Affinity purification of T7 RNA transcripts with homogeneous ends using ARiBo and CRISPR tags.

Affinity purification of RNA using the ARiBo tag technology currently provides an ideal approach to quickly prepare RNA with 3' homogeneity. Here, we explored strategies to also ensure 5' homogeneity of affinity-purified RNAs. First, we systematically investigated the effect of starting nucleotides on the 5' heterogeneity of a small SLI RNA substrate from the Neurospora VS ribozyme purified from an SLI-ARiBo precursor. A series of 32 SLI RNA sequences with variations in the +1 to +3 region was produced from two T7 promoters (class III consensus and class II 2.5) using either the wild-type T7 RNA polymerase or the P266L mutant. Although the P266L mutant helps decrease the levels of 5'-sequence heterogeneity in several cases, significant levels of 5' heterogeneity (≥1.5%) remain for transcripts starting with GGG, GAG, GCG, GGC, AGG, AGA, AAA, ACA, AUA, AAC, ACC, AUC, and AAU. To provide a more general approach to purifying RNA with 5' homogeneity, we tested the suitability of using a small CRISPR RNA stem-loop at the 5' end of the SLI-ARiBo RNA. Interestingly, we found that complete cleavage of the 5'-CRISPR tag with the Cse3 endoribonuclease can be achieved quickly from CRISPR-SLI-ARiBo transcripts. With this procedure, it is possible to generate SLI-ARiBo RNAs starting with any of the four standard nucleotides (G, C, A, or U) involved in either a single- or a double-stranded structure. Moreover, the 5'-CRISPR-based strategy can be combined with affinity purification using the 3'-ARiBo tag for quick purification of RNA with both 5' and 3' homogeneity.

Illuminating the Live-Cell Dynamics of Hepatitis B Virus Covalently Closed Circular DNA Using the CRISPR-Tag System.

The covalently closed circular DNA (cccDNA) of hepatitis B virus (HBV) is the major obstacle to curing chronic hepatitis B (CHB). Current cccDNA detection methods are mostly based on biochemical extraction and bulk measurements. They nevertheless generated a general sketch of its biological features. However, an understanding of the spatiotemporal features of cccDNA is still lacking. To achieve this, we established a system combining CRISPR-Tag and recombinant HBV minicircle technology to visualize cccDNA at single-cell level in real time. Using this system, we found that the observed recombinant cccDNA (rcccDNA) correlated quantitatively with its active transcripts when a low to medium number of foci (<20) are present, but this correlation was lost in cells harboring high copy numbers (≥20) of rcccDNA. The disruption of HBx expression seems to displace cccDNA from the dCas9-accessible region, while HBx complementation restored the number of observable cccDNA foci. This indicated regulation of cccDNA accessibility by HBx. Second, observable HBV and duck HBV (DHBV) cccDNA molecules are substantially lost during cell division, and the remaining ones were distributed randomly to daughter cells. In contrast, Kaposi's sarcoma-associated herpesvirus (KSHV)-derived episomes can be retained in a LANA (latency-associated nuclear antigen)-dependent manner. Last, the dynamics of rcccDNA episomes in nuclei displayed confined diffusion at short time scales, with directional transport over longer time scales. In conclusion, this system enables the study of physiological kinetics of cccDNA at the single-cell level. The differential accessibility of rcccDNA to dCas9 under various physiological conditions may be exploited to elucidate the complex transcriptional and epigenetic regulation of the HBV minichromosome. IMPORTANCE Understanding the formation and maintenance of HBV cccDNA has always been a central issue in the study of HBV pathobiology. However, little progress has been made due to the lack of robust assay systems and its resistance to genetic modification. Here, a live-cell imaging system by grafting CRISPR-Tag into the recombinant cccDNA was established to visualize its molecular behavior in real time. We found that the accessibility of rcccDNA to dCas9-based imaging is related to HBx-regulated mechanisms. We also confirmed the substantial loss of observable rcccDNA in one-round cell division and random distribution of the remaining molecules. Molecular dynamics analysis revealed the confined movement of the rcccDNA episome, suggesting its juxtaposition to chromatin domains. Overall, this novel system offers a unique platform to investigate the intranuclear dynamics of cccDNA within live cells.