋缺失株的构建

在构建了含伪狂犬病病毒（Pseudorabies Virus,PRV）上海株gI基因和gE基因克隆鉴定的基础上,采用酶切的方法构建了载体pgEI。然后用限制性内切酶BamHI和BstPI缺失掉gE基因5‘端363bp,同时把绿色荧光蛋白（GFP）基因表达盒插入到缺失部分,并在下游 引入一个多克隆位点,构建了缺失转移载体pgEI-GFP。用DOTAP转染试剂盒将pgEI-GFP转染了感染PRV-SH的BHK-21细胞,待出现80％病变后收获病毒,并以蚀斑法得到纯化的缺失了gE/gI重组病毒株。小鼠试验证实了缺失株的毒力有所下降。     

表达O型口蹄疫病毒VPl基因的重组病毒BHV-1的构建与鉴定

[目的]为了构建表达口蹄疫病毒(O/china/99)VP1基因的牛疱疹病毒1型,将人工合成的口蹄疫病毒VP1基因插入到巨细胞病毒(CMV)启动子之下构建gE基因缺失转移载体.[方法]利用磷酸钙介导转染法将该转移载体与亲本病毒BHV-1/gE-/LacZ+的基因组DNA共转染牛鼻甲细胞后收获增殖的病毒.通过筛选白色病毒蚀斑,得到重组病毒BHV-1/gE-/VP1.[结果]PCR检测结果表明VP1基因已经插入到了重组病毒BHV-1/gE-的基因组中,间接免疫荧光试验和Westem blot证实了BHV-1/gE-/VP1中的VP1基因在感染的细胞中获得了表达.[结论]本研究成功地构建了表达口蹄疫病毒VP1基因的重组病毒BHV-1/gE-/VP1,为研制口蹄疫及其他重要牛传染病的BHV-1病毒载体疫苗奠定了基础.     

伪狂犬病病毒TK-/gG-缺失株的构建及其生物学特性研究

将伪狂犬病病毒TK^-/gG^-/LacZ⁺突变株的基因组DNA与含有缺失的gG基因的转移质粒pUSKBB共转染猪肾传代细胞PK-15,待完全病变后收获病毒进行空斑试验,用PCR筛选gG缺失的重组病毒。空斑纯化3次后,随机挑取空斑进行PCR扩增,证实所获得的病毒为均一的TK^-/gG^-缺失株。遗传稳定性试验表明该重组病毒能在PK-15细胞上稳定遗传,动物试验表明该缺失株对Balb/c小鼠极为安全且能保护Balb/c小鼠抵抗致死量PRV强毒的攻击。该突变株的获得为我国伪狂犬病的控制和根除奠定了基础。     

表达绿色荧光蛋白重组新城疫病毒 LaSota疫苗株的构建

新城疫病毒是理想的新型活病毒疫苗载体,具有巨大的优势和应用前景。采用生产实践中广泛应用、免疫效果良好的NDV LaSota弱毒疫苗株,建立了反向遗传操作系统。在此基础上,进一步构建了表达绿色荧光蛋白(GFP)的重组NDV基因组cDNA克隆,成功救获了重组病毒rLaSota-EGFP,病毒F1代尿囊病毒液按1×104EID50接种9~10日龄SPF鸡胚尿囊腔,接种后分别于24h、48h、72h及96h收获尿囊液,检测平均HA滴度分别为28、210.3、211.3和211,每mL尿囊液病毒量EID50分别为108.64、109.22、109.21和109.64,重组病毒与亲本株生长滴度在相近时间达到峰值,生长动力学特性与亲本株无明显差异。各代次重组病毒按1×106EID50病毒量接种9~10日龄SPF鸡胚,96h内完全不致死鸡胚。救获重组病毒保持了LaSota弱毒疫苗亲本毒株对鸡胚良好的高滴度生长适应和低致病特性,并且鸡胚连续传9代次仍保持GFP的稳定表达及生物学特性不变。重组病毒rLaSota-EGFP的成功救获为开展新城疫病毒活载体疫苗研制提供了可行的技术平台。     

表达绿色荧光蛋白重组新城疫病毒 LaSota疫苗株的构建

新城疫病毒是理想的新型活病毒疫苗载体,具有巨大的优势和应用前景。采用生产实践中广泛应用、免疫效果良好的NDV LaSota弱毒疫苗株,建立了反向遗传操作系统。在此基础上,进一步构建了表达绿色荧光蛋白（GFP）的重组NDV基因组cDNA克隆,成功救获了重组病毒rLaSota_EGFP,病毒F1代尿囊病毒液按1×10.4EID50接种9～10日龄SPF鸡胚尿囊腔,接种后分别于24h、48h、72h及96h收获尿囊液,检测平均HA滴度分别为2.8、2 10.3、2 11.3和2 11,每mL尿囊液病毒量EID50分别为108.64、109.22、109.21和109.64,重组病毒与亲本株生长滴度在相近时间达到峰值,生长动力学特性与亲本株无明显差异。各代次重组病毒按1×10.6EID50病毒量接种9～10日龄SPF鸡胚,96h内完全不致死鸡胚。救获重组病毒保持了LaSota弱毒疫苗亲本毒株对鸡胚良好的高滴度生长适应和低致病特性,并且鸡胚连续传9代次仍保持GFP的稳定表达及生物学特性不变。重组病毒rLaSota_EGFP的成功救获为开展新城疫病毒活载体疫苗研制提供了可行的技术平台。     

表达O型口蹄疫病毒 VP1基因的重组病毒BHV-1的构建与鉴定

摘要：【目的】为了构建表达口蹄疫病毒（O/China/99）VP1基因的牛疱疹病毒1型,将人工合成的口蹄疫病毒VP1基因插入到巨细胞病毒（CMV）启动子之下构建gE基因缺失转移载体。【方法】利用磷酸钙介导转染法将该转移载体与亲本病毒BHV-1/gE-/LacZ+的基因组DNA共转染牛鼻甲细胞后收获增殖的病毒。通过筛选白色病毒蚀斑,得到重组病毒BHV-1/gE-/VP1。【结果】PCR检测结果表明VP1基因已经插入到了重组病毒BHV-1/gE-的基因组中,间接免疫荧光试验和Western blot证实了BHV-1/gE-/VP1中的VP1基因在感染的细胞中获得了表达。【结论】本研究成功的构建了表达口蹄疫病毒VP1基因的重组病毒BHV-1/gE-/VP1,为研制口蹄疫及其他重要牛传染病的BHV-1病毒载体疫苗奠定了基础。     

Analysis of the two active sites of the hyaluronan synthase and the chondroitin synthase of Pasteurella multocida

Type A Pasteurella multocida produces a hyaluronan (HA) capsule to enhance infection. The 972-residue HA synthase, pmHAS, polymerizes the linear HA polysaccharide composed of alternating beta3N-acetylglucosamine (GlcNAc)-beta4glucuronic acid (GlcUA). We demonstrated previously that pmHAS possesses two independent glycosyltransferase sites. Here we further define the sites and putative motifs. Deletion of residues 1-117 does not affect HA polymerizing activity. The carboxyl-terminal boundary of the GlcUA-transferase resides within residues 686-703. Both transferase sites contain a DXD motif essential for HA synthase activity. D247N or D249N mutants possessed only GlcUA-transferase activity, whereas D527N or D529N mutants possessed only GlcNAc-transferase activity, further confirming our assignment of the two active sites within the synthase polypeptide. A potential role of the DXD motif in substrate binding was supported by experiments utilizing high UDP-sugar concentrations that partially rescued the activity of certain mutants. The WGGED sequence motif is involved in GlcNAc-transferase activity because mutants with substitutions at E369 or D370 possessed only GlcUA-transferase activity. Type F P. multocida synthesizes an unsulfated chondroitin (beta3GalNAc-beta4GlcUA) capsule. A chimeric enzyme consisting of residues 1-427 of pmHAS and residues 421-704 of pmCS, the homologous chondroitin synthase, was an active HA synthase. The converse chimeric enzyme consisting of residues 1-420 of pmCS and residues 428-703 of pmHAS was a functional chondroitin synthase. Analyses of a panel of pmHAS/pmCS chimeric enzymes identified a 44-residue region, corresponding to pmHAS residues 225-265, involved in UDP-hexosamine selectivity. Overall, these findings further support the model of two independent transferase sites within a single polypeptide.     

Quantification of glycosaminoglycans by reversed-phase HPLC separation of fluorescent isoindole derivatives

Glycosaminoglycans (GAGs) are linear polysaccharides made by all animal cells. GAGs bind to hundreds of proteins, such as growth factors, cytokines, chemokines, extracellular matrix components, protease inhibitors, proteases, and lipoprotein lipase, through carbohydrate and protein interactions. These interactions control many multicellular processes. The increased use of GAGs isolated from cells and small tissue samples in bioassays and binding experiments demands a sensitive and robust quantification method. We have developed such a method, which is based on a popular assay for amino acid analysis. We have refined it to enhance GAG quantification. It allows the quantification of glucosamine- and galactosamine-containing GAGs after the reversed-phase separation of their fluorescent isoindole derivatives. The derivatives are created by the reaction of o-phthaldialdehyde and 3-mercaptopropionic acid (3MPA) with the amino group of hexosaminitol monosaccharides generated from GAG acid hydrolysis and sodium borohydride reduction. The advantages of our method include automatic derivitization, a simple chromatograph with clean separation of glucosaminitol and galactosaminitol derivatives from contaminating amino acids, excellent sensitivity with 0.04 pmol detection, and linearity from 2.5 to 1280 pmol. A major advantage is that it can be readily implemented in any laboratory with typical reversed-phase high performance liquid chromatography (HPLC) equipment.     

Topology and mutational analysis of the single Emb arabinofuranosyltransferase of Corynebacterium glutamicum as a model of Emb proteins of Mycobacterium tuberculosis

The cell wall mycolyl-arabinogalactan (AG)--peptidoglycan complex is essential in mycobacterial species, such as Mycobacterium tuberculosis, and is the target of several antitubercular drugs. For instance, ethambutol (EMB) targets AG biosynthesis through inhibition of the arabinofuranosyltransferases Mt-EmbA and Mt-EmbB, as well as the single Emb from Corynebacterium glutamicum. Here, we present for the first time an experimental analysis of the membrane topology of Emb. The domain organization clearly positions highly conserved loop regions, like the recognized glycosyltransferase C motif and the hydrophilic C-terminus towards the periplasmic side of the cell. Moreover, the assignment and orientation of hydrophobic segments identified a loop region, which might dip into the membrane and could possibly line a transportation channel for the emerging substrate. Site-directed mutations introduced into plasmid-encoded Cg-emb were analyzed in a C. glutamicumDeltaemb strain for their AG glycosyl composition and linkage analysis. Mutations analyzed did not perturb galactan synthesis; however, D297A produced a dramatically reduced arabinan content and prevented growth, indicating an inactive Emb. A second D298A mutation also drastically reduced arabinan content; however, growth of the corresponding mutant was not altered, indicating a certain tolerance of this mutation in terms of Emb function. A W659L-P667A-Q674E triple mutation in the chain length regulation motif (Pro-motif) resulted in a reduced arabinose deposition in AG but retained all arabinofuranosyl linkages. Taken together, the data clearly define important residues of Emb involved in arabinan domain formation and, for the first time, shed new light on the topology of this important enzyme.     

Increased expression of protein C-mannosylation in the aortic vessels of diabetic Zucker rats

C-Mannosylation is a novel type of glycosylation in proteins. There are several examples of proteins in which the specific motif Trp-X-X-Trp is mannosylated at the first Trp to produce C-mannosylated Trp (CMW). Although C-mannosylation modifies Trp-X-X-Trp, predicted to be a functional motif of various integral proteins such as cytokine receptors, the physiological or pathological relevance of C-mannosylation in the cell is still not known. In this study, to characterize C-mannosylation in biological samples, we generated specific polyclonal antibodies against CMW by using a chemically synthesized CMW as an antigen. Using the antibody, we investigated the effect of hyperglycemic conditions on protein C-mannosylation in cultured cells and diabetic Zucker fatty rats. We found that protein C-mannosylation was increased in macrophage-like RAW264.7 cells under hyperglycemic conditions compared to low-glucose conditions. Furthermore, C-mannosylation was increased in the aortic vessel wall of Zucker fatty rats. Thrombospondin-1 was identified as a protein modified with C-mannosylation, and its expression was also increased in the aortic tissues of Zucker fatty rats. These results indicate that C-mannosylation is increased in specific tissues or cell types under hyperglycemic conditions, suggesting a pathological role for the increased C-mannosylation in the development of diabetic complications.     

Detailed glycan analysis of serum glycoproteins of patients with congenital disorders of glycosylation indicates the specific defective glycan processing step and provides an insight into pathogenesis

The fundamental importance of correct protein glycosylation is abundantly clear in a group of diseases known as congenital disorders of glycosylation (CDGs). In these diseases, many biological functions are compromised, giving rise to a wide range of severe clinical conditions. By performing detailed analyses of the total serum glycoproteins as well as isolated transferrin and IgG, we have directly correlated aberrant glycosylation with a faulty glycosylation processing step. In one patient the complete absence of complex type sugars was consistent with ablation of GlcNAcTase II activity. In another CDG type II patient, the identification of specific hybrid sugars suggested that the defective processing step was cell type-specific and involved the mannosidase III pathway. In each case, complementary serum proteome analyses revealed significant changes in some 31 glycoproteins, including components of the complement system. This biochemical approach to charting diseases that involve alterations in glycan processing provides a rapid indicator of the nature, severity, and cell type specificity of the suboptimal glycan processing steps; allows links to genetic mutations; indicates the expression levels of proteins; and gives insight into the pathways affected in the disease process.     

Pathogenesis of primary defects in mitochondrial ATP synthesis

Maternally inherited mutations in the mtDNA-encoded ATPase 6 subunit of complex V (ATP synthase) of the respiratory chain/oxidative phosphorylation system are responsible for a subgroup of severe and often-fatal disorders characterized predominantly by lesions in the brain, particularly in the striatum. These include NARP (neuropathy, ataxia, and retinitis pigmentosa), MILS (maternally inherited Leigh syndrome), and FBSN (familial bilateral striatal necrosis). Of the five known pathogenic mutations causing these disorders, four are located at two codons (156 and 217), each of which can suffer mutations converting a conserved leucine to either an arginine or a proline. Based on the accumulating data on both the structure of ATP synthase and the mechanism by which rotary catalysis couples proton flow to ATP synthesis, we propose a model that may help explain why mutations at codons 156 and 217 are pathogenic.     

Glycoprofiling with micro-arrays of glycoconjugates and lectins

To facilitate deciphering the information content in the glycome, thin film-coated photoactivatable surfaces were applied for covalent immobilization of glycans, glycoconjugates, or lectins in microarray formats. Light-induced immobilization of a series of bacterial exopolysaccharides on photoactivatable dextran-coated analytical platforms allowed covalent binding of the exopolysaccharides. Their specific galactose decoration was detected with fluorescence-labeled lectins. Similarly, glycoconjugates were covalently immobilized and displayed glycans were profiled for fucose, sialic acid, galactose, and lactosamine epitopes. The applicability of such platforms for glycan profiling was further tested with extracts of Caco2 epithelial cells. Following spontaneous differentiation or on pretreatment with sialyllactose, Caco2 cells showed a reduction of specific glycan epitopes. The changed glycosylation phenotypes coincided with altered enteropathogenic E. coli adhesion to the cells. This microarray strategy was also suitable for the immobilization of lectins through biotin-neutravidin-biotin bridging on platforms functionalized with a biotin derivatized photoactivatable dextran. All immobilized glycans were specifically and differentially detected either on glycoconjugate or lectin arrays. The results demonstrate the feasibility and versatility of the novel platforms for glycan profiling.     

Alteration of neural tissue structure by expression of polysialic acid induced by viral delivery of PST polysialyltransferase

The expression of polysialic acid (PSA) on neural cell adhesion molecule (NCAM) is known to attenuate cell-cell interactions. During neural development the widespread expression of PSA-NCAM creates permissive conditions for the migration of neuronal and glial precursors and the guidance and targeting of axons. NCAM polysialylation can occur via either of two specific sialyltransferases, ST8SiaII (STX) and ST8SiaIV (PST), and the purpose of this study was to determine if retroviral delivery of either PST or STX could induce PSA expression in vivo and thereby alter tissue plasticity. Retroviruses expressing GFP-PST or GFP-STX were injected into embryonic retina, and development was evaluated by examining neuroepithelial structure, the expression of markers for specific cell types, cellular proliferation, and apoptosis. Chick retina was chosen because it down-regulates PSA early in its development and has a highly stereotyped program of morphogenesis. Retroviral expression of PST induced PSA expression in retina and resulted in severe but localized alterations in retinal morphogenesis, including an early disruption of radial glial cell morphology, highly disorganized retinal layers, and invasion of pigmented cells into the neural retina. In contrast, retroviral delivery of STX did not induce PSA expression or affect morphogenesis. These findings demonstrate that expression of PSA is sufficient to promote morphological alterations in a relatively nonplastic neural tissue.     

Effects of the sugar headgroup of a glycoglycerolipid on the phase behavior of phospholipid model membranes in the dry state

Glycolipids are important components of almost all biological membranes. They possess unique properties that have only been incompletely characterized so far. The plant glycolipid digalactosyldiacylglycerol (DGDG) strongly influences the physical behavior of phospholipid model membranes in both the dry and hydrated state. It was, however, unclear whether the strong effect of DGDG on the gel to liquid-crystalline phase transition temperature (Tm) in dry phosphatidylcholine (PC) bilayers is mainly due to the high degree of unsaturation of the DGDG fatty acyl chains or to interactions between the DGDG and PC headgroups. Also, no information on the relative effectiveness of membrane bound and free sugars on membrane phase behavior was available. We have used Fourier-transform infrared spectroscopy (FTIR) to investigate the phase properties and H-bonding patterns in dry membranes made from 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphatidylcholine (POPC) containing one saturated and one monounsaturated (16:0/18:1) fatty acid and different fractions of DGDG or 1,2-dilinolenoyl-sn-glycero-3-phosphatidylcholine (DLPC) (18:3/18:3). This was compared to the effects of galactose (Gal) and digalactose (diGal). All additives depressed Tm of the dry membranes, but DGDG was much more effective than DLPC or Gal. diGal had a similar effect as DGDG, pointing to the sugar headgroup as the component with the strongest influence on membrane phase behavior. A combination of DLPC and diGal, which should theoretically be equivalent to DGDG, was much more effective than the galactolipid. H-bonding interactions with the P = O group of PC were also stronger for free diGal than for DGDG, indicating that the free sugar may be structurally more flexible to adopt an optimal conformation for interactions with the PC headgroup.