CRISPR-assisted transcription activation by phase-separation proteins

hpCasMINI: An engineered hypercompact CRISPR-Cas12f system with boosted gene editing activity

Compact CRISPR-Cas systems have demonstrated potential for effective packaging into adeno-associated viruses (AAVs) for use in gene therapy. However, their applications are currently limited due to modest gene-editing activity. Here we introduce an engineered compact CRISPR-Cas12f (hpCasMINI, 554 aa), with hyper editing efficiency in mammalian cells via adding an α-helix structure to the N-terminus of an Un1Cas12f1 variant CasMINI (529 aa). The hpCasMINI system boosts gene activation and DNA cleavage activity with about 1.4-3.0-fold and 1.1-19.5-fold, respectively, and maintains the high specificity when compared to CasMINI. In addition, the system can activate luciferase reporter gene and endogenous Fgf21 gene in adult mouse liver, as well as construct liver tumorigenesis model via disrupting Trp53 and Pten genes and inserting oncogenic KrasG12D into the Trp53 locus. When compared to SpCas9 and LbCas12a, hpCasMINI displays higher gene activation and exhibits higher DNA cleavage specificity, although with lower activity, at the tested sites. Moreover, with a similar strategy, we engineer compact versions of hpOsCas12f1 (458 aa) from enOsCas12f1 and hpAsCas12f1 (447 aa) from AsCas12f1-HKRA, both of which display increased DNA cleavage activity, with hpAsCas12f1 also showing improved gene activation capability. Therefore, we develop activity-increased miniature hpCasMINI, hpOsCas12f1 and hpAsCas12f1 nucleases, which hold great potential for gene therapy in the future.

Engineered circular guide RNAs enhance miniature CRISPR/Cas12f-based gene activation and adenine base editing

CRISPR system has been widely used due to its precision and versatility in gene editing. Un1Cas12f1 from uncultured archaeon (hereafter referred to as Cas12f), known for its compact size (529 aa), exhibits obvious delivery advantage for gene editing in vitro and in vivo. However, its activity remains suboptimal. In this study, we engineer circular guide RNA (cgRNA) for Cas12f and significantly improve the efficiency of gene activation about 1.9-19.2-fold. When combined with a phase separation system, the activation efficiency is further increased about 2.3-3.9-fold. In addition, cgRNA enhances the editing efficiency and narrows the editing window of adenine base editing about 1.2-2.5-fold. Importantly, this optimization strategy also boosts the Cas12f-induced gene activation efficiency in mouse liver. Therefore, we demonstrate that cgRNA is able to enhance Cas12f-based gene activation and adenine base editing, which holds great potential for gene therapy.

ASPM mediates nuclear entrapment of FOXM1 via liquid-liquid phase separation to promote progression of hepatocarcinoma

BACKGROUND

Fork-head box protein M1 (FOXM1) plays critical roles in development and progression of multiple cancers, including hepatocellular carcinoma (HCC). However, the exact regulatory hierarchy of FOXM1 remains unclear. Here, a genome-wide screen is performed to identify intranuclear proteins that promote FOXM1 transcription activity via liquid-liquid phase separation (LLPS).

RESULTS

Abnormal spindle-like microcephaly associated (ASPM) is identified to interact with FOXM1 protein via LLPS and enhance its stability by preventing proteasome-mediated degradation. ChIP-sequencing data show ASPM and FOXM1 co-occupy the promoters of multiple genes to promote their transcription, enhancing FOXM1-driven oncogenic progression. In functional experiments, inhibition of ASPM suppresses tumor growth of HCC cells in vivo and in vitro, while overexpression of ASPM has opposite effects. Importantly, reconstitution of FOXM1 partially compensates for the weakened proliferative capacity of HCC cells caused by ASPM silencing. Intriguingly, FOXM1 binds to the promoter region of ASPM and transcriptionally activates ASPM expression in HCC cells. Furthermore, we find that a higher co-expression of ASPM and FOXM1 significantly correlates with poor prognosis in HCC patients. It indicates a double positive feedback loop between ASPM and FOXM1 which coordinately promotes the aggressive progression of HCC.

CONCLUSIONS

Collectively, we demonstrate that LLPS and transcriptional regulation form an oncogenic double positive feedback loop between ASPM and FOXM1. This provides a rationale strategy to treat HCC by targeting this mechanism.

CRISPR-dCas9-Mediated PTEN Activation via Tumor Cell Membrane-Coated Nanoplatform Enhances Sensitivity to Tyrosine Kinase Inhibitors in Nonsmall Cell Lung Cancer

EGFR tyrosine kinase inhibitors (EGFR-TKIs) have garnered substantial clinical success in treating nonsmall cell lung cancer (NSCLC) harboring epidermal growth factor receptor (EGFR) mutations. However, the inevitable emergence of drug resistance, frequently attributed to activation, mutation, or deletion of multiple signaling pathways, poses a significant challenge. Notably, the loss of PTEN protein expression has emerged as a pivotal mechanism fostering resistance in EGFR mutant lung cancers. Consequently, strategies aimed at upregulating PTEN expression hold great promise for restoring drug sensitivity. Leveraging the versatility, precision, and efficacy of nuclease-deactivated Cas9 (dCas9) as a transcriptional activator, we designed a CRISPR-dCas9 system to stimulate PTEN expression. To further enhance target specificity and drug delivery efficiency, we innovatively harnessed the tumor cell membrane (CCM) as a homologous targeting surface coating for our vector, thereby creating a targeted activation nanoplatform. Comprehensive in vitro and in vivo evaluations demonstrated that the synergistic interplay between gefitinib and the CRISPR-dCas9 system significantly enhanced drug sensitivity. The finding underscores the potential of our approach in addressing the issue of lung cancer resistance, offering a promising avenue for personalized and effective cancer therapies.

Dynamic properties of transcriptional condensates modulate CRISPRa-mediated gene activation

CRISPR activation (CRISPRa) is a powerful tool for endogenous gene activation, yet the mechanisms underlying its optimal transcriptional activation remain unclear. By monitoring real-time transcriptional bursts, we find that CRISPRa modulates both burst duration and amplitude. Our quantitative imaging reveals that CRISPR-SunTag activators, with three tandem VP64-p65-Rta (VPR), form liquid-like transcriptional condensates and exhibit high activation potency. Although visible CRISPRa condensates are associated with some RNA bursts, the overall levels of phase separation do not correlate with transcriptional bursting or activation strength in individual cells. When the number of SunTag scaffolds is increased to 10 or more, solid-like condensates form, sequestering co-activators such as p300 and MED1. These condensates display low dynamicity and liquidity, resulting in ineffective gene activation. Overall, our studies characterize various phase-separated CRISPRa systems for gene activation, highlighting the foundational principles for engineering CRISPR-based programmable synthetic condensates with appropriate properties to effectively modulate gene expression.

Biomolecular condensation of human IDRs initiates endogenous transcription via intrachromosomal looping or high-density promoter localization

Protein intrinsically disordered regions (IDRs) are critical gene-regulatory components and aberrant fusions between IDRs and DNA-binding/chromatin-associating domains cause diverse human cancers. Despite this importance, how IDRs influence gene expression, and how aberrant IDR fusion proteins provoke oncogenesis, remains incompletely understood. Here we develop a series of synthetic dCas9-IDR fusions to establish that locus-specific recruitment of IDRs can be sufficient to stimulate endogenous gene expression. Using dCas9 fused to the paradigmatic leukemogenic NUP98 IDR, we also demonstrate that IDRs can activate transcription via localized biomolecular condensation and in a manner that is dependent upon overall IDR concentration, local binding density, and amino acid composition. To better clarify the oncogenic role of IDRs, we construct clinically observed NUP98 IDR fusions and show that, while generally non-overlapping, oncogenic NUP98-IDR fusions convergently drive a core leukemogenic gene expression program in donor-derived human hematopoietic stem cells. Interestingly, we find that this leukemic program arises through differing mechanistic routes based upon IDR fusion partner; either distributed intragenic binding and intrachromosomal looping, or dense binding at promoters. Altogether, our studies clarify the gene-regulatory roles of IDRs and, for the NUP98 IDR, connect this capacity to pathological cellular programs, creating potential opportunities for generalized and mechanistically tailored therapies.

Viral N protein hijacks deaminase-containing RNA granules to enhance SARS-CoV-2 mutagenesis

Host cell-encoded deaminases act as antiviral restriction factors to impair viral replication and production through introducing mutations in the viral genome. We sought to understand whether deaminases are involved in SARS-CoV-2 mutation and replication, and how the viral factors interact with deaminases to trigger these processes. Here, we show that APOBEC and ADAR deaminases act as the driving forces for SARS-CoV-2 mutagenesis, thereby blocking viral infection and production. Mechanistically, SARS-CoV-2 nucleocapsid (N) protein, which is responsible for packaging viral genomic RNA, interacts with host deaminases and co-localizes with them at stress granules to facilitate viral RNA mutagenesis. N proteins from several coronaviruses interact with host deaminases at RNA granules in a manner dependent on its F17 residue, suggesting a conserved role in modulation of viral mutagenesis in other coronaviruses. Furthermore, mutant N protein bearing a F17A substitution cannot localize to deaminase-containing RNA granules and leads to reduced mutagenesis of viral RNA, providing support for its function in enhancing deaminase-dependent viral RNA editing. Our study thus provides further insight into virus-host cell interactions mediating SARS-CoV-2 evolution.

Systematic Evaluation and Application of IDR Domain-Mediated Transcriptional Activation of NUP98 in Saccharomyces cerevisiae

Implementing dynamic control over gene transcription to decouple cell growth is essential for regulating protein expression in microbial cells. However, the availability of efficient regulatory elements in Saccharomyces cerevisiae remains limited. In this study, we present a novel β-estradiol-inducible gene expression system, termed DEN. This system combines a DNA-binding domain with an estradiol-binding domain and an intrinsically disordered region (IDR) from NUP98. Comparative analysis shows that the DEN system outperforms IDRs from other proteins, achieving an approximately 60-fold increase in EGFP expression upon β-estradiol induction. Moreover, our system is tightly controlled; nontoxic gene expression makes it a powerful tool for rapid and precise modulation of target gene expression. This system holds great potential for unlocking new functionalities from existing proteins in future research.

Mini and enhanced CRISPR activators for cancer therapies

INTRODUCTION

The RNA-guided nuclease Cas9 can be used as a programmable transcription activator, but there is still room for improvement in its effectiveness in eukaryotes, and its potential in cancer genetic therapy has been poorly investigated.

OBJECTIVES

We aim to construct optimized CRISPRa tools and detect their potential role in cancer therapy by screening 9aa-TAD.

METHODS

We selected a range of transcriptional coactivators for programmable activation and analyzed their effects on the expression of multiple endogenous genes using Flow cytometry and qRT-PCR. In order to improve the activation capacity of the CRISPRa tool, we fused the coactivators with the efficient dCas9-VPR system to construct a new activation system. Utilize RNA-seq to assess the activation specificity of genome-wide. To evaluate the value of the newly constructed activation system in cancer gene therapy, we activated the expression of the tumor suppressor genes PER2 and ZNF382, and performed changes in cancer cell proliferation qRT-PCR and clonal formation analysis.

RESULTS

In this study, we screened the NHR module from C. elegans, which demonstrated a high transcription activation capacity with a compact size compared to VP64. We successfully demonstrated its efficiency in activating endogenous genes in mammalian cells. Furthermore, we developed an enhanced fused variant called NHR-VP64-p65-Rta (NVPR), which showed even higher efficiency compared to the previously established VPR module, making it an effective CRISPRa tool. The dCas9-NVPR complex also exhibited high specificity on a genome-wide scale. Finally, we utilized the dCas9-NVPR tool to restore the expression of tumor suppressor genes PER2 and ZNF382, effectively inhibiting the malignant phenotype of cancer cells.

CONCLUSION

We have successfully developed and demonstrated a breakthrough CRISPRa tool with promising implications for cancer genetic therapy. This innovation expands the range of available gene editing tools and further validates the immense potential of CRISPR-based approaches in precision medicine.

Activating UCHL1 through the CRISPR activation system promotes cartilage differentiation mediated by HIF-1α/SOX9

Developing strategies to enhance cartilage differentiation in mesenchymal stem cells and preserve the extracellular matrix is crucial for successful cartilage tissue reconstruction. Hypoxia-inducible factor-1α (HIF-1α) plays a pivotal role in maintaining the extracellular matrix and chondrocyte phenotype, thus serving as a key regulator in chondral tissue engineering strategies. Recent studies have shown that Ubiquitin C-terminal hydrolase L1 (UCHL1) is involved in the deubiquitylation of HIF-1α. However, the regulatory role of UCHL1 in chondrogenic differentiation has not been investigated. In the present study, we initially validated the promotive effect of UCHL1 expression on chondrogenesis in adipose-derived stem cells (ADSCs). Subsequently, a hybrid baculovirus system was designed and employed to utilize three CRISPR activation (CRISPRa) systems, employing dead Cas9 (dCas9) from three distinct bacterial sources to target UCHL1. Then UCHL1 and HIF-1α inhibitor and siRNA targeting SRY-box transcription factor 9 (SOX9) were used to block UCHL1, HIF-1α and SOX9, respectively. Cartilage differentiation and chondrogenesis were measured by qRT-PCR, immunofluorescence and histological staining. We observed that the CRISPRa system derived from Staphylococcus aureus exhibited superior efficiency in activating UCHL1 compared to the commonly used the CRISPRa system derived from Streptococcus pyogenes. Furthermore, the duration of activation was extended by utilizing the Cre/loxP-based hybrid baculovirus. Moreover, our findings show that UCHL1 enhances SOX9 expression by regulating the stability and localization of HIF-1α, which promotes cartilage production in ADSCs. These findings suggest that activating UCHL1 using the CRISPRa system holds significant potential for applications in cartilage regeneration.

Biomolecular condensates and disease pathogenesis

Biomolecular condensates or membraneless organelles (MLOs) formed by liquid-liquid phase separation (LLPS) divide intracellular spaces into discrete compartments for specific functions. Dysregulation of LLPS or aberrant phase transition that disturbs the formation or material states of MLOs is closely correlated with neurodegeneration, tumorigenesis, and many other pathological processes. Herein, we summarize the recent progress in development of methods to monitor phase separation and we discuss the biogenesis and function of MLOs formed through phase separation. We then present emerging proof-of-concept examples regarding the disruption of phase separation homeostasis in a diverse array of clinical conditions including neurodegenerative disorders, hearing loss, cancers, and immunological diseases. Finally, we describe the emerging discovery of chemical modulators of phase separation.

Specific multivalent molecules boost CRISPR-mediated transcriptional activation

CRISPR/Cas-based transcriptional activators can be enhanced by intrinsically disordered regions (IDRs). However, the underlying mechanisms are still debatable. Here, we examine 12 well-known IDRs by fusing them to the dCas9-VP64 activator, of which only seven can augment activation, albeit independently of their phase separation capabilities. Moreover, modular domains (MDs), another class of multivalent molecules, though ineffective in enhancing dCas9-VP64 activity on their own, show substantial enhancement in transcriptional activation when combined with dCas9-VP64-IDR. By varying the number of gRNA binding sites and fusing dCas9-VP64 with different IDRs/MDs, we uncover that optimal, rather than maximal, cis-trans cooperativity enables the most robust activation. Finally, targeting promoter-enhancer pairs yields synergistic effects, which can be further amplified via enhancing chromatin interactions. Overall, our study develops a versatile platform for efficient gene activation and sheds important insights into CRIPSR-based transcriptional activators enhanced with multivalent molecules.

Targeted gene regulation through epigenome editing in plants

The precise targeted gene regulation in plants is essential for improving plant traits and gaining a comprehensive understanding of gene functions. The regulation of gene expression in eukaryotes can be achieved through transcriptional and epigenetic mechanisms. Over the last decade, advancements in gene-targeting technologies, along with an expanded understanding of epigenetic gene regulation mechanisms, have significantly contributed to the development of programmable gene regulation tools. In this review, we will discuss the recent progress in targeted plant gene regulation through epigenome editing, emphasizing the role of effector proteins in modulating target gene expression via diverse mechanisms, including DNA methylation, histone modifications, and chromatin remodeling. Additionally, we will also briefly review targeted gene regulation by transcriptional regulation and mRNA modifications in plants.

Highly efficient and specific regulation of gene expression using enhanced CRISPR-Cas12f system

The recently developed CRISPR activator (CRISPRa) system uses a CRISPR-Cas effector-based transcriptional activator to effectively control the expression of target genes without causing DNA damage. However, existing CRISPRa systems based on Cas9/Cas12a necessitate improvement in terms of efficacy and accuracy due to limitations associated with the CRISPR-Cas module itself. To overcome these limitations and effectively and accurately regulate gene expression, we developed an efficient CRISPRa system based on the small CRISPR-Cas effector Candidatus Woesearchaeota Cas12f (CWCas12f). By engineering the CRISPR-Cas module, linking activation domains, and using various combinations of linkers and nuclear localization signal sequences, the optimized eCWCas12f-VPR system enabled effective and target-specific regulation of gene expression compared with that using the existing CRISPRa system. The eCWCas12f-VPR system developed in this study has substantial potential for controlling the transcription of endogenous genes in living organisms and serves as a foundation for future gene therapy and biological research.

Expanding RNA editing toolkit using an IDR-based strategy

RNA base editors should ideally be free of immunogenicity, compact, efficient, and specific, which has not been achieved for C > U editing. Here we first describe a compact C > U editor entirely of human origin, created by fusing the human C > U editing enzyme RESCUE-S to Cas inspired RNA targeting system (CIRTS), a tiny, human-originated programmable RNA-binding domain. This editor, CIRTS-RESCUEv1 (V1), was inefficient. Remarkably, a short histidine-rich domain (HRD), which is derived from the internal disordered region (IDR) in the human CYCT1, a protein capable of liquid-liquid phase separation (LLPS), enhanced V1 editing at on-targets as well as off-targets, the latter effect being minor. The V1-HRD fusion protein formed puncta characteristic of LLPS, and various other IDRs (but not an LLPS-impaired mutant) could replace HRD to effectively induce puncta and potentiate V1, suggesting that the diverse domains acted via a common, LLPS-based mechanism. Importantly, the HRD fusion strategy was applicable to various other types of C > U RNA editors. Our study expands the RNA editing toolbox and showcases a general method for stimulating C > U RNA base editors.

Technologies for studying phase-separated biomolecular condensates

Biomolecular condensates, also referred to as membrane-less organelles, function as fundamental organizational units within cells. These structures primarily form through liquid-liquid phase separation, a process in which proteins and nucleic acids segregate from the surrounding milieu to assemble into micron-scale structures. By concentrating functionally related proteins and nucleic acids, these biomolecular condensates regulate a myriad of essential cellular processes. To study these significant and intricate organelles, a range of technologies have been either adapted or developed. In this review, we provide an overview of the most utilized technologies in this rapidly evolving field. These include methods used to identify new condensates, explore their components, investigate their properties and spatiotemporal regulation, and understand the organizational principles governing these condensates. We also discuss potential challenges and review current advancements in applying the principles of biomolecular condensates to the development of new technologies, such as those in synthetic biology.

Current therapies for osteoarthritis and prospects of CRISPR-based genome, epigenome, and RNA editing in osteoarthritis treatment

Osteoarthritis (OA) is one of the most common degenerative joint diseases worldwide, causing pain, disability, and decreased quality of life. The balance between regeneration and inflammation-induced degradation results in multiple etiologies and complex pathogenesis of OA. Currently, there is a lack of effective therapeutic strategies for OA treatment. With the development of CRISPR-based genome, epigenome, and RNA editing tools, OA treatment has been improved by targeting genetic risk factors, activating chondrogenic elements, and modulating inflammatory regulators. Supported by cell therapy and in vivo delivery vectors, genome, epigenome, and RNA editing tools may provide a promising approach for personalized OA therapy. This review summarizes CRISPR-based genome, epigenome, and RNA editing tools that can be applied to the treatment of OA and provides insights into the development of CRISPR-based therapeutics for OA treatment. Moreover, in-depth evaluations of the efficacy and safety of these tools in human OA treatment are needed.

Liquid-Liquid Phase Separation Sheds New Light upon Cardiovascular Diseases

Liquid-liquid phase separation (LLPS) is a biophysical process that mediates the precise and complex spatiotemporal coordination of cellular processes. Proteins and nucleic acids are compartmentalized into micron-scale membrane-less droplets via LLPS. These droplets, termed biomolecular condensates, are highly dynamic, have concentrated components, and perform specific functions. Biomolecular condensates have been observed to organize diverse key biological processes, including gene transcription, signal transduction, DNA damage repair, chromatin organization, and autophagy. The dysregulation of these biological activities owing to aberrant LLPS is important in cardiovascular diseases. This review provides a detailed overview of the regulation and functions of biomolecular condensates, provides a comprehensive depiction of LLPS in several common cardiovascular diseases, and discusses the revolutionary therapeutic perspective of modulating LLPS in cardiovascular diseases and new treatment strategies relevant to LLPS.