双斑蟋营养成分分析及评价

由于具有较好的营养价值以及较高的食物转化效率,食用昆虫特别是蟋蟀受到普遍关注。在双斑蟋（Gryllus bimaculatus,GB）营养成分测定的基础上,对比家蟋（Acheta domesticus,AD）和黑蟋（Gryllus testaceus,GT）的营养及含量,分析评价了双斑蟋的使用价值。结果显示：双斑蟋水分含量71.0%、粗蛋白含量58.60%（干重）、粗脂肪含量28.90%（干重）、粗纤维含量7.23%（干重）、灰分4.93%（干重）;蛋白含量与黑蟋相当而高于家蟋,粗脂肪和灰分含量要高于家蟋和黑蟋;双斑蟋含有17种氨基酸,总氨基酸含量51.03%（干重）,必需氨基酸含量24.76%（干重）、占总氨基酸的48.3%,氨基酸含量低于其他两种蟋蟀;双斑蟋中常量元素含量最高的为钾（6 416 mg/kg,干重）、含量最低的是钙（92 mg/kg,干重）,微量元素中锌含量较高（241 mg/kg,干重）;双斑蟋油脂中不饱和脂肪酸的相对含量为65.33%,以亚油酸（37.05%）和油酸（25.86%）为主、饱和脂肪酸以棕榈酸（25.44%）和硬脂酸（8.74%）为主。双斑蟋的脂肪酸组成、含量与家蟋相近,而与黑蟋的脂肪酸组成差别较大,三种蟋蟀中含量最高的饱和脂肪酸为棕榈酸,而含量最高的不饱和酸为亚油酸。结果表明,双斑蟋的必需氨基酸组成符合FAO/WHO推荐的氨基酸构成比例的蛋白条件,具有较高的营养价值和食用价值。     

安徽4个不同地区石菖蒲中挥发油成分及其质量差异分析

运用气相色谱-质谱联用技术（GC-MS）对安徽4个不同地区石菖蒲中挥发油成分进行分析,并对其质量进行评价。结果显示,皖南山区、大别山区、安庆及芜湖地区石菖蒲挥发油中依次分别鉴定出45、52、48、54种化合物,共同化合物为25种,各产地已鉴定的25种共同化学成分含量分别占各自总成分的93.27%、84.75%、90.73%、92.84%,其中含量最高的β-细辛醚含量占比依次为54.73%、50.12%、57.24%、60.15%,其次α-细辛醚依次为32.18%、30.14%、28.15%、26.15%,4个地区石菖蒲挥发油中均不含黄樟醚。不同地区石菖蒲中挥发油化合物存在一定差异,安徽地区石菖蒲安全性均较高且大别山区石菖蒲最为优质。     

皂苷类药物的制剂研究进展

皂苷类药物普遍分子量比较大,水溶性好,但不易透过细胞膜难以被人体吸收,因此口服制剂体内生物利用度较低.近年来对单体皂苷及总皂苷类药物制剂方面的研究越来越多,随着新型的给药系统和新辅料的出现,皂苷类药物在体内的生物利用度大大提高.本文主要介绍以单体皂苷或总皂苷活性部位为主药的制剂研究进展,以期为该类成分的进一步研究提供思路.     

Molecular cloning and characterization of ascorbate oxidase gene in non-heading Chinese cabbage

The cDNA clone of ascorbate oxidase gene was isolated from non-heading Chinese cabbage (Brassica campestris ssp. chinensis Makino, cv. Suzhouqing) and characterized. Sequence analysis showed that there was a high similarity between this sequence (named BcAO) and its homologues in other plant species. Southern blotting indicated that more than one nuclear gene encoded this enzyme in non-heading Chinese cabbage. The mRNA level of the BcAO gene in leaves was monitored by real-time PCR at different developmental stages and under different stress conditions. Results showed that the expression of BcAO was upregulated by light, and the BcAO gene responded to copper stress as well. After inoculation with Alternaria brassicae, the expression of BcAO in the leaves was increased in general and peaked at 12 and 72 h post inoculation, with much higher expression at the later date. Cloning the BcAO gene will enable us to further understand its function and would provide useful information for resistance breeding program for non-heading Chinese cabbage.     

HCV-specific interleukin-21+CD4+ T cells responses associated with viral control through the modulation of HCV-specific CD8+ T cells function in chronic hepatitis C patients

Interleukin-21 (IL-21)+CD4+ T cells are involved in the immune response against hepatitis B virus (HBV) by secreting IL-21. However, the role of IL-21+CD4+ T cells in the immune response against chronic hepatitis C (CHC) virus infection is poorly understood. This study aimed to investigate the role of IL-21+CD4+ T cells in CHC patients and the potential mechanisms. The study subjects included nineteen CHC patients who were grouped by viral load (low, < 10⁶ RNA copies/ml, n = 8; high, > 10⁶ RNA copies/ml, n = 11). The peripheral frequency of HCV-specific IL-21+CD4+ T cells was higher in the low viral load group and was negatively correlated with the serum HCV RNA viral load in all CHC patients. Meanwhile, IL-21+ cells accumulated in the liver in the low viral load group. In vitro, IL-21 treatment increased the expression of proliferation markers and cytolytic molecules on HCV-specific CD8+ T cells. In summary, these findings suggest that HCV-specific IL-21+CD4+ T cells might contribute to HCV control by rescuing HCV-specific CD8+ T cells in CHC patients.     

Effects and statistical optimization of fermentation conditions on growth and poly (vinyl alcohol)-degrading enzyme production of Streptomyces venezuelae GY1

The effects of environmental conditions, including temperature, pH and dissolved oxygen, on growth and production of polyvinyl alcohol (PVA)-degrading enzymes of the newly-isolated strain Streptomyces venezuelae GY1 were investigated. The medium composition for strain GY1 was studied first by single factorial design and then optimized using a central composite design. PVA with high saponification is better for growth of, and PVA-degrading enzyme production by S. venezuelae GY1 compared with PVA with low saponification, in contrast with the characteristics of other bacteria producing PVA-degrading enzymes. The optimal temperature and initial pH for production of PVA-degrading enzyme by strain GY1 was 30°C and 7.0, respectively. The optimal medium composition for PVA-degrading enzyme production is: 1.01 g L^?1 of PVA1799, 0.307 g L^?1 of NaNO₃ and 0.512 g L^?1 of MgSO₄?7H₂O.     

A Developmental Framework for Complex Plasmodesmata Formation Revealed by Large-Scale Imaging of the Arabidopsis Leaf Epidermis

Plasmodesmata (PD) form tubular connections that function as intercellular communication channels. They are essential for transporting nutrients and for coordinating development. During cytokinesis, simple PDs are inserted into the developing cell plate, while during wall extension, more complex (branched) forms of PD are laid down. We show that complex PDs are derived from existing simple PDs in a pattern that is accelerated when leaves undergo the sink–source transition. Complex PDs are inserted initially at the three-way junctions between epidermal cells but develop most rapidly in the anisocytic complexes around stomata. For a quantitative analysis of complex PD formation, we established a high-throughput imaging platform and constructed PDQUANT, a custom algorithm that detected cell boundaries and PD numbers in different wall faces. For anticlinal walls, the number of complex PDs increased with increasing cell size, while for periclinal walls, the number of PDs decreased. Complex PD insertion was accelerated by up to threefold in response to salicylic acid treatment and challenges with mannitol. In a single 30-min run, we could derive data for up to 11k PDs from 3k epidermal cells. This facile approach opens the door to a large-scale analysis of the endogenous and exogenous factors that influence PD formation.     

Calcium/Calmodulin-Dependent Protein Kinase Is Negatively and Positively Regulated by Calcium,Providing a Mechanism for Decoding Calcium Responses during Symbiosis Signaling

The establishment of symbiotic associations in plants requires calcium oscillations that must be decoded to invoke downstream developmental programs. In animal systems, comparable calcium oscillations are decoded by calmodulin (CaM)–dependent protein kinases, but symbiotic signaling involves a calcium/CaM–dependent protein kinase (CCaMK) that is unique to plants. CCaMK differs from the animal CaM kinases by its dual ability to bind free calcium, via calcium binding EF-hand domains on the protein, or to bind calcium complexed with CaM, via a CaM binding domain. In this study, we dissect this dual regulation of CCaMK by calcium. We find that calcium binding to the EF-hand domains promotes autophosphorylation, which negatively regulates CCaMK by stabilizing the inactive state of the protein. By contrast, calcium-dependent CaM binding overrides the effects of autophosphorylation and activates the protein. The differential calcium binding affinities of the EF-hand domains compared with those of CaM suggest that CCaMK is maintained in the inactive state at basal calcium concentrations and is activated via CaM binding during calcium oscillations. This work provides a model for decoding calcium oscillations that uses differential calcium binding affinities to create a robust molecular switch that is responsive to calcium concentrations associated with both the basal state and with oscillations.