The reproductive toxicity of saponins isolated from Cortex Albiziae in female mice / 中国天然药物

Saponin frsom Cortex Albiziae (SCA) are extensively used in the clinical treatment of tumor and depression. However, SCA may cause several adverse effects, including reproductive toxicity. The present study was designed to assess the mechanism by which SCA cause reproductive toxicity in female mice. The general reproductive toxicity testing was accomplished in female Kunming mice. The animals were divided into four groups: three groups that were treated by oral gavage with 135, 270, and 540 mg·kg(-1)·d(-1) of SCA prepared in physiological saline, respectively, and one vehicle control group that was treated with physiological saline only. The gestational toxicity tests were conducted at 540 mg·kg(-1)·d(-1). The general reproductive toxicity results showed that the pregnancy rate of the SCA-treated group decreased with the pregnancy rate being decreased by 70% at 540 mg·kg(-1)·d(-1). SCA elicited maternal toxicity in the ovary and the uterus, but no fetal toxicity or teratogenicity was observed. The rates of implantation in the early, middle, and late pregnancy were all decreased, with stillbirths and maternal deaths being observed. Histopathological changes showed that SCA adversely affected the ovary and the uterus. In conclusion, SCA-induced reproductive toxicity in female mice is most likely caused by its damage to the ovary and the uterus.

Research advances in herpesviruses glycoprotein N gene and its encoded protein / 病毒学报

Glycoprotein N is encoded by glycoprotein N (gN) gene of herpesviruses. The amino acid composition and expression level of this protein vary among difference species of herpesviruses. According to present studies, gN protein is expressed in cytoplasm of host cells, mainly in endoplasmic reticulum. The gN forms a complex with glycoprotein M in host cells. The complex is involved in the processes of viral replication and inter-cellular infection. Moreover, this protein plays a role in immune evasion from host immune system. The study will provide a theoretical basis for further study of herpesvirus gN gene and its encoded protein.

Research advances in the Cap gene of circovirus and its encoding capsid protein / 病毒学报

The Cap gene of antisense strand of circovirus has the most variation of the genome, and encodes a capsid protein which has the main immunogenicity. The N-terminal of capsid protein makes up of nuclear localization signal which is involved with virus location. This review summarizes the research advance of Cap gene of circovirus in the sequence characteristics, its encoding capsid protein, basic functions of the capsid protein and its interaction with MKRN1 protein, Hsp40 protein, receptor protein gClqR and complement factor C1qB protein. This paper lays a theory foundation for the further study of the capsid protein in the aspects of viral attachment, replication and transportation.

Study on preparation process and stability of beta-cyclodextrin inclusion compound in volatile oil of Cinnamomum longepaniculatum leaves / 中国中药杂志

To study the optimum preparation process and stability of beta-cyclodextrin inclusion compound in volatile oil of Cinnamomum longepaniculatum leaves. The saturated aqueous solution method was adopted to prepare inclusion compounds for an orthogonal test. The inclusion compound productivity and the inclusion rate were taken as indexes for screening the inclusion processes. The inclusion effect was evaluated with the infrared spectrophotometry and TLC, and the stability under conditions of high temperature, high humidity and strong light was detected. Under optimum preparation conditions for inclusion, the ratio between volatile oil and beta-cyclodextrin was 1: 8 (mL: g), that between beta-cyclodextrin and water was 1: 15, the inclusion temperature was 40 degrees C, and the inclusion time was 3 h. The results of spectrophotometry and TLC showed that the optimum conditions can generate beta-cyclodextrin inclusion compound in volatile oil of C. longepaniculatum leaves with certain light resistance, thermo-stability and hygro-stability. Therefore the optimum inclusion process features simple operation and stable inclusion compounds.

Research on the gene structure of duck hepatitis B virus and its encoding proteins / 病毒学报

Duck hepatitis B virus (DHBV) belongs to the Avihepadnavirus genus of the Hepadnaviridae, and it not only has the same replication pattern, but also has the similar genomic and antigenic structures to Hepatitis B virus (HBV). The genome of DHBV is a partially double-stranded closed circular DNA. The genome consists of three distinct open reading frames (ORFs): ORF-PreS/S, ORF-PreC/C and ORF-P, which all locate on the negative DNA strand and encode four separate proteins. The ORF-PreS/S encodes envelope proteins L and S, and the ORF-PreC/C and ORF-P encode capsid proteins C and polymerase proteins P, respectively. The characteristics of genome structure,viral proteins features and functions were described in this review in order to provide useful information for the further study of DHBV and the duck model infected by DHBV.

Cloning, prokaryotic expression and subcellular localization in the infected host cells of the duck plague virus DPV UL35 gene / 病毒学报

Based on the duck plague virus (DPV) UL35 gene sequence that our laboratory obtained (GenBank accession number EF643558), a pair of primers was designed using Oligo6.0 and primer5.0, then the UL35 gene was amplified from DPV CHv strain genomic DNA and cloned into the pMD18-T to construct a clone plasmid pMD18-T-UL35. After identification of the pMD18-T-UL35 by PCR amplification and restriction digestion, the fragment of the UL35 gene was subcloned into the prokaryotic expression vector pET-32a(+). The resultant recombinant plasmid pET-32a(+)-UL35 was then transformed into E. coli BL21 (DE3) strain and optimally-expressed under the induction of 1.0 mmol/L IPTG at 34 degrees C for 5 hours. SDS-PAGE analysis showed the recombinant protein (VP26) had a molecular weight of about 33KDa and accounted for 32.3% of total bacterial protein by gel scanning. The protein was then purified by Ni(2+)-affinity chromatography and used to immunize rabbit for producing the VP26 anti-serum and its antibody titer was up to 1:32 detected by agar diffusion reaction. After the IgG of the polyclonal antibodies was purified by High-Q anion-exchange chromatography, Western blot analysis indicated that the IgG had specific reaction with the VP26. Moreover, the subcellular localization detection was observed using immunofluorescence technique. The results showed that the specific fluorescences appeared relatively few in nucleus in 2 to 8 hours and increased gradually in 12 to 36 hours and eventually reached to the maximum, which aggregated in the spot region of the nucleus after the duck embryo fibroblast (DEF) were infected by DPV. However, there were only a small amount of specific fluorescences in the cytoplasm in 12 hours and increased with the extension of infection time in 24 to 48 hours. The specific fluorescences finally reached to the maximum in the cytoplasm in 72 hours. The results provided significant data for furthering the study on the function of DPV UL35 gene.

Studies on the propagation characteristics of duck plague virulent virus in duck embryo fibroblasts / 病毒学报

The propagation characteristics of virulent duck plague virus (DPV) in duck embryo fibroblast (DEF) were studied by the method of light microscopy observation of DEF cell culture monolayer, electron microscopy observation of infected DEF cell culture, real-time PCR detecting virus propagation. The results demonstrated that on duck embryo fibroblast a number of plaques were formed by DPV 42 h postinfection. Electron microscopy of the ultrathin section of infected duck embryo fibroblasts demonstrated that the nucleic acid of DPV was round in shape with diameter of 35-45 nm and was often in a cluster in the nucleus of DEF. The nucleocapsid of DPV was round in shape with diameter of 90-100 nm and could be observed both in nucleus and cytoplasm of DEF. The mature DPV which had the structures of envelop and tegument was spherical in shape with diameter of 150-300 nm and was located in cytoplasmic vacuoles. DPV penetrated the DEF cell membrane by direct fusion between the viral envelop and the plasma membrane. Progeny viral nucleic acid was produced in the nucleus and the assembled nucleocapsids obtained the structure of tegument in the cytoplasm and obtained the structure of envelop by budding into the cytoplasmic vesicles. The mature DPV particles were released out of the cell through exocytosis of the cytoplasmic vesicles. Detection of DPV by real-time PCR demonstrated that virus in DEF began its obvious propagation 10 h postinfection and virus amount tended to increase until 30 h postinfection. DPV began to be released into the supernatant 22 h postinfection and the DPV amount peaked 50 h postinfection, when the virus content in DEF and supernatant both underwent approximately 10(3) fold increase. DPV mainly existed in the DEF and the virus content in DEF was 10(2)-10(3) fold than the supernatant.