The role of endosymbionts in the evolution of haploid-male genetic systems in scale insects (Coccoidea)

There is an extraordinary diversity in genetic systems across species, but this variation remains poorly understood. In part, this is because the mechanisms responsible for transitions between systems are often unknown. A recent hypothesis has suggested that conflict between hosts and endosymbiotic microorganisms over transmission could drive the transition from diplodiploidy to systems with male haploidy (haplodiploidy, including arrhenotoky and paternal genome elimination [PGE]). Here, we present the first formal test of this idea with a comparative analysis across scale insects (Hemiptera: Coccoidea). Scale insects are renowned for their large variation in genetic systems, and multiple transitions between diplodiploidy and haplodiploidy have taken place within this group. Additionally, most species rely on endosymbiotic microorganisms to provide them with essential nutrients lacking in their diet. We show that species harboring endosymbionts are indeed more likely to have a genetic system with male haploidy, which supports the hypothesis that endosymbionts might have played a role in the transition to haplodiploidy. We also extend our analysis to consider the relationship between endosymbiont presence and transitions to parthenogenesis. Although in scale insects there is no such overall association, species harboring eukaryote endosymbionts were more likely to be parthenogenetic than those with bacterial symbionts. These results support the idea that intergenomic conflict can drive the evolution of novel genetic systems and affect host reproduction.     

Rapid induction of large chromosomal deletions by a Cre/inverted loxP system in mouse ES Cell hybrids

Loss of heterozygosity by whole or partial loss of chromosomal regions is crucial to genetic disorders, cancers and diseases. It is difficult to analyze the mechanisms of pathogenesis caused by large-scale chromosomal abnormalities due to the extreme rarity of this mutagenesis. Using a Cre/inverted loxP system, we have generated a chromosome elimination cassette (CEC) that induces a selective loss of embryonic-stem-cell-derived chromosomes in undifferentiated embryonic stem cell-somatic cell hybrids. Here, due to the increased expression of Cre, rapid formation of Cre recombination products and immediate loss of CEC-tagged chromosomes were detected by fluorescence in situ hybridization. Cre also initiated intrachromosomal recombination between identical short sequences outside loxP, leading to large chromosomal deletions of CEC-tagged regions. The Cre-mediated antiparallel synapses likely act as a scaffold to bring the identical short sequences into close proximity for recombination. This CEC technology might allow better understanding of the modulator sequences responsible for the tangled structure formation and its solution mechanism, inducing mitotic recombination leading to chromosomal deletions.     

Optimal fed-batch operation of recombinant cells subject to plasmid instability and death

Optimal feed rate strategy is studied for fed-batch culture of recombinant cells with plasmid instability and with different death rates for the plasmid-free cells (PFC) and plasmid-bearing cells (PBC). Most of the fed-batch fermentation is known to have first-order singularity and therefore a single singular arc. However, this study shows that a singular arc with second-order singularity and therefore two distinct singular arcs are possible for a recombinant cell process if PFC and PBC are subjected to death, and their specific growth rates are proportional to each other. Two types of singular arcs are elucidated and analyzed. The optimal policies over the singular arcs are theoretically explored as these findings reveal qualitative information on the singular arc, which is critically important in providing the optimal initial conditions in numerical computation of optimal feed rate profile.     

Mathematical Model of Growth and Heterologous Hantavirus Protein Production of the Recombinant Yeast Saccharomyces cerevisiae

A segregated mathematical model was developed for the analysis and interpretation of cultivation data of growth of the recombinant yeast Saccharomyces cerevisiae on multiple substrates (glucose, maltose, pyruvate, ethanol, acetate, and galactose). The model accounts for substrate consumption, plasmid stability, and production level of a model protein, a modified nucleocapsid protein of the Puumala virus. Recombinant nucleocapsid proteins from different Hantaviruses have previously been demonstrated as suitable antigens for diagnostics as well as for sero‐epidemiological studies. The model is based on a system of 10 nonlinear ordinary differential equations and accounts for the influence of various factors, e.g., selective pressure for enhancing plasmid stability by formaldehyde or the toxic effects of the intracellular accumulation of the heterologous protein on cell growth and product yield. The model allows the growth of two populations of cells to be simulated: plasmid‐bearing and plasmid‐free yeast cells, which have lost the plasmid during cultivation. Based on the model, sensitivity studies in respect to parameter changes were performed. These enabled, for example, the evaluation of the impact of an increase in the initial concentration of nutrients and growth factors (e.g., vitamins, microelements, etc.) on the biomass yield and the heterologous protein production level. As expected, the productivity of the heterologous protein in S. cerevisiae is closely correlated with plasmid stability. The 25 free model parameters, including the yield coefficients for different growth stages and dynamic constants, were estimated by nonlinear techniques, and the model was validated against a data set not used for parameter estimation. The simulation results were found to be in good agreement with the experimental data.     

质粒pRSET-A前导肽串联多聚体的构建及其多克隆抗体制备*

质粒pRSET-A是一个常用的高效原核表达载体,编码一N端含组氨酸标签（6×His）的34aa前导肽序列,以方便利用抗组氨酸标签抗体鉴定或纯化所表达的重组蛋白。本实验设计一对两侧含编码疏水性氨基酸密码子的引物,经过扩增前导序列10~34aa基因序列,并重新克隆入质粒pRSET-A构建串联二聚体后,再利用质粒pRSET-A的BamH I / Bgl II同尾酶克隆位点,经一系列简单的酶切和连接,快速构建这一前导肽中不含组氨酸标签序列的串联多聚体基因,并成功表达其六聚体重组蛋白。将此重组蛋白主动免疫山羊,获得了能够特异地识别pRSET-A编码的N端前导肽序列的抗体。结果显示,所制备的羊抗10~34aa前导肽抗体能够识别pRSET-A指导表达的含有完整前导肽的重组蛋白,但不能识别不含10~34aa序列的重组蛋白;同时,利用同位酶技术可以快速高效构建短肽的串联多聚体以制备具有高免疫原性的亚单位疫苗或免疫调控物质。     

Normal adult climbing fiber monoinnervation of cerebellar Purkinje cells in mice lacking MHC class I molecules

Some immune system proteins have recently been implicated in the development and plasticity of neuronal connections. Notably, proteins of the major histocompatibility complex 1 (MHC class 1) have been shown to be involved in synaptic plasticity in the hippocampus and the development of projection patterns in the visual system. We examined the possible role for the MHC class 1 proteins in one well-characterized example of synaptic exuberance and subsequent refinement, the climbing fiber (CF) to Purkinje cell (PC) synapse. Cerebella from adult mice deficient for two MHC genes, H2-D1 and H2-K1, and for beta2-microglobulin gene were examined for evidence of deficient elimination of supernumerary CF synapses on their PCs. Electrophysiological and morphological evidence showed that, despite the absence of these MHC class 1 molecules, adult PCs in these transgenic mice are monoinnervated as in wild-type animals. These findings indicate that, at the level of restriction of afferent number at this synapse, functional MHC class 1 proteins are not required.     

Oxidative DNA cleavage by Schiff base tetraazamacrocyclic oxamido nickel(II) complexes

Nickel is considered a weak carcinogen. Some researches have shown that bound proteins or synthetic ligands may increase the toxic effect of nickel ions. A systematic study of ligand effects on the interaction between nickel complexes and DNA is necessary. Here, we compared the interactions between DNA and six closely related Schiff base tetraazamacrocyclic oxamido nickel(II) complexes NiL(1-3a,1-3b). The structure of one of the six complexes, NiL(3b) has been characterized by single crystal X-ray analysis. All of the complexes can cleave plasmid DNA under physiological conditions in the presence of H(2)O(2). NiL(3b) shows the highest DNA cleavage activity. It can convert supercoiled DNA to nicked DNA then linear DNA in a sequential manner as the complex concentration or reaction time is increased. The cleavage reaction is a typical pseudo-first-order consecutive reaction with the rate constants of 3.27+/-0.14h(-1) (k(1)) and 0.0966+/-0.0042h(-1) (k(2)), respectively, when a complex concentration of 0.6mM is used. The cleavage mechanism between the complex and plasmid DNA is likely to involve hydroxyl radicals as reactive oxygen species. Circular dichronism (CD), fluorescence spectroscopy and gel electrophoresis indicate that the complexes bind to DNA by partial intercalative and groove binding modes, but these binding interactions are not the dominant factor in determining the DNA cleavage abilities of the complexes.     

A rapid and non leaky way for preparation of the sharp intracellular recording microelectrodes

To fill microelectrodes using backfilling method needs excessive time approximately 4–6  h. It is often difficult to fill microelectrodes without damage or leakage. A main problem is bubble formation in microelectrodes which has an impact on the electrical properties of the electrode and thus it influences the quality of the recording. Based on Archimede's principle there is a force within a solution which pushes insoluble material with a lower specific gravity upward and outside of the solution. Centrifugation can increase the force to eliminate the bubbles.

We designed a microelectrode holder to protect microelectrode sensitive tips from mechanical damage due to the gravity tensions; it can help to eliminate the bubbles easily and simultaneously in 10  min or less.

The tests were performed for 2000, 4000, and 8000  rpm centrifugation each one for 3, 6 and 12  min duration respectively, it was found that the bubbles were completely eliminated at 8000  rpm for 6–12  min and there were no significant differences for resistance, and the number of leaky or damaged electrodes between the two methods.

In the new design of devices, the materials used and the design of the holder are simple and the approach is applicable to many laboratories worldwide.     

Two approaches to construct mammalian expression vector of shRNA to reduce expression and replication of HBV in vitro

Two approaches have been developed to construct plasmids that mediate RNA interference to inhibit the replication and expression of HBV in 2.2.15 cell. The overlapping PCR extension and restriction enzyme-digestion were used to generate DNA fragments encoding designed shRNA based on sequences of ORF C of HBV genome. The pU6 derived vectors were constructed to develop plasmid based shRNA delivery systems termed pU6/HBVi. There were significant reductions in the expression of HBsAg and HBeAg between cells transfected with pU6/HBVi and control groups (as to HBsAg: P < 0. 01; and HBeAg: P < 0. 01). Consistently, the HBV DNA copies were reduced from 2.71 x 10(7) to <5 x 10(2) copies with or without pU6/HBVi. These results suggested that shRNA delivery by recombinant plasmids harboring shRNA encoding DNA fragment of interest generated either by overlapping PCR extension or restriction enzyme-digestion, could inhibit expressions of viral proteins and reduce viral replications. The pU6 derived plasmids might be a useful shRNA delivery system in mammalian cells. In addition, we found siRNA based on stealth 2311 was a potent RNAi target of HBV genome.     

Host-specific factors determine the persistence of IncP-1 plasmids

Conjugative plasmids play a very important role in bacterial adaptation through the dissemination of useful traits. Incompatibility group P-1 (IncP-1) plasmids exhibit an extreme broad-host-range among Gram-negative bacteria and known to be one of the major agents to disseminate various phenotypic traits such as antibiotic resistance and xenobiotic degradation. Although the plasmids are believed to be very stable in most Gram-negative bacteria, little is known about the factors that affect their stability in various hosts, allowing their persistence in bacterial population. Here we show that the stability of the cryptic IncP-1β plasmid pBP136 differed greatly in four different Escherichia coli K12 host backgrounds (MG1655, DH5α, EC100, and JM109), whereas the closely related plasmid pB10 was stable in all four strains. The supply of the kleF gene, which is involved in the stability of IncP-1 plasmids but absent in pBP136, did not improve the stability of the plasmid. Our findings suggest that persistence of IncP-1 plasmids in the absence of selection is affected by strain-specific factors.