Combining orthogonal CRISPR and CRISPRi systems for genome engineering and metabolic pathway modulation in Escherichia coli.

CRISPR utilizing Cas9 from Streptococcus pyogenes (SpCas9) and CRISPR interference (CRISPRi) employing catalytically inactive SpCas9 (SpdCas9) have gained popularity for Escherichia coli engineering. To integrate the SpdCas9-based CRISPRi module using CRISPR while avoiding mutual interference between SpCas9/SpdCas9 and their cognate single-guide RNA (sgRNA), this study aimed at exploring an alternative Cas nuclease orthogonal to SpCas9. We compared several Cas9 variants from different microorganisms such as Staphylococcus aureus (SaCas9) and Streptococcus thermophilius CRISPR1 (St1Cas9) as well as Cas12a derived from Francisella novicida (FnCas12a). At the commonly used E. coli model genes  LacZ, we found that SaCas9 and St1Cas9 induced DNA cleavage more effectively than FnCas12a. Both St1Cas9 and SaCas9 were orthogonal to SpCas9 and the induced DNA cleavage promoted the integration of heterologous DNA of up to 10 kb, at which size St1Cas9 was superior to SaCas9 in recombination frequency/accuracy. We harnessed the St1Cas9 system to integrate SpdCas9 and sgRNA arrays for constitutive knockdown of three genes, knock-in pyc and knockout adhE, without compromising the CRISPRi knockdown efficiency. The combination of orthogonal CRISPR/CRISPRi for metabolic engineering enhanced succinate production while inhibiting byproduct formation and may pave a new avenue to E. coli engineering.

Combining CRISPR and CRISPRi Systems for Metabolic Engineering of E. coli and 1,4-BDO Biosynthesis.

Biosynthesis of 1,4-butanediol (1,4-BDO) in E. coli requires an artificial pathway that involves six genes and time-consuming, iterative genome engineering. CRISPR is an effective gene editing tool, while CRISPR interference (CRISPRi) is repurposed for programmable gene suppression. This study aimed to combine both CRISPR and CRISPRi for metabolic engineering of E. coli and 1,4-BDO production. We first exploited CRISPR to perform point mutation of gltA, replacement of native lpdA with heterologous lpdA, knockout of sad and knock-in of two large (6.0 and 6.3 kb in length) gene cassettes encoding the six genes (cat1, sucD, 4hbd, cat2, bld, bdh) in the 1,4-BDO biosynthesis pathway. The successive E. coli engineering enabled production of 1,4-BDO to a titer of 0.9 g/L in 48 h. By combining the CRISPRi system to simultaneously suppress competing genes that divert the flux from the 1,4-BDO biosynthesis pathway (gabD, ybgC and tesB) for >85%, we further enhanced the 1,4-BDO titer for 100% to 1.8 g/L while reducing the titers of byproducts gamma-butyrolactone and succinate for 55% and 83%, respectively. These data demonstrate the potential of combining CRISPR and CRISPRi for genome engineering and metabolic flux regulation in microorganisms such as E. coli and production of chemicals (e.g., 1,4-BDO).

Enhancing Protein Production Yield from Chinese Hamster Ovary Cells by CRISPR Interference.

Chinese hamster ovary (CHO) cells are an important host for biopharmaceutical production. Generation of stable CHO cells typically requires cointegration of dhfr and a foreign gene into chromosomes and subsequent methotrexate (MTX) selection for coamplification of dhfr and foreign gene. CRISPR interference (CRISPRi) is an emerging system that effectively suppresses gene transcription through the coordination of dCas9 protein and guide RNA (gRNA). However, CRISPRi has yet to be exploited in CHO cells. Here we constructed vectors expressing the functional CRISPRi system and proved effective CRISPRi-mediated suppression of dhfr transcription in CHO cells. We next generated stable CHO cell clones coexpressing DHFR, the model protein (EGFP), dCas9 and gRNA targeting dhfr. Combined with MTX selection, CRISPRi-mediated repression of dhfr imparted extra selective pressure to force CHO cells to coamplify more copies of dhfr and egfp genes. Compared with the traditional method relying on MTX selection (up to 250 nM), the CRISPRi approach increased the dhfr copy number ∼3-fold, egfp copy number ∼3.6-fold and enhanced the EGFP expression ∼3.8-fold, without impeding the cell growth. Furthermore, we exploited the CRISPRi approach to enhance the productivity of granulocyte colony stimulating factor (G-CSF) ∼2.3-fold. Our data demonstrate, for the first time, the application of CRISPRi in CHO cells to enhance recombinant protein production and may pave a new avenue to CHO cell engineering.

Enhanced critical-size calvarial bone healing by ASCs engineered with Cre/loxP-based hybrid baculovirus.

Calvarial bone repair remains challenging for adults. Although adipose-derived stem cells (ASCs) hold promise to heal bone defects, use of ASCs for critical-size calvarial bone repair is ineffective. Stromal cell-derived factor 1 (SDF-1) is a chemokine capable of triggering stem cell migration. Although recombinant SDF-1 protein is co-delivered with other molecules including BMP-2 to facilitate calvarial bone repair, these approaches did not yield satisfactory healing. This study aimed to exploit a newly developed Cre/loxP-based hybrid baculovirus for efficient gene delivery and prolonged transgene expression in ASCs. We demonstrated that transduction of rat ASCs with the hybrid Cre/loxP-based baculovirus enabled robust and sustained expression of functional BMP-2 and SDF-1. Expression of BMP-2 or SDF-1 alone failed to effectively induce rat ASCs osteogenesis and healing of critical-size calvarial bone defects. Nonetheless, prolonged BMP-2/SDF-1 co-expression in ASCs synergistically activated both Smad and ERK1/2 pathways and hence potentiated the osteogenesis. Consequently, transplantation of the hybrid baculovirus-engineered, BMP-2/SDF-1-expressing ASCs/scaffold constructs potently healed the critical-size (6 mm) calvarial bone defects (filling ≈70% of defect volume), which considerably outperformed the calvarial bone repair using BMP-2/SDF-1 delivered with biomaterial-based scaffolds. These data implicated the potential of Cre/loxP-based hybrid baculovirus vector for ASCs engineering and calvarial bone healing.

Enhanced integration of large DNA into E. coli chromosome by CRISPR/Cas9.

Metabolic engineering often necessitates chromosomal integration of multiple genes but integration of large genes into Escherichia coli remains difficult. CRISPR/Cas9 is an RNA-guided system which enables site-specific induction of double strand break (DSB) and programmable genome editing. Here, we hypothesized that CRISPR/Cas9-triggered DSB could enhance homologous recombination and augment integration of large DNA into E. coli chromosome. We demonstrated that CRISPR/Cas9 system was able to trigger DSB in >98% of cells, leading to subsequent cell death, and identified that mutagenic SOS response played roles in the cell survival. By optimizing experimental conditions and combining the λ-Red proteins and linear dsDNA, CRISPR/Cas9-induced DSB enabled homologous recombination of the donor DNA and replacement of lacZ gene in the MG1655 strain at efficiencies up to 99%, and allowed high fidelity, scarless integration of 2.4, 3.9, 5.4, and 7.0 kb DNA at efficiencies approaching 91%, 92%, 71%, and 61%, respectively. The CRISPR/Cas9-assisted gene integration also functioned in different E. coli strains including BL21 (DE3) and W albeit at different efficiencies. Taken together, our methodology facilitated precise integration of dsDNA as large as 7 kb into E. coli with efficiencies exceeding 60%, thus significantly ameliorating the editing efficiency and overcoming the size limit of integration using the commonly adopted recombineering approach. Biotechnol. Bioeng. 2017;114: 172-183. © 2016 Wiley Periodicals, Inc.

Improved calvarial bone repair by hASCs engineered with Cre/loxP-based baculovirus conferring prolonged BMP-2 and MiR-148b co-expression.

Repairing large calvarial bone defects remains a challenging task. Previously, it was discovered that that miR-148b, when acting in concert with bone morphogenetic protein 2 (BMP-2), enhanced the osteogenesis of human adipose-derived stem cells (hASCs) and improved calvarial bone healing in nude mice. However, the molecular target of miR-148b remained elusive. Here it is revealed that miR-148b directly targets NOG, whose gene product (noggin) is an antagonist to BMPs and negatively regulates BMP-induced osteogenic differentiation and bone formation. A new Cre/loxP-based baculovirus system was employed to drive prolonged BMP-2 and miR-148b overexpression in hASCs, wherein the BMP-2 overexpression induced noggin expression but the concurrent miR-148b expression downregulated noggin, thus relieving the negative regulatory loop and ameliorating hASC osteogenesis without hindering hASC proliferation or triggering appreciable cytotoxicity. Implantation of the engineered hASCs coexpressing BMP-2 and miR-148b into nude mice enabled substantial repair of critical-size calvarial bone defects (4 mm diameter) at 12 weeks post-transplantation, filling 83% of the defect area, 75% of bone volume and restoring the bone density to 89% of the original bone density. Such superior healing effects indicate the potential of the Cre/loxP-based baculovirus-mediated BMP-2/miR-148b expression for calvarial bone repair. Copyright © 2016 John Wiley & Sons, Ltd.

CRISPR interference (CRISPRi) for gene regulation and succinate production in cyanobacterium S. elongatus PCC 7942.

BACKGROUND: Cyanobacterium Synechococcus elongatus PCC 7942 holds promise for biochemical conversion, but gene deletion in PCC 7942 is time-consuming and may be lethal to cells. CRISPR interference (CRISPRi) is an emerging technology that exploits the catalytically inactive Cas9 (dCas9) and single guide RNA (sgRNA) to repress sequence-specific genes without the need of gene knockout, and is repurposed to rewire metabolic networks in various procaryotic cells. RESULTS: To employ CRISPRi for the manipulation of gene network in PCC 7942, we integrated the cassettes expressing enhanced yellow fluorescent protein (EYFP), dCas9 and sgRNA targeting different regions on eyfp into the PCC 7942 chromosome. Co-expression of dCas9 and sgRNA conferred effective and stable suppression of EYFP production at efficiencies exceeding 99%, without impairing cell growth. We next integrated the dCas9 and sgRNA targeting endogenous genes essential for glycogen accumulation (glgc) and succinate conversion to fumarate (sdhA and sdhB). Transcription levels of glgc, sdhA and sdhB were effectively suppressed with efficiencies depending on the sgRNA binding site. Targeted suppression of glgc reduced the expression to 6.2%, attenuated the glycogen accumulation to 4.8% and significantly enhanced the succinate titer. Targeting sdhA or sdhB also effectively downregulated the gene expression and enhanced the succinate titer ≈12.5-fold to ≈0.58-0.63 mg/L. CONCLUSIONS: These data demonstrated that CRISPRi-mediated gene suppression allowed for re-directing the cellular carbon flow, thus paving a new avenue to rationally fine-tune the metabolic pathways in PCC 7942 for the production of biotechnological products.

CRISPR-Cas9 for the genome engineering of cyanobacteria and succinate production.

Cyanobacteria hold promise as a cell factory for producing biofuels and bio-derived chemicals, but genome engineering of cyanobacteria such as Synechococcus elongatus PCC 7942 poses challenges because of their oligoploidy nature and long-term instability of the introduced gene. CRISPR-Cas9 is a newly developed RNA-guided genome editing system, yet its application for cyanobacteria engineering has yet to be reported. Here we demonstrated that CRISPR-Cas9 system can effectively trigger programmable double strand break (DSB) at the chromosome of PCC 7942 and provoke cell death. With the co-transformation of template plasmid harboring the gene cassette and flanking homology arms, CRISPR-Cas9-mediated DSB enabled precise gene integration, ameliorated the homologous recombination efficiency and allowed the use of lower amount of template DNA and shorter homology arms. The CRISPR-Cas9-induced cell death imposed selective pressure and enhanced the chance of concomitant integration of gene cassettes into all chromosomes of PCC 7942, hence accelerating the process of obtaining homogeneous and stable recombinant strains. We further explored the feasibility of engineering cyanobacteria by CRISPR-Cas9-assisted simultaneous glgc knock-out and gltA/ppc knock-in, which improved the succinate titer to 435.0±35.0µg/L, an ≈11-fold increase when compared with that of the wild-type cells. These data altogether justify the use of CRISPR-Cas9 for genome engineering and manipulation of metabolic pathways in cyanobacteria.

Healing of massive segmental femoral bone defects in minipigs by allogenic ASCs engineered with FLPo/Frt-based baculovirus vectors.

Adipose-derived stem cells (ASCs) hold promise for bone regeneration but possess inferior osteogenesis potential. Allotransplantation of ASCs engineered with the BMP2/VEGF-expressing baculoviruses into rabbits healed critical-size segmental bone defects. To translate the technology to clinical applications, we aimed to demonstrate massive bone healing in minipigs that more closely mimicked the clinical scenarios, using a new hybrid baculovirus system consisting of BacFLPo expressing the codon-optimized FLP recombinase (FLPo) and the substrate baculovirus harboring the transgene flanked by Frt sequences. Co-transduction of minipig ASCs (pASCs) with BacFLPo and the substrate baculovirus enabled transgene cassette excision, recombination and minicircle formation in ≈73.7% of pASCs, which substantially prolonged the transgene (BMP2 and VEGF) expression to 28 days. When encoding BMP2, the FLPo/Frt-based system augmented the pASCs osteogenesis. Allotransplantation of the BMP2/VEGF-expressing pASCs into minipigs healed massive segmental bone defects (30 mm in length) at the mid-diaphysis of femora, as evaluated by computed tomography, positron emission tomography, histology, immunohistochemical staining and biochemical testing. The defect size was ≈15% of femoral length in minipigs and was equivalent to ≈60-70 mm of femoral defect in humans, thus the healing using pASCs engineered with the FLPo/Frt-based baculovirus represented a remarkable advance for the treatment of massive bone defects.

Efficient gene delivery into cell lines and stem cells using baculovirus.

Baculovirus is a promising vector for transducing numerous types of mammalian cells. We have developed hybrid baculovirus vectors and protocols for the efficient transduction of a variety of cell lines, primary cells and stem cells, including bone marrow-derived mesenchymal stem cells (BMSCs) and adipose-derived stem cells (ASCs). The hybrid vector enables intracellular minicircle formation and prolongs transgene expression. The advantages of this transduction protocol are that baculovirus supernatant alone needs to be added to cells growing in medium, and transduction occurs after only 4-6 h of incubation at room temperature (25 °C) with gentle shaking. The entire procedure, from virus generation to transduction, can be completed within 4 weeks. Compared with other transduction procedures, this protocol is simple and can confer efficiencies >95% for many cell types. This protocol has potential applications in tissue regeneration, as transduced cells continue to express transgenes after implantation. For example, transduction of rabbit ASCs (rASCs) with growth factor-encoding hybrid baculovirus vectors, as described as an example application in this protocol, enables robust and sustained growth factor expression, stimulates stem cell differentiation and augments tissue regeneration after implantation.

Osteogenic differentiation of adipose-derived stem cells and calvarial defect repair using baculovirus-mediated co-expression of BMP-2 and miR-148b.

Repair of large calvarial bony defect remains a challenge for orthopedic surgeons. Since microRNAs (miRNAs) modulate the osteogenesis of osteoprogenitor cells, we aimed to engineer human adipose-derived stem cells (hASCs), a promising cell source for bone engineering, with miRNA-expressing baculovirus vectors. We constructed 4 baculoviruses each expressing 1 human miRNA (miR-26a, miR-29b, miR-148b, miR-196a) and verified that the miRNA-expressing baculovirus vectors augmented hASCs osteogenesis. Among these 4 miRNAs, miR-148b and miR-196a exerted more potent osteoinductive effects than miR-26a and miR-29b. Furthermore, we unveiled that co-transduction of hASCs with miR-148b-expressing and bone morphogenetic protein 2 (BMP-2)-expressing baculovirus vectors enhanced and prolonged BMP-2 expression, and synergistically promoted the in vitro osteogenic differentiation of hASCs. Implantation of the hASCs co-expressing BMP-2/miR-148b into critical-size (4 mm in diameter) calvarial bone defects in nude mice accelerated and potentiated the bone healing and remodeling, filling ≈94% of defect area and ≈89% of defect volume with native calvaria-like flat bone in 12 weeks, as judged from micro computed tomography, histology and immunohistochemical staining. Altogether, this study confirmed the feasibility of combining miRNA and growth factor expression for synergistic stimulation of in vitro osteogenesis and in vivo calvarial bone healing.

Long-term tracking of segmental bone healing mediated by genetically engineered adipose-derived stem cells: focuses on bone remodeling and potential side effects.

We previously showed that transplantation of adipose-derived stem cells (ASCs) engineered with hybrid baculovirus (BV) persistently expressing bone morphogenetic protein 2 (BMP2)/vascular endothelial growth factor (VEGF) into segmental defects in New Zealand White (NZW) rabbits led to successful defect reunion. By using microcomputed tomography and histology, here we further demonstrated that transplanting the hybrid BV-engineered ASCs into the massive defects (10 mm in length) at the femoral diaphysis of NZW rabbits resulted in trabecular bone formation in the interior via endochondral ossification and bone remodeling at 3 months post-transplantation. The progression of bone remodeling gave rise to the resorption of trabecular bone and conspicuous reconstruction of medullary cavity and cortical bone with lamellar structure at 8 months post-transplantation, hence conferring mechanical properties that were comparable to those of nonoperated femora. Importantly, X-ray, positron emission tomography/computed tomography scans, and histopathology revealed no signs of heterotopic bone formation and tumor formation. These data altogether attested that the genetically engineered ASCs and prolonged BMP2/VEGF expression not only healed and remodeled the stringent segmental defects, but also revitalized the defects into living bone tissues that structurally and biomechanically resembled intact bones without appreciable side effects, making it one step closer to translate this technology to the clinical setting.

Regenerating cartilages by engineered ASCs: prolonged TGF-ß3/BMP-6 expression improved articular cartilage formation and restored zonal structure.

Adipose-derived stem cells (ASCs) hold promise for cartilage regeneration but their chondrogenesis potential is inferior. Here, we used a baculovirus (BV) system that exploited FLPo/Frt-mediated transgene recombination and episomal minicircle formation to genetically engineer rabbit ASCs (rASCs). The BV system conferred prolonged and robust TGF-ß3/BMP-6 expression in rASCs cultured in porous scaffolds, which critically augmented rASCs chondrogenesis and suppressed osteogenesis/hypertrophy, leading to the formation of cartilaginous constructs with improved maturity and mechanical properties in 2-week culture. Twelve weeks after implantation into full-thickness articular cartilage defects in rabbits, these engineered constructs regenerated neocartilages that resembled native hyaline cartilages in cell morphology, matrix composition and mechanical properties. The neocartilages also displayed cartilage-specific zonal structures without signs of hypertrophy and degeneration, and eventually integrated with host cartilages. In contrast, rASCs that transiently expressed TGF-ß3/BMP-6 underwent osteogenesis/hypertrophy and resulted in the formation of inferior cartilaginous constructs, which after implantation regenerated fibrocartilages. These data underscored the crucial role of TGF-ß3/BMP-6 expression level and duration in rASCs in the cell differentiation, constructs properties and in vivo repair. The BV-engineered rASCs that persistently express TGF-ß3/BMP-6 improved the chondrogenesis, in vitro cartilaginous constructs production and in vivo hyaline cartilage regeneration, thus representing a remarkable advance in cartilage engineering.

The use of ASCs engineered to express BMP2 or TGF-ß3 within scaffold constructs to promote calvarial bone repair.

Calvarial bone healing is difficult and grafts comprising adipose-derived stem cells (ASCs) and PLGA (poly(lactic-co-glycolic acid)) scaffolds barely heal rabbit calvarial defects. Although calvarial bone forms via intramembranous ossification without cartilage templates, it was suggested that chondrocytes/cartilages promote calvarial healing, thus we hypothesized that inducing ASCs chondrogenesis and endochondral ossification involving cartilage formation can improve calvarial healing. To evaluate this hypothesis and selectively induce osteogenesis/chondrogenesis, rabbit ASCs were engineered to express the potent osteogenic (BMP2) or chondrogenic (TGF-ß3) factor, seeded into either apatite-coated PLGA or gelatin sponge scaffolds, and allotransplanted into critical-size calvarial defects. Among the 4 ASCs/scaffold constructs, gelatin constructs elicited in vitro chondrogenesis, in vivo osteogenic metabolism and calvarial healing more effectively than apatite-coated PLGA, regardless of BMP2 or TGF-ß3 expression. The BMP2-expressing ASCs/gelatin triggered better bone healing than TGF-ß3-expressing ASCs/gelatin, filling ≈ 86% of the defect area and ≈ 61% of the volume at week 12. The healing proceeded via endochondral ossification, instead of intramembranous pathway, as evidenced by the formation of cartilage that underwent osteogenesis and hypertrophy. These data demonstrated ossification pathway switching and significantly augmented calvarial healing by the BMP2-expressing ASCs/gelatin constructs, and underscored the importance of growth factor/scaffold combinations on the healing efficacy and pathway.

Enhanced and prolonged baculovirus-mediated expression by incorporating recombinase system and in cis elements: a comparative study.

Baculovirus (BV) is a promising gene vector but mediates transient expression. To prolong the expression, we developed a binary system whereby the transgene in the substrate BV was excised by the recombinase (ΦC31o, Cre or FLPo) expressed by a second BV and recombined into smaller minicircle. The recombination efficiency was lower by ΦC31o (≈40-75%), but approached ≈90-95% by Cre and FLPo in various cell lines and stem cells [e.g. human adipose-derived stem cells (hASCs)]. Compared with FLPo, Cre exerted higher expression level and lower negative effects; thus, we incorporated additional cis-acting element [oriP/Epstein-Barr virus nuclear antigen 1 (EBNA1), scaffold/matrix attached region or human origin of replication (ori)] into the Cre-based BV system. In proliferating cells, only oriP/EBNA1 prolonged the transgene expression and maintained the episomal minicircles for 30 days without inadvertent integration, whereas BV genome was degraded in 10 days. When delivering bmp2 or vegf genes, the efficient recombination/minicircle formation prolonged and enhanced the growth factor expression in hASCs. The prolonged bone morphogenetic protein 2 expression ameliorated the osteogenesis of hASCs, a stem cell with poor osteogenesis potential. Altogether, this BV vector exploiting Cre-mediated recombination and oriP/EBNA1 conferred remarkably high recombination efficiency, which prolonged and enhanced the transgene expression in dividing and non-dividing cells, thereby broadening the applications of BV.

Immune responses during healing of massive segmental femoral bone defects mediated by hybrid baculovirus-engineered ASCs.

Baculovirus holds promise for genetic modification of adipose-derived stem cells (ASCs) and bone engineering. To explore the immune responses during bone healing and the cell fate, ASCs were mock-transduced (Mock group), transduced with the baculovirus transiently expressing growth factors promoting osteogenesis (BMP2) or angiogenesis (VEGF) (S group), or transduced with hybrid baculoviruses persistently expressing BMP2/VEGF (L group). After allotransplantation into massive femoral defects in rabbits, these 3 groups triggered similar degrees of transient inflammatory response (e.g. neutrophil proliferation and immune cell infiltration into the graft site), revealing that baculovirus and transgene products did not exacerbate the inflammation. The cells in all 3 groups underwent apoptosis initially, persisted for at least 4 weeks and were eradicated thereafter. The L group prolonged the in vivo BMP2/VEGF expression (up to 4 weeks), extended the antibody responses, and slightly enhanced the cell-mediated cytotoxicity. Nonetheless, the L group led to remarkably better bone healing and remodeling than the Mock and S groups. These data confirmed that the ASCs engineered with the hybrid BV imparted prolonged expression of BMP2/VEGF which, although stimulated low levels of humoral and cell-mediated immune responses, essentially augmented the healing of massive segmental bone defects.

Simultaneous induction of autophagy and toll-like receptor signaling pathways by graphene oxide.

Graphene oxide (GO) nanosheets have sparked growing interests in biological and medical applications. This study examined how macrophage, the primary immune cell type engaging microbes, responded to GO treatment. We uncovered that incubation of macrophage cell RAW264.7 with GO elicited autophagy in a concentration-dependent manner, as evidenced by the appearance of autophagic vacuoles and activation of autophagic marker proteins. Such GO-induced autophagy was observed in various cell lines and in macrophage treated with GO of different sizes. Strikingly, GO treatment of macrophage provoked the toll-like receptor (TLR) signaling cascades and triggered ensuing cytokine responses. Molecular analysis identified that TLR4 and TLR9 and their downstream signaling mediators MyD88, TRAF6 and NF-κB played pivotal roles in the GO-induced inflammatory responses. By silencing individual genes in the signaling pathway, we further unveiled that the GO-induced autophagy was modulated by TLR4, TLR9 and was dependent on downstream adaptor proteins MyD88, TRIF and TRAF6. Altogether, we demonstrated that GO treatment of cells simultaneously triggers autophagy and TLR4/TLR9-regulated inflammatory responses, and the autophagy was at least partly regulated by the TLRs pathway. This study thus suggests a mechanism by which cells respond to nanomaterials and underscores the importance of future safety evaluation of nanomaterials.

Augmented healing of critical-size calvarial defects by baculovirus-engineered MSCs that persistently express growth factors.

Repair of large calvarial bony defects remains clinically challenging because successful spontaneous calvarial re-ossification rarely occurs. Although bone marrow-derived mesenchymal stem cells (BMSCs) genetically engineered with baculovirus (BV) for transient expression of osteogenic/angiogenic factors hold promise for bone engineering, we hypothesized that calvarial bone healing necessitates prolonged growth factor expression. Therefore, we employed a hybrid BV vector system whereby one BV expressed FLP while the other harbored the BMP2 (or VEGF) cassette flanked by Frt sequences. Transduction of rabbit BMSCs with the FLP/Frt-based BV vector led to FLP-mediated episome formation, which not only extended the BMP2/VEGF expression beyond 28 days but augmented the BMSCs osteogenesis. After allotransplantation into rabbits, X-ray, PET/CT, µCT and histological analyses demonstrated that the sustained BMP2/VEGF expression remarkably ameliorated the angiogenesis and regeneration of critical-size (8 mm) calvarial defects, when compared with the group implanted with BMSCs transiently expressing BMP2/VEGF. The prolonged expression by BMSCs accelerated the bone remodeling and regenerated the bone through the natural intramembranous pathway, filling ≈83% of the area and ≈63% of the volume in 12 weeks. These data implicated the potential of the hybrid BV vector to engineer BMSCs for sustained BMP2/VEGF expression and the repair of critical-size calvarial defects.

Development of hybrid baculovirus vectors for artificial MicroRNA delivery and prolonged gene suppression.

MicroRNA (miRNA) plays essential roles in regulating gene expression, but miRNA delivery remains a hurdle, thus entailing a vector system for efficient transfer. Baculovirus emerges as a promising gene delivery vector but its inherent transient expression restricts its applications in some scenarios. Therefore, this study primarily aimed to develop baculovirus as a miRNA expression vector for prolonged gene suppression. We constructed recombinant baculoviruses carrying artificial egfp-targeting miRNA sequences within the miR155 backbone, which after expression by the cytomegalovirus promoter could knockdown the enhanced green fluorescent protein (EGFP) expression in a sequence- and dose-dependent manner. By swapping the mature miRNA sequences, the baculovirus miRNA shuttle effectively repressed the overexpression of endogenous TNF-α in arthritic synoviocytes without inducing apoptosis. To prolong the baculovirus-mediated expression, we further developed a hybrid baculovirus vector that exploited the Sleeping Beauty (SB) transposon for gene integration and sustained miRNA expression. The hybrid baculovirus vector that combined the miR155 scaffold and SB transposon effectively repressed the transgene expression for a prolonged period of time, hence diversifying the applications of baculovirus to indications necessitating prolonged gene regulation such as arthritis.

Baculovirus as a gene delivery vector for cartilage and bone tissue engineering.

Baculovirus is an effective vector for gene delivery into various mammalian cells, including chondrocytes and mesenchymal stem cells, and has been employed for diverse applications. By gene delivery and expression of the growth factor, recombinant baculovirus has been shown to modulate the differentiation state of the cells and stimulates the production of extracellular matrix and tissue formation, hence repairing the damaged cartilage and bone in vivo. This article reviews the studies pertaining to the applications of baculovirus-mediated gene delivery in cartilage and bone tissue engineering and discusses recent progress, future applications and potential hurdles.