Correction of substitution, deletion, and insertion mutations by 5'-tailed duplexes.

Germline and somatic mutations cause various diseases, including cancer. Clinical applications of genome editing are keenly anticipated, since it can cure genetic diseases. Recently, we reported that a 5'-tailed duplex (TD), consisting of an approximately 80-base editor strand oligodeoxyribonucleotide and a 35-base assistant strand oligodeoxyribonucleotide, could edit a target gene on plasmid DNA and correct a single-base substitution mutation without an artificial nuclease in human cells. In this study, we assessed the ability of the TD to correct base substitution mutations located consecutively or separately, and deletion and insertion mutations. A TD with an 80-base editor strand was co-introduced into human U2OS cells with plasmid DNA bearing either a wild-type or mutated copepod green fluorescent protein (copGFP) gene. Among the mutations, three-base consecutive substitutions were efficiently repaired. The correction efficiencies of deletion mutations were similar to those of substitution mutations, and two to three times higher than those of insertion mutations. Up to three-base substitution, deletion, and insertion mutations were excellent targets for correction by TDs. These results suggested that the TDs are useful for editing disease-causing genes with small mutations.

[Construction and application of lentivirus overexpression vector with two labeling genes fused with CopGFP and PuroR].

Objective: To construct the lentivirus overexpression vector with two label genes fused with CopGFP and PuroR and to detect the emission of green fluorescence as well as resistance to puromycin in liver cancer cells infected with lentivirus packaged with the above vector. Methods: Firstly, two fragments containing copGFP and PuroR coding sequences were amplified from pCDH-CMV-MCS-copGFP and pLKO.1 respectively; secondly, the two amplified regions were fused with each other by recombinant PCR; thirdly, the fusion DNA fragment was cut and inserted into pCDH-CMV-MCS-copGFP vector, which was linearized with the same restriction endonuclease as used to digest fusion DNA fragment: BamH Ⅰ and Sal Ⅰ. The fusion region in the constructed vector was confirmed by DNA sequencing. The checked vector was co-transfected with package assistant plasmids, namely PLP1, PLP2 and VSVG into in 293T cells and the culture supernatant was subjected to centrifuge and infect liver cancer MHCC97H cells, which were then used to detect their resistance to puromycin (infected cells were treated with 1 mg/ml puromycin for 7 days after infection) and to observe green fluorescence emission in microscope. To determine its efficiency in expressing foreign target protein, the Sp1 coding region was inserted into the MCS sites of the vector, and Sp1 mRNA and protein expression levels were compared with the vehicle vector by RT-qPCR and Western blot. Results: The lentivirus overexpression vector with two label genes fused with CopGFP and PuroR was successfully constructed, and the liver cancer cells infected with lentivirus packaged with the vector expressing two labeling genes fused with CopGFP and PuroRshowed both emission of green fluorescence and resistance to puromycin simultaneously, while cells containing with the vector inserted with Sp1 coding region improved Sp1 mRNA level with 3.3 fold and protein level with 2.2 fold higher in comparison with cells containing the vehicle vector (P＜0.01). Conclusion: The fused label genes consisting of copGFP and PuroR are correctly cloned into the lentivirus vector and confer cells with the ability to emission of green fluorescence and resistance to puromycin, besides, the vector may promote the expression of the target gene with long coding sequence.

Correction of monomeric enhanced green fluorescent protein (mEGFP) gene by short 5'-tailed duplexes.

Mutations of important genes elicit various disorders, including cancer. Recently, a new version of a 5'-tailed duplex (short TD), consisting of a ∼100-base editor strand containing the wild-type sequence and a ∼35-base assistant strand, was shown to correct a base substitution mutation in a target gene in human cells. In that previous study, the target was the copepod green fluorescent protein (copGFP) gene. To examine the usefulness of the short TD, we performed gene correction experiments using a mutant form of the monomeric enhanced Aequorea victoria green fluorescent protein (mEGFP) gene containing a TAC to CAC mutation in codon 75 (corresponding to the tyrosine to histidine substitution in the chromophore). The short TDs with the wild-type sequence efficiently corrected the inactivated gene in human U2OS cells. These results indicated that the short TDs are effective for gene editing.

Using genetically modified extracellular vesicles as a non-invasive strategy to evaluate brain-specific cargo.

The lack of techniques to trace brain cell behavior in vivo hampers the ability to monitor status of cells in a living brain. Extracellular vesicles (EVs), nanosized membrane-surrounded vesicles, released by virtually all brain cells might be able to report their status in easily accessible biofluids, such as blood. EVs communicate among tissues using lipids, saccharides, proteins, and nucleic acid cargo that reflect the state and composition of their source cells. Currently, identifying the origin of brain-derived EVs has been challenging, as they consist of a rare population diluted in an overwhelming number of blood and peripheral tissue-derived EVs. Here, we developed a sensitive platform to select out pre-labelled brain-derived EVs in blood as a platform to study the molecular fingerprints of brain cells. This proof-of-principle study used a transducible construct tagging tetraspanin (TSN) CD63, a membrane-spanning hallmark of EVs equipped with affinity, bioluminescent, and fluorescent tags to increase detection sensitivity and robustness in capture of EVs secreted from pre-labelled cells into biofluids. Our platform enables unprecedented efficient isolation of neural EVs from the blood. These EVs derived from pre-labelled mouse brain cells or engrafted human neuronal progenitor cells (hNPCs) were submitted to multiplex analyses, including transcript and protein levels, in compliance with the multibiomolecule EV carriers. Overall, our novel strategy to track brain-derived EVs in a complex biofluid opens up new avenues to study EVs released from pre-labelled cells in near and distal compartments into the biofluid source.

Gene correction by 5'-tailed duplexes with short editor oligodeoxyribonucleotides.

Various diseases, including cancer, are caused by genetic mutations. A 5'-tailed duplex (TD) DNA, consisting of a long single-stranded (ss) editor DNA and a short (∼35-base) ss assistant oligodeoxyribonucleotide, can introduce a base-substitution in living cells and thus correct mutated genes. Previously, several hundred-base DNAs were employed as the editor DNAs. In this study, 5'-TDs were prepared from various editor DNAs with different lengths and examined for their gene correction abilities, using plasmid DNA bearing a mutated copepod green fluorescent protein (copGFP) gene, in human cells. High-throughput analysis was performed by the reactivated fluorescence of the wild-type protein encoded by the corrected gene as the indicator. The analysis revealed that 5'-TDs with ∼100-base ss editor DNAs enabled gene editing at least as efficiently as those with longer editor DNAs. Moreover, the antisense strand was more effective as the editor than the sense strand, in contrast to the 5'-TDs with longer editor strands. These results indicated that the 5'-TD fragments with shorter editor strands than those used in previous studies are useful nucleic acids for gene correction.

CRISPR/Cas9-Mediated Gene Tagging: A Step-by-Step Protocol.

CRISPR/Cas9 provides a simple and powerful tool for modifying almost any DNA of interest. One promising application of the CRISPR/Cas9 system is for tagging genes with a fluorescence marker or tag peptides. For such a purpose, FLAG, HIS, and HA tags or fluorescence proteins (EGFP, BFP, RFP, etc.) have been broadly used to tag endogenous genes of interest. The advantages of generating fluorescence tagging proteins are to provide easy tracing of the subcellular locations, real-time monitoring the expression and dynamics of the protein in different conditions, which cannot be achieved using traditional immunostaining or biochemistry assays. However, the generation of such a gene-tagged cell line could be technically challenging. In this chapter, we demonstrate the generation of tagging the porcine GAPDH (pGAPDH) gene GFP by CRISPR/Cas9-based homology-directed repair.