Purpose

The transformation of fibroblasts to myofibroblasts is critical to corneal wound healing, stromal haze formation, and scarring. It has recently been demonstrated that the provision of biomimetic substratum topographic cues inhibits the progression toward the myofibroblast phenotype under the influence of transforming growth factor β1 (TGF-β1). The objective of this study was to determine the effect of another fundamental biophysical cue, substrate compliance, on TGF-β1-induced myofibroblast transformation of primary corneal cells isolated from human and rabbit corneas.

Methods

Human and rabbit corneal fibroblasts were cultured on surfaces of varying substrate compliance (4-71 kPa) and tissue culture plastic (TCP) (> 1 gigapascal [GPa]). Cells were cultured in media containing TGF-β1 at concentrations of 0, 1, or 10 ng/mL for 72 hours. RNA and protein were collected from cells cultured on polyacrylamide gels and TCP and were analyzed for the expression of α-smooth muscle actin (α-SMA), a key marker of myofibroblast transformation, using quantitative PCR, immunocytochemistry, and Western blot.

Results

Cells grown on more compliant substrates demonstrated significantly reduced amounts of α-SMA mRNA compared with TCP. Immunocytochemistry and Western blot analysis determining the presence of α-SMA corroborated this finding, thus confirming a reduced transformation to the myofibroblast phenotype on more compliant substrates compared with cells on TCP in the presence of TGF-β1.

Conclusions

These data indicate that substrate compliance modulates TGF-β1-induced expression of α-SMA and thus influences myofibroblast transformation in the corneal stroma. This provides further evidence that biomimetic biophysical cues inhibit myofibroblast transformation and participate in stabilizing the native cellular phenotype.

Reduction sensitive linkers (RSLs) have the potential to transform the field of drug delivery due to their ease of use and selective cleavage in intracellular environments. However, despite their compelling attributes, developing reduction sensitive self-immolative linkers for aliphatic amines has been challenging due to their poor leaving group ability and high pK _a values. Here a traceless self-immolative linker composed of a dithiol-ethyl carbonate connected to a benzyl carbamate (DEC) is presented, which can modify aliphatic amines and release them rapidly and quantitatively after disulfide reduction. DEC was able to reversibly modify the lysine residues on CRISPR-Cas9 with either PEG, the cell penetrating peptide Arg₁₀, or donor DNA, and generated Cas9 conjugates with significantly improved biological properties. In particular, Cas9-DEC-PEG was able to diffuse through brain tissue significantly better than unmodified Cas9, making it a more suitable candidate for genome editing in animals. Furthermore, conjugation of Arg₁₀ to Cas9 with DEC was able to generate a self-delivering Cas9 RNP that could edit cells without transfection reagents. Finally, conjugation of donor DNA to Cas9 with DEC increased the homology directed DNA repair (HDR) rate of the Cas9 RNP by 50% in HEK 293T cell line. We anticipate that DEC will have numerous applications in biotechnology, given the ubiquitous presence of aliphatic amines on small molecule and protein therapeutics.

CRISPR-mediated genome editing of primary human lymphocytes is typically carried out via electroporation, which can be cytotoxic, cumbersome and costly. Here we show that the yields of edited primary human lymphocytes can be increased substantially by delivering a CRISPR ribonucleoprotein mixed with an amphiphilic peptide identified through screening. We evaluated the performance of this simple delivery method by knocking out genes in T cells, B cells and natural killer cells via the delivery of Cas9 or Cas12a ribonucleoproteins or an adenine base editor. We also show that peptide-mediated ribonucleoprotein delivery paired with an adeno-associated-virus-mediated homology-directed repair template can introduce a chimaeric antigen receptor gene at the T-cell receptor α constant locus, and that the engineered cells display antitumour potency in mice. The method is minimally perturbative, does not require dedicated hardware, and is compatible with multiplexed editing via sequential delivery, which minimizes the risk of genotoxicity. The peptide-mediated intracellular delivery of ribonucleoproteins may facilitate the manufacturing of engineered T cells.

CRISPR-Cas RNA-guided endonucleases hold great promise for disrupting or correcting genomic sequences through site-specific DNA cleavage and repair. However, the lack of methods for cell- and tissue-selective delivery currently limits both research and clinical uses of these enzymes. We report the design and in vitro evaluation of S. pyogenes Cas9 proteins harboring asialoglycoprotein receptor ligands (ASGPrL). In particular, we demonstrate that the resulting ribonucleoproteins (Cas9-ASGPrL RNP) can be engineered to be preferentially internalized into cells expressing the corresponding receptor on their surface. Uptake of such fluorescently labeled proteins in liver-derived cell lines HEPG2 (ASGPr+) and SKHEP (control; diminished ASGPr) was studied by live cell imaging and demonstrates increased accumulation of Cas9-ASGPrL RNP in HEPG2 cells as a result of effective ASGPr-mediated endocytosis. When uptake occurred in the presence of a peptide with endosomolytic properties, we observed receptor-facilitated and cell-type specific gene editing that did not rely on electroporation or the use of transfection reagents. Overall, these in vitro results validate the receptor-mediated delivery of genome-editing enzymes as an approach for cell-selective gene editing and provide a framework for future potential applications to hepatoselective gene editing in vivo.