Long noncoding RNAs (lncRNAs), defined as non-translated transcripts greater than 200 nucleotides in length, are often differentially expressed throughout developmental stages, tissue types, and disease states. The identification, visualization, and suppression/overexpression of these sequences have revealed impacts on a wide range of biological processes, including epigenetic regulation. Biochemical investigations on select systems have revealed striking insight into the biological roles of lncRNAs and lncRNA:protein complexes, which in turn prompt even more unanswered questions. To begin, multiple protein-and RNA-centric technologies have been employed to isolate lncRNA:protein and lncRNA:chromatin complexes. LncRNA interactions with the multi-subunit protein complex PRC2, which acts as a transcriptional silencer, represent some of the few cases where the binding affinity, selectivity, and activity of a lncRNA:protein complex have been investigated. At the same time, recent reports of full-length lncRNA secondary structures suggest the formation of complex structures with multiple independent folding domains and pave the way for more detailed structural investigations and predictions of lncRNA threedimensional structure. This review will provide an overview of the methods and progress made to date as well as highlight new methods that promise to further inform the molecular recognition, specificity, and function of lncRNAs. Graphical Abstract *Corresponding Author: amanda.hargrove@duke.edu. Notes The authors declare no competing financial interest. HHS Public Access Author Manuscript Author ManuscriptAuthor Manuscript Author ManuscriptThe "noncoding RNA revolution" (Cech, Stetiz) has revealed myriad functional RNA molecules with roles extending far beyond that of a messenger between DNA and protein. 1 The world of noncoding RNAs (ncRNAs), or RNAs that are not usually translated to proteins, came to light in large part as a result of the Encyclopedia of DNA Elements (ENCODE) project. 2 This consortium found that while up to 90% of the genome was transcribed only 1.2% was translated to protein. Furthermore, this large pool of untranslated transcripts demonstrated biochemical indices of function traditionally ascribed solely to proteins. 3 Research exploring the biological activity of these ncRNA transcripts promptly grew. Among the many newly discovered functions of noncoding RNAs, several classes are now known to play critical roles in the regulation of gene expression 1 as well as disease progression. 4 NcRNAs are classified based on size, with small ncRNAs less than 200 n.t. and long noncoding RNAs (lncRNAs) greater than 200 n.t. Several small ncRNA classes, including microRNAs (miRNAs) and small-interfering RNAs (siRNA), regulate gene expression by forming partially complementary duplexes with mRNAs, which in turn promote mRNA degradation or inhibit mRNA translation into peptides. [5][6][7][8] LncRNAs, on the other hand, have been found to exhibit a wide range of regulatory roles, including traffick...
8-Oxo-2'-deoxyguanosine (OdG) is a prominent DNA lesion produced from the reaction of 2'-deoxyguanosine (dG) with reactive oxygen species. While dG directs the insertion of only dCTP during replication, OdG can direct the insertion of either dCTP or dATP, allowing for the production of dG → dT transversions. When replicated by Klenow fragment-exo (KF-exo), OdG preferentially directs the incorporation of dCTP over dATP, thus decreasing its mutagenic potential. However, when replicated by a highly related polymerase, the large fragment of polymerase I from Bacillus stearothermophilus (BF), dATP incorporation is preferred, and a higher mutagenic potential results. To gain insight into the reasons for this opposite preference and the effects of the C2, N7, and C8 positions on OdG mutagenicity, single-nucleotide insertions of dCTP and/or dATP opposite dG, OdG, and seven of their analogues were examined by steady state kinetics with both KF-exo and BF. Results from these studies suggest that the two enzymes behave similarly and are both sensitive not only to steric and electronic changes within the imidazole ring during both dCTP and dATP incorporation but also to the presence of the C2-exocyclic amine during dATP incorporation. The difference in incorporation preference opposite OdG appears to be due to a somewhat increased sensitivity to structural perturbations during dCTP incorporation with BF. Single-nucleotide extensions past the resulting base pairs were also studied and were not only similar between the two enzymes but also consistent with published ternary crystallographic studies with BF. These results are analyzed in the context of previous biochemical and structural studies, as well as stability studies with the resulting base pairs.
Background aims: Next-generation immune cell therapy products will require complex modifications using engineering technologies that can maintain high levels of cell functionality. Non-viral engineering methods have the potential to address limitations associated with viral vectors. However, while electroporation is the most widely used non-viral modality, concerns about its effects on cell functionality have led to the exploration of alternative approaches. Here the authors have examined the suitability of the Solupore non-viral delivery system for engineering primary human T cells for cell therapy applications. Methods: The Solupore system was used to deliver messenger RNA (mRNA) and clustered regularly interspaced short palindromic repeats (CRISPR)/CRISPR-associated protein 9 (Cas9) guide RNA ribonucleoprotein (RNP) cargos to T cells, and efficiency was measured by flow cytometry. Cell perturbation was assessed by immune gene expression profiling, including an electroporation comparator. In vitro and in vivo cytotoxicity of chimeric antigen receptor (CAR) T cells generated using the Solupore system was evaluated using a realtime cellular impedance assay and a Raji-luciferase mouse tumor model, respectively. Results: Efficient transfection was demonstrated through delivery of mRNA and CRISPR CAS9 RNP cargos individually, simultaneously and sequentially using the Solupore system while consistently maintaining high levels of cell viability. Gene expression profiling revealed minimal alteration in immune gene expression, demonstrating the low level of perturbation experienced by the cells during this transfection process. By contrast, electroporation resulted in substantial changes in immune gene expression in T cells. CAR T cells generated using the Solupore system exhibited efficient cytotoxicity against target cancer cells in vitro and in vivo. Conclusions: The Solupore system is a non-viral means of simply, rapidly and efficiently delivering cargos to primary human immune cells with retention of high cell viability and functionality.
The bacterial repair enzyme MutT hydrolyzes the damaged nucleotide OdGTP (the 5′-triphosphate derivative of 8-oxo-2′-deoxyguanosine; OdG), which is a known mutagen and has been linked to antibacterial action. Previous work has indicated important roles for the C8-oxygen, N7-hydrogen, and C2-exocyclic amine during OdGTP recognition by MutT. In order to gain a more nuanced understanding of the contribution of these three sites to the overall activity of MutT, we determined the reaction parameters for dGTP, OdGTP, and nine of their analogues using steady state kinetics. Our results indicate that overall high reaction efficiencies can be achieved despite altering any one of these sites. However, altering two or more sites leads to a significant decrease in efficiency. The data also suggest that, similar to another bacterial OdG repair enzyme, MutM, a specific carbonyl in the enzyme can not only promote activity by forming an active site hydrogen bond with the N7-hydrogen of OdGTP, but can also hinder activity through electrostatic repulsion with the N7-lone pair of dGTP.
Advances in deep sequencing technologies have facilitated the identification and annotation of thousands of long noncoding RNAs (lncRNAs) across the transcriptome. LncRNAs are documented to play critical housekeeping roles within the cell and are implicated in a wide variety of diseases, including cancer. While studies into lncRNA function in cancer abound, there are limited examples to date of detailed lncRNA structural analyses to enable understanding of structure‐function relationships. Understanding structure‐function relationships would increase our insight into the noncoding transcriptome and yield potential avenues for targeting lncRNAs implicated in disease. The lncRNA Second Chromosome Locus Associated with Prostate 1 (SChLAP1) has been identified in multiple clinical studies as a predictive biomarker and molecular driver of aggressive prostate cancer. While several protein interactors have been identified for SChLAP1 to date, structural insight into SChLAP1:protein recognition has not yet been explored. We believe that structural analysis of SChLAP1 will assist in designing specific therapeutic strategies to inhibit SChLAP1:protein interactions implicated in prostate cancer. To this end, we performed Selective 2′‐Hydroxyl Acylation analyzed by Primer Extension with Mutational Profiling (SHAPE‐MaP) and dimethyl sulfate (DMS)‐MaP in vitroand in cellulo. This approach yielded the first secondary structure model of SChLAP1, which revealed a complex architecture with a wide variety of secondary structures throughout the length of the transcript. Analyzing our in‐cell probing data with the ΔSHAPE algorithm, we identified protein binding regions within SChLAP1 and mapped them to non‐human primate‐conserved exons within the transcript. Finally, we identified a smaller, highly structured fragment of SChLAP1 that houses multiple putative protein binding sites implicated in prostate cancer. We believe that this region of SChLAP1 is amenable to therapeutic targeting and may be used as a smaller construct for in vitrodevelopment of SChLAP1‐targeting therapeutics. We also believe this fragment may be amenable to 3D biophysical analyses, such as X‐ray crystallography or cryo‐EM, to further enhance structural understanding of SChLAP1:protein complexation. Ongoing work is focused on determining the sufficiency of this fragment for protein recognition and characterizing potential magnesium‐dependent tertiary structures. We believe this work will facilitate the development of specific therapeutic strategies for SChLAP1 and contribute to the growing need of characterizing structure‐function relationships within lncRNAs.
8-Oxo-2'-deoxyguanosine (OdG) is an abundant DNA lesion produced during oxidative damage to DNA. It can form relatively stable base pairs with both dC and dA that mimic natural dG:dC and dT:dA base pairs, respectively. Thus, when in the template strand, OdG can direct the insertion of either dCTP or dATP during replication, the latter of which can lead to a dG → T transversion. The potential for OdG to cause mutation is dependent on the preference for dCTP or dATP insertion opposite OdG, as well as the ability to extend past the resulting base pairs. The C2-amine and C8-oxygen could play major roles during these reactions since both would lie outside the Watson-Crick cognate base pairs shape in the major groove when OdG base pairs to dA and dC, respectively, and both have the ability to form strong interactions, like hydrogen bonds. To gain a more generalized understanding of how the C2-amine and C8-oxygen of OdG affect its mutagenic potential, the incorporation opposite and extension past seven analogues of dG/OdG that vary at C2 and/or C8 were characterized for three DNA polymerases, including an exonuclease-deficient version of the replicative polymerase from RB69 (RB69), human polymerase (pol) β, and polymerase IV from Sulfolobus solfataricus P2 (Dpo4). Based on the results from these studies, as well as those from previous studies with RB69, pol β, Dpo4, and two A-family polymerases, the influence of the C2-amine and C8-oxygen during each incorporation and extension reaction with each polymerase is discussed. In general, it appears that when the C2-amine and the C8-oxygen are in the minor groove, they allow OdG to retain interactions that are normally present during insertion and extension. However, when the two groups are in the major groove, they each tend to form novel active site interactions, both stabilizing and destabilizing, that are not present during insertion and extension with natural DNA.
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