Generation of <Emphasis Type="Italic">Vibrio anguillarum</Emphasis> Ghost by Coexpression of PhiX 174 Lysis <Emphasis Type="Italic">E</Emphasis> gene and Staphylococcal Nuclease <Emphasis Type="Italic">A</Emphasis> Gene

Vibrio anguillarum ghosts (VAG) were generated, for the first time, using a conjugation vector containing a ghost bacteria inducing cassette, pRK-λP_R-cI-Elysis, in which the expression of PhiX174 lysis gene E was controlled by the P _R /cI regulatory system of lambda phage. By scanning electron microscopy, holes ranging 80–200 nm in diameter were observed in the VAG. To avoid the presence of bacterial genomic DNA and an antibiotic resistance gene in the final VAG product, we constructed a new dual vector, pRK-λP_R-cI-E-SNA, containing the E-mediated lysis cassette and the staphylococcal nuclease A (SNA)-mediated DNA degradation cassette, and generated safety-enhanced VAG for use as a fish vaccine.     

锌指核酸酶技术的应用

锌指核酸酶(zinc finger nuclease,ZFN)技术是近年来发展起来的一种对基因组DNA实现靶向修饰的新技术。ZFN通过作用于基因组DNA上特异的靶位点产生DNA双链切口(double strand break,DSB),然后经过非同源末端连接(non-homologous end joining,NHEJ)或同源重组(homologous recombination,HR)途径实现对基因组DNA的靶向敲除或者替换。该技术近些年来已经被广泛应用于基因靶向修饰的研究。本文在简要介绍ZFN技术的基础上,重点综述了目前该技术在基因靶向修饰中的应用研究进展,并同时对该技术目前所需解决的一些问题以及未来的研究方向进行了分析。     

基因前定点敲入FLAG标签表达的FLAG-SND1蛋白参与胞内应激颗粒的形成

CRISPR/Cas9 (clustered regularly interspaced short palindromic repeats-Cas9 nuclease) 基因编辑技术是近年来新兴的一种可以实现基因特异性敲除和敲入的技术。本文利用CRISPR/Cas9基因编辑系统,将3×FLAG标签定点敲入HeLa细胞SND1基因前方,使细胞内源性表达的SND1蛋白带有3×FLAG标签,并观察SND1与应激颗粒及加工体的定位情况。设计针对SND1基因起始密码子ATG附近的sgRNA,以px459为表达载体,构建出重组真核表达质粒。设计含有3×FLAG及待插入位置上下游150 bp同源臂的序列,经公司合成获得重组质粒。将2个质粒共同转染HeLa细胞,使用嘌呤霉素筛选阳性细胞,挑取单克隆后培养。Western 印迹表明,细胞表达3×FLAG-SND1融合蛋白质。提取细胞基因组DNA进行测序。测序无误获得稳定株后,用流式细胞术检测细胞周期和凋亡,发现与WT细胞相比无显著性差异。同时,使用0.5 mmol/L亚砷酸钠处理,细胞发生氧化应激,eIF2α蛋白磷酸化增加,胞浆中出现应激颗粒,SND1与应激颗粒标志蛋白TIAR存在共定位现象,但不存在与加工体蛋白DCP1α的共定位。     

Impaired mammary tumor formation and metastasis by the point mutation of a Smad3 linker phosphorylation site

Triple-negative breast cancer (TNBC) is often aggressive and metastatic. Transforming growth factor-β acts as a tumor-promoter in TNBC. Smad3, a major downstream effector protein in the TGF-β signaling pathway, is regulated by phosphorylation at several sites. The functional significance of the phosphorylation of the linker region in Smad3 is poorly understood for TNBC. Among the four sites in the Smad3 linker region, threonine-179 (T179) appears to be unique as it serves as the binding site for multiple WW-domain-containing proteins upon phosphorylation, suggesting that this phosphorylation is a key for Smad3 to engage other pathways.Using genome editing, we introduced for the first time a knock-in (KI) mutation in the endogenous Smad3 gene in IV2, a lung-tropic subline of the human MDA-MB-231 TNBC cell line. In the resulting cell line, the Smad3 T179 phosphorylation site is replaced by non-phosphorylatable valine (T179V) with the mutation in both alleles.The T179V KI reduced cell growth rate and mammosphere formation. These phenomena were accompanied by a significant upregulation of p21^Cip1 and downregulation of c-Myc. The T179V KI also reduced cell migration and invasion in vitro. In the mouse xenograft models, the T179V KI markedly reduced the establishment of primary tumor in the mammary fat pad and the lung metastasis.Our results using gene editing indicate the cancer-promoting role of Smad3 T179 phosphorylation in the human TNBC cells. Our findings highly suggest that controlling this phosphorylation may have therapeutic potential for TNBC.     

Biosynthetic incorporation of tryptophan analogues into staphylococcal nuclease: effect of 5-hydroxytryptophan and 7-azatryptophan on structure and stability.

5-Hydroxytryptophan (5HW) and 7-azatryptophan (7AW) are analogue of tryptophan that potentially can be incorporated biosynthetically into proteins and used as spectroscopic probes for studying protein-DNA and protein-protein complexes. The utility of these probes will depend on the extent to which they can be incorporated and the demonstration that they cause minimal perturbation of a protein's structure and stability. To investigate these factors in a model protein, we have incorporated 5HW and 7AW biosynthetically into staphylococcal nuclease A, using a trp auxotroph Escherichia coli expression system containing the temperature-sensitive lambda cI repressor, Both tryptophan analogues are incorporated into the protein with good efficiency. From analysis of absorption spectra, we estimate approximately 95% incorporation of 5HW into position 140 of nuclease, and we estimate approximately 98% incorporation of 7AW, CD spectra of the nuclease variants are similar to that of the tryptophan-containing protein, indicating that the degree of secondary structure is not changed by the tryptophan analogues. Steady-state fluorescence data show emission maxima of 338 nm for 5HW-containing nuclease and 355 nm for 7AW-containing nuclease. Time-resolved fluorescence intensity and anisotropy measurements indicate that the incorporated 5HW residue, like tryptophan at position 140, has a dominant rotational correlation time that is approximately the value expected for global rotation of the protein. Guanidine-hydrochloride-induced unfolding studies show the unfolding transition to be two-state for 5HW-containing protein, with a free energy change for unfolding that is equal to that of the tryptophan-containing protein. In contrast, the guanidine-hydrochloride-induced unfolding of 7AW-containing nuclease appears to show a non-two-state transition, with the apparent stability of the protein being less than that of the tryptophan form.     

A network of allosterically coupled residues in the bacteriophage T4 Mre11–Rad50 complex

The Mre11–Rad50 (MR) protein complex, made up of a nuclease and ATPase, respectively, is involved in the processing of double‐strand breaks as part of an intricate mechanism for their repair. Although it is clear that the MR complex is subject to allosteric regulation and that there is communication between the nuclease and ATPase active sites, the underlying mechanisms are poorly understood. We performed statistical coupling analysis on Mre11 and Rad50 to predict linked residues based on their evolutionary correlation. This analysis predicted a coevolving sector of six residues that may be allosterically coupled. The prediction was tested using double‐mutant cycle analysis of nuclease and ATPase activity. The results indicate that a tyrosine residue located near the active site of Mre11 is allosterically coupled to several Rad50 residues located over 40 Å away. This allosteric coupling may be the basis for the reciprocal regulation of the ATPase and nuclease activities of the complex.     

Intrinsic protein disorder could be overlooked in cocrystallization conditions: An SRCD case study

X‐ray diffractometry dominates protein studies, as it can provide 3D structures of these diverse macromolecules or their molecular complexes with interacting partners: substrates, inhibitors, and/or cofactors. Here, we show that under cocrystallization conditions the results could reflect induced protein folds instead of the (partially) disordered original structures. The analysis of synchrotron radiation circular dichroism spectra revealed that the Im7 immunity protein stabilizes the native‐like solution structure of unfolded NColE7 nuclease mutants via complex formation. This is consistent with the fact that among the several available crystal structures with its inhibitor or substrate, all NColE7 structures are virtually the same. Our results draw attention to the possible structural consequence of protein modifications, which is often hidden by compensational effects of intermolecular interactions. The growing evidence on the importance of protein intrinsic disorder thus, demands more extensive complementary experiments in solution phase with the unligated form of the protein of interest.     

Transgenic trait deployment using designed nucleases

The demand for crops requiring increasingly complex combinations of transgenes poses unique challenges for transgenic trait deployment. Future value‐adding traits such as those associated with crop performance are expected to involve multiple transgenes. Random integration of transgenes not only results in unpredictable expression and potential unwanted side effects but stacking multiple, randomly integrated, independently segregating transgenes creates breeding challenges during introgression and product development. Designed nucleases enable the creation of targeted DNA double‐strand breaks at specified genomic locations whereby repair can result in targeted transgene integration leading to precise alterations in DNA sequences for plant genome editing, including the targeting of a transgene to a genomic locus that supports high‐level and stable transgene expression without interfering with resident gene function. In addition, targeted DNA integration via designed nucleases allows for the addition of transgenes into previously integrated transgenic loci to create stacked products. The currently reported frequencies of independently generated transgenic events obtained with site‐specific transgene integration without the aid of selection for targeting are very low. A modular, positive selection‐based gene targeting strategy has been developed involving cassette exchange of selectable marker genes which allows for targeted events to be preferentially selected, over multiple cycles of sequential transformation. This, combined with the demonstration of intragenomic recombination following crossing of transgenic events that contain stably integrated donor and target DNA constructs with nuclease‐expressing plants, points towards the future of trait stacking that is less dependent on high‐efficiency transformation.