Truncated and Mutated Form of Cathepsin B

EDIT: Cathepsin B is a lysosomal protease present in the cytosol of various cancer types. We overexpressed wild-type cathepsin B in HEK293T cells to investigate cathepsin B induced cleavage of different peptide linkers via a fluorescence readout assay. We successfully showed that the linker GFLG was efficiently cleaved by cathepsin B in vivo. Furthermore, we were able to demonstrate that wild-type cathepsin B matured into its active forms when overexpressed in HEK293T cells. Together, these findings enable the functionalization of our PICasSO system for a wide range of therapeutic and synthetic biology applications.

1. Sequence overview

2. Usage and Biology

Cathepsin B is a cysteine protease typically located in lysosomes or secreted outside the cell, where it degrades proteins of the extracellular matrix (Ruan et al., 2015). To facilitate lysosomal escape of cathepsin B, cells were treated with low concentrations of doxorubicin. As an alternative strategy, we created a cytosolic single-chain version of cathepsin B. Full-length human cathepsin B has an N-terminal signal peptide facilitating targeting and translation of cathepsin B into the rough endoplasmic reticulum (Ni et al., 2022). Procathepsin B is then transported into the lysosome where it matures into its active form by cleavage into a light and heavy chain (Szulc-Dąbrowska et al., 2020).

3. Assembly and part evolution

The first modification we made to the gene encoding for human cathepsin B, was the deletion of the first twenty amino acids. This N-terminally truncated version of cathepsin B had previously been observed to have catalytic activity even in the absence of lysosomal proteases like pepsin (Müntener et al., 2005). Furthermore, we introduced three point mutations into the polypeptide chain of cathepsin B (D22A, H110A, and R116A). This has been shown to increase the activity of cathepsin B at higher pH values by disrupting the interactions of an occluding loop with the substrate binding pocket of cathepsin B (Nägler et al., 1997).

4. Results

The Peptide Linker GFLG Is Cleaved by Cathepsin B in Vivo

We performed a fluorescence readout assay in HEK293T cells to investigate cathepsin B cleavage of different peptide linkers. 24 hours after transfection, we added doxorubicin in a final concentration of 500 nM to the cell supernatant. Figure 1 shows the fluorescence intensity of mCherry for five different peptide linkers (GFLG, FFRG, FRRL, VA, FK). The negative control was not transfected with the plasmid encoding cathepsin B. We investigated two different test conditions, in which we either transfected 30 ng or 60 ng of the plasmid encoding cathepsin B. The fluorescence intensity of mCherry was normalized by the measured fluorescence intensity of eGFP in each condition. Additionally, the values for 30 ng and 60 ng cathepsin B were normalized against the corresponding negative controls. One data point for the VA linker, transfected with 60 ng of the plasmid encoding cathepsin B, was excluded due to severe deviation from the other values. We conducted a two-way analysis of variance (ANOVA) to assess the significance of the observed differences between the negative control and the test conditions for each linker. As the negative control did not contain the plasmid encoding cathepsin B, we expected the measured fluorescence intensity of mCherry to be the highest in these conditions. However, this was only observed for the GFLG and FK linkers. Contrary to our expectations, the fluorescence intensity of the negative control was the lowest out of the three conditions tested for the remaining linkers. It appears that the addition of the plasmid encoding cathepsin B increases mCherry fluorescence intensity when the linker is not cleaved. However, this increase is only significant for the FFRG linker in the 60 ng condition. For the GFLG linker, we observed significant decreases in fluorescence intensity between the negative control and both test conditions, with no difference between the 30 ng and 60 ng conditions. For the FK linker, no significant decreases in fluorescence intensity between the negative control and the test conditions were observed.

Figure 1: Fluorescence Readout After 48 hours for Five Different Peptide Linkers and Three Different Conditions. The fluorescence intensity for mCherry was measured for five different linkers and normalized against a baseline eGFP fluorescence intensity. The negative control was not transfected with the plasmid encoding cathepsin B. The fluorescence intensity of the negative control was set to one. Two different test conditions were investigated, in which either 30 ng or 60 ng of the plasmid encoding cathepsin B were transfected. The fluorescent readout was analyzed using a two-way ANOVA. Medium: DMEM (10% FCS). P values: ns, P > 0.05; *, P ≤ 0.05; **, P ≤ 0.01; ***, P ≤ 0.001; ****, P ≤ 0.0001.

mCherry and eGFP are Both Expressed in HEK293T Cells

Figure 2 shows micrographs taken with a fluorescence microscope of three different conditions: the null control, the negative control and the test sample. All samples were transfected with plasmids encoding eGFP and mCherry. The null control and the negative control were not transfected with the plasmid encoding cathepsin B. The null control was also not transfected with any of the plasmids encoding Gal4-Linker-VP64 constructs. The test sample was transfected with 30 ng of the plasmid encoding cathepsin B and with the plasmid encoding Gal4-GFLG-VP64. As expected, the null control showed no detectable mCherry signal, since no plasmid encoding a Gal4-V64 construct was transfected. Consequently, mCherry overexpression via VP64 could not be induced. However, we observed a high fluorescence intensity for eGFP, indicating that the transfection was successful. The negative control showed strong signals of both mCherry and eGFP. Therefore, it can be assumed that the transfection was successful and that our mCherry readout system is functional. Interestingly, there are some cells which either seem to only express mCherry or eGFP and some cells that show no fluorescence signal. The test sample showed less eGFP and mCherry fluorescence compared to the negative control. We expected to observe reduced fluorescence intensity of mCherry, as the transfected cells would express cathepsin B, which cleaves the linker, thereby decreasing mCherry expression.

Figure 2: Micrographs of HEK293T Cells in Two Control Conditions and One Test Condition. Micrographs were taken with a fluorescence microscope 48 hours after transfection. An overlay of brightfield, eGFP and mCherry is shown. The null control and the negative control were not transfected with the plasmid encoding cathepsin B. The Null Control was also not transfected with any of the plasmids encoding Gal4-Linker-VP64 constructs. The test sample was transfected with 30 ng of the plasmid encoding cathepsin B and with the plasmid encoding Gal4-GFLG-VP64. The micrograph of the test sample is not from the same biological replicate as the micrographs of the two controls.

Mature Cathepsin B is Expressed in HEK293T Cells

Figure 3 shows a western blot of the wild-type (wt) version of cathepsin B as well as the truncated and mutated version of cathepsin B (Δ1-20, D22A, H110A, R116A). Cells of both cathepsin B versions were treated with 500 nM doxorubicin (dox) 24 hours post-transfection and incubated for additional 24 hours. For each condition, three replicates were blotted. We observed no differences in protein expression levels between the dox-treated and untreated wt versions of cathepsin B. For the truncated and mutated version of cathepsin B, however, only the untreated samples showed the corresponding band at approximately 36 kDa expected for this version of cathepsin B. Additionally, the bands of the truncated and mutated version appeared much weaker than the ones of the wt, indicating poorer protein expression. The household protein β-tubulin is visible in all samples at approximately 55 kDa. The wt cathepsin B additionally showed bands for pro-cathepsin B at approximately 42 kDa, a mature single-chain version of cathepsin B at approximately 33 kDa and a mature double-chain version at approximately 26 kDa.

Figure 3: Western Blot of Two Versions of Cathepsin B With and Without Doxorubicin. From left to right: protein ladder, wild-type (wt) cathepsin B with (+) and without (-) doxorubicin, truncated and mutated version of cathepsin B with (+) and without (-) doxorubicin. The household protein, β-tubulin, is visible in all samples at 55 kDa. The wt cathepsin B also shows bands for pro-cathepsin B at 42 kDa, mature single-chain cathepsin B at 33 kDa and mature double-chain cathepsin B at 26 kDa. The band for the truncated and mutated version of cathepsin B can be seen in the samples without doxorubicin at 36 kDa.

Conclusion

All in all, these findings demonstrate that our fluorescence-based readout assay can reliably detect cathepsin B-mediated cleavage of peptide linkers, with the GFLG linker showing particular susceptibility to cleavage. This makes GFLG a promising candidate for targeted applications in environments with upregulated cathepsin B activity, such as in cancerous tissues. Additionally, our cathepsin B-cleavage linker can be combined with caged inteins (Gramespacher et al., 2017) conjugated to a dead Cas9 to selectively induce Cas-stapling in the presence of cathepsin B.

5. References

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Jin, C., EI-Sagheer, A. H., Li, S., Vallis, K. A., Tan, W., & Brown, T. (2022). Engineering Enzyme-Cleavable Oligonucleotides by Automated Solid-Phase Incorporation of Cathepsin B Sensitive Dipeptide Linkers. Angewandte Chemie International Edition, 61(13), e202114016. https://doi.org/10.1002/anie.202114016

Ruan, H., Hao, S., Young, P., & Zhang, H. (2015). Targeting Cathepsin B for Cancer Therapies. Horiz Cancer Res, 56, 23-40.

Shim, N., Jeon, S. I., Yang, S., Park, J. Y., Jo, M., Kim, J., Choi, J., Yun, W. S., Kim, J., Lee, Y., Shim, M. K., Kim, Y., & Kim, K. (2022). Comparative study of cathepsin B-cleavable linkers for the optimal design of cathepsin B-specific doxorubicin prodrug nanoparticles for targeted cancer therapy. Biomaterials, 289, 121806. https://doi.org/10.1016/j.biomaterials.2022.121806

Wang, J., Liu, M., Zhang, X., Wang, X., Xiong, M., & Luo, D. (2024). Stimuli-responsive linkers and their application in molecular imaging. Exploration, 4(4), 20230027. https://doi.org/10.1002/EXP.20230027

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