Diseases

Synthetic BZLF1-targeted transcriptional activator for efficient lytic induction therapy against EBV-associated epithelial cancers

Cancer + MetastasisCheng LabCRISPR/Cas + TALENDiseasesEpigeneticsGene TherapyRepresentativeSynthetic Biology + Genome Engineering
Man Wu*, Pok Man Hau*, Linxian Li*, Chi Man Tsang, Yike Yang, Aziz Taghbalout, Grace Tin-Yun Chung, Shin Yee Hui, Wing Chung Tang, Nathaniel Jillette, Jacqueline Jufen Zhu, Horace Hok Yeung Lee, Ee Ling Kong, Melissa Sue Ann Chan, Jason Ying Kuen Chan, Brigette Buig Yue Ma, Mei-Ru Chen, Charles Lee, Ka Fai To, Albert Wu Cheng#, Kwok-Wai Lo# (co-corresponding)
Nat Commun 15, 3729
Publication year: 2024

The unique virus-cell interaction in Epstein-Barr virus (EBV)-associated malignancies implies targeting the viral latent-lytic switch is a promising therapeutic strategy. However, the lack of specific and efficient therapeutic agents to induce lytic cycle in these cancers is a major challenge facing clinical implementation. We develop a synthetic transcriptional activator that specifically activates endogenous BZLF1 and efficiently induces lytic reactivation in EBV-positive cancer cells. A lipid nanoparticle encapsulating nucleoside-modified mRNA which encodes a BZLF1-specific transcriptional activator (mTZ3-LNP) is synthesized for EBV-targeted therapy. Compared with conventional chemical inducers, mTZ3-LNP more efficiently activates EBV lytic gene expression in EBV-associated epithelial cancers. Here we show the potency and safety of treatment with mTZ3-LNP to suppress tumor growth in EBV-positive cancer models. The combination of mTZ3-LNP and ganciclovir yields highly selective cytotoxic effects of mRNA-based lytic induction therapy against EBV-positive tumor cells, indicating the potential of mRNA nanomedicine in the treatment of EBV-associated epithelial cancers.

Artificial RNA-guided splicing factors

Cheng LabCRISPR/Cas + TALENDiseasesPatentsRNA Splicing + RBPsSynthetic Biology + Genome Engineering
Albert Cheng, Nathaniel Jillette
WO2020069331
Publication year: 2020

Provided herein, in some aspects, are compositions and methods for artificially modulating alternative splicing, for example, inducing exon inclusion and/or exon exclusion events. In some embodiments, a catalytically inactive programmable nuclease, such as dCasRx, is fused to an RNA-binding protein (or fragment or isoform thereof) and, when guided to a target of interest by a specific guide RNA (gRNA), can regulate alternative splicing in eukaryotic cells.

Genetic and Chemical Correction of Cholesterol Accumulation and Impaired Autophagy in Hepatic and Neural Cells Derived from Niemann-Pick Type C Patient-Specific iPS Cells

DiseasesPhDEra
Maetzel, D., Sarkar, S., Wang, H., Abi-Mosleh, L., Xu, P., Cheng, A.W., Gao, Q., Mitalipova, M. Jaenisch, R.#
Stem Cell Reports 2(6):866-880
Publication year: 2014

Niemann-Pick type C (NPC) disease is a fatal inherited lipid storage disorder causing severe neurodegeneration and liver dysfunction with only limited treatment options for patients. Loss of NPC1 function causes defects in cholesterol metabolism and has recently been implicated in deregulation of autophagy. Here, we report the generation of isogenic pairs of NPC patient-specific induced pluripotent stem cells (iPSCs) using transcription activator-like effector nucleases (TALENs). We observed decreased cell viability, cholesterol accumulation, and dysfunctional autophagic flux in NPC1-deficient human hepatic and neural cells. Genetic correction of a disease-causing mutation rescued these defects and directly linked NPC1 protein function to impaired cholesterol metabolism and autophagy. Screening for autophagy-inducing compounds in disease-affected human cells showed cell type specificity. Carbamazepine was found to be cytoprotective and effective in restoring the autophagy defects in both NPC1-deficient hepatic and neuronal cells and therefore may be a promising treatment option with overall benefit for NPC disease.

Functional integration of dopaminergic neurons directly converted from mouse fibroblasts

DiseasesPhDEraStem Cells + Reprogramming
Kim, J., Su, S.C., Wang, H., Cheng, A.W., Cassady, J.P., Lodato, M.A., Lengner, C.J., Chung, C.Y., Dawlaty, M.M., Tsai, L.H., Jaenisch R.#
Cell Stem Cell 9(5):413-419
Publication year: 2011

Recent advances in somatic cell reprogramming have highlighted the plasticity of the somatic epigenome, particularly through demonstrations of direct lineage reprogramming of one somatic cell type to another by defined factors. However, it is not clear to what extent this type of reprogramming is able to generate fully functional differentiated cells. In addition, the activity of the reprogrammed cells in cell transplantation assays, such as those envisaged for cell-based therapy of Parkinson’s disease (PD), remains to be determined. Here we show that ectopic expression of defined transcription factors in mouse tail tip fibroblasts is sufficient to induce Pitx3+ neurons that closely resemble midbrain dopaminergic (DA) neurons. In addition, transplantation of these induced DA (iDA) neurons alleviates symptoms in a mouse model of PD. Thus, iDA neurons generated from abundant somatic fibroblasts by direct lineage reprogramming hold promise for modeling neurodegenerative disease and for cell-based therapies of PD.