The thermo‐adjustable hydrophilic/hydrophobic properties of AB, ABA and BAB block copolymers in which A is poly(methyl vinyl ether) (PMVE) and B is poly(isobutyl vinyl ether) (PIBVE) have been investigated. The block copolymers were prepared by “living” cationic polymerization using sequential addition of monomers. The polymerizations were carried out with the system acetal/trimethylsilyl iodide as initiator and ZnI2 as activator. The initiating system based on diethoxyethane leads to AB block copolymers whereas the initiating system based on tetramethoxypropane leads to ABA or BAB triblock copolymers. Well‐defined block copolymers of different composition with controlled molecular weights up to approx. 10 000 have been prepared. When IBVE is added to living PMVE, PIBVE‐blocks form only in the presence of an additional amount of ZnI2, which is attributed to the fact that part of the ZnI2 is inactive because of complex formation with PMVE. At room temperature, the combination of hydrophilic (PMVE) and hydrophobic (PIBVE) segments provides the copolymers with surfactant properties. Above the lower critical solution temperature (LCST) of PMVE, situated around 36 °C, the PMVE‐blocks become hydrophobic and the amphiphilic nature of the block copolymers is lost. The corresponding changes in hydrophilic/hydrophobic balance have been evaluated by investigation of the emulsifying properties of the block copolymers for water/decane mixtures as a function of the temperature. Below the LCST, the block copolymers have emulsifying properties similar to or better than those of the commercial PEO‐PPO block copolymers (Pluronic®). Either oil‐in‐water or water‐in‐oil emulsions can be obtained, depending on the polymer architecture and the water/decane volume ratio. The emulsifying properties are strongly reduced or completely lost above 40 °C. Emulsions obtained with a PMVE36‐b‐PIBVE54 block copolymer for a water/decane (v/v) ratio of 85/15 remained stable for more than six months.
50/50 and a 85/15 water/decane w/o emulsion (15 g/l) with the PMVE36‐b‐PIBVE54 block copolymer at 20 °C. 相似文献
Targeted mutagenesis in model organisms is key for gene functional annotation and biomedical research. Despite technological advances in gene editing by the CRISPR-Cas9 systems, rapid and efficient introduction of site-directed mutations remains a challenge in large animal models. Here, we developed a robust and flexible insertional mutagenesis strategy, homology-independent targeted trapping (HIT-trapping), which is generic and can efficiently target-trap an endogenous gene of interest independent of homology arm and embryonic stem cells. Further optimization and equipping the HIT-trap donor with a site-specific DNA inversion mechanism enabled one-step generation of reversible and conditional alleles in a single experiment. As a proof of concept, we successfully created mutant alleles for 21 disease-related genes in primary porcine fibroblasts with an average knock-in frequency of 53.2%, a great improvement over previous approaches. The versatile HIT-trapping strategy presented here is expected to simplify the targeted generation of mutant alleles and facilitate large-scale mutagenesis in large mammals such as pigs.Following the completion of animal genome sequencing projects, rapid and efficient mutagenesis strategies are needed for analyzing gene function and for creating human disease models. Gene trapping is a high-throughput mutagenesis strategy whereby random vector insertion can be achieved across the mouse genome. A typical gene-trap vector contains a promoter-less reporter/selection gene flanked by an upstream splice acceptor (SA) and a downstream poly(A) signal. Upon insertion into an intron of a gene, the vector both inactivates the trapped gene and enables the gene-specific expression of a reporter gene (Gossler et al. 1989; Stanford et al. 2001). To date, gene-trapping approaches have been successfully applied toward large-scale mutagenesis in mouse embryonic stem cells (mESCs) and generation of gene knockout mice (Skarnes et al. 2004). The main drawback of random gene trapping is that gene-trap alleles are not specifically engineered to target genes of interest in advance. Therefore, methods to streamline the introduction of predesigned, site-specific modifications into the genome by homologous recombination would represent a significant technological advance. Previously, a hybrid approach combining gene targeting and gene trapping (targeted trapping) enabled mutation of expressed genes in mESCs with high efficiency, using a gene-trap construct flanked by homologous sequences of the target locus (Friedel et al. 2005). Also, homologous recombination is commonly used for creating conditional alleles, which is essential to avoid embryonic lethality and to study the stage- and tissue-specific functions of genes (Branda and Dymecki 2004). However, both standard gene trapping and targeted trapping are only suitable for genes expressed in embryonic stem (ES) cells. Furthermore, construction of targeting donor vectors with homology arms is labor intensive and costly, and the low efficiency of homologous recombination is also a rate-limiting step for gene targeting in mammalian genomes.Recently, by taking advantage of precise genomic double-strand breaks (DSBs) created by the clustered regularly interspaced short palindromic repeats (CRISPR)-associated protein 9 (Cas9) system (Ran et al. 2013; Doudna and Charpentier 2014; Hsu et al. 2014), homology-directed repair (HDR) efficiency was substantially enhanced (Porteus and Carroll 2005), and even donors with short homology arms (Orlando et al. 2010) or single-stranded DNA oligonucleotides (Chen et al. 2011; Quadros et al. 2017) were found to be compatible with site-specific integration. However, each targeting donor for HDR still needs to be customized with gene-specific homology sequences. Because of the lack of ES cells for certain animals such as pigs, sheep, and cattle, the genome must be edited either in a zygote embryo or in a somatic cell for somatic cell nuclear transfer (SCNT) (Reddy et al. 2020). It is still not feasible to achieve large-scale insertional mutagenesis including conditional knockouts in these important species with random gene trapping or HDR-based methods. Also, the problem of genetic mosaicism in embryo editing remains unresolved (Mehravar et al. 2019), prompting a need for technological advances to accelerate genetic modification in somatic cells.Alternatively, the generally more efficient nonhomologous end joining (NHEJ) pathway has been exploited for site-specific insertion of exogenous DNA by simultaneous cleavage of both donor plasmid and genome using programmable nucleases (Cristea et al. 2013; Maresca et al. 2013; Brown et al. 2016; Suzuki et al. 2016; Sawatsubashi et al. 2018). In contrast to HDR-based strategies, NHEJ-mediated insertions do not require gene-specific homology arms, enabling diverse sites to be targeted with a universal donor vector. Therefore, we speculated that a gene-trap cassette could be inserted into a specific locus easily through this mechanism in any cell type.Here, by combining NHEJ-mediated knock-in and gene trapping, we developed a strategy for targeted mutagenesis, especially in somatic cells with low HDR activity, referred to as HIT-trapping. By using a universal donor, this strategy allows us to (1) create null alleles, (2) produce a fluorescent reporter signal that could potentially allow cells with null alleles to be identified very quickly, and (3) produce reversible and conditional alleles that would be very helpful to have in most animal models but are often cumbersome to create. 相似文献
Summary Kinematic variables of the vertical jump (jumping height, jump phase durations and joint angles) were measured on 39 male
physical education students. In addition, kinetic parameters of the hip and knee extensors, and of the plantar flexors (maxima
voluntary force and its rate of development) were recorded on the same subjects, in isometric conditions. The results demonstrated
significant positive correlations between kinetic parameters of the active muscle groups and jumping height (r=0.217−0.464). The dominant effect on these correlations was due to the knee extensors. Correlations between these parameters
and the duration of the jump phases were much weaker. Correlation coefficients between kinetic parameters and limb angles
in the lowest body position showed that fast force production in one muscle group was related to a significant decrease in
the joint angles of distant body segments. Multiple correlation coefficients between leg extensor parameters and kinematic
variables (ranging between 0.256 for the duration of the counter-movement phase and 0.616 for jump height) suggested that
kinetic parameters could explain more than a quarter of the variability of this complex human movement. Therefore, the conclusion
was drawn that an extended set of measurements of the relevant musculo-skeletal system parameters could predict a considerable
amount of the variability of human movement. However, high correlation coefficients between the same kinetic parameters of
different muscle groups suggest that not all active muscle groups have to be included in the measurements. 相似文献
Zebrafish SmyD1 is a SET and MYND domain-containing protein that plays an important role in myofiber maturation and muscle contraction. SmyD1 is required for myofibril organization and sarcomere assembly during myofiber maturation. Whole-mount in situ hybridization revealed that smyd1 mRNAs are specifically expressed in skeletal and cardiac muscles in zebrafish embryos. However, it is unknown if smyd1 is expressed in other striated muscles, such as cranial and fin muscles, and moreover, the regulatory elements required for its muscle-specific expression. We report here the analyses of smyd1 expression using smyd1-gfp transgenic zebrafish. smyd1-gfp transgenic zebrafish were generated using the 5.3-kb smyd1 promoter and its 5'-flanking sequence. GFP expression was found in the skeletal and cardiac muscles of smyd1-gfp transgenic embryos. GFP expression appeared stronger in slow muscles than fast muscles in transgenic zebrafish larvae. In addition, GFP expression was also detected in cranial and fin muscles of smyd1-gfp transgenic zebrafish larvae. In situ hybridization confirmed smyd1 mRNA expression in these tissues, suggesting that the expression of the smyd1-gfp transgene recapitulated that of the endogenous smyd1 gene. Deletion analysis revealed that the 0.5-kb sequence in the proximal promoter of smyd1 was essential for its muscle specificity. Together, these data indicate that smyd1 is specifically expressed in most, if not all, striated muscles, and the muscle specificity is controlled by the 5.3-kb promoter and flanking sequences. 相似文献
