Genes specifying long non-coding RNAs (lncRNAs) occupy a large fraction of the genomes of complex organisms. The term 'lncRNAs' encompasses RNA polymerase I (Pol I), Pol II and Pol III transcribed RNAs, and RNAs from processed introns. The various functions of lncRNAs and their many isoforms and interleaved relationships with other genes make lncRNA classification and annotation difficult. Most lncRNAs evolve more rapidly than protein-coding sequences, are cell type specific and regulate many aspects of cell differentiation and development and other physiological processes. Many lncRNAs associate with chromatin-modifying complexes, are transcribed from enhancers and nucleate phase separation of nuclear condensates and domains, indicating an intimate link between lncRNA expression and the spatial control of gene expression during development. lncRNAs also have important roles in the cytoplasm and beyond, including in the regulation of translation, metabolism and signalling. lncRNAs often have a modular structure and are rich in repeats, which are increasingly being shown to be relevant to their function. In this Consensus Statement, we address the definition and nomenclature of lncRNAs and their conservation, expression, phenotypic visibility, structure and functions. We also discuss research challenges and provide recommendations to advance the understanding of the roles of lncRNAs in development, cell biology and disease. 

/pdf/long-non-coding-rnas-definitions-functions-challenges-and-rcnyfhip.pdf

Long non-coding RNAs: definitions, functions, challenges and recommendations

http://www.cell.com/article/S0092867422007061/pdf

Circular RNAs: Characterization, cellular roles, and applications

A guide to membraneless organelles and their various roles in gene regulation

Gastric cancer (GC) was the fourth deadliest cancer in the world in 2020, and about 770,000 people died from GC that year. The death of patients with GC is mainly caused by the metastasis, recurrence, and chemotherapy resistance of GC cells. The cancer stem cell theory defines cancer stem cells (CSCs) as a key factor in the metastasis, recurrence, and chemotherapy resistance of cancer. It considers targeting gastric cancer stem cells (GCSCs) to be an effective method for the treatment of GC. For GCSCs, genes or noncoding RNAs are important regulatory factors. Many experimental studies have found that some drugs can target the stemness of gastric cancer by regulating these genes or noncoding RNAs, which may bring new directions for the clinical treatment of gastric cancer. Therefore, this review mainly discusses related genes or noncoding RNAs in GCSCs and drugs that target its stemness, thereby providing some information for the treatment of GC.

/pdf/targeting-gastric-cancer-stem-cells-to-enhance-treatment-2iqgb6pr.pdf

Targeting Gastric Cancer Stem Cells to Enhance Treatment Response

http://www.jbc.org/article/S0021925822002228/pdf

Essence determines phenomenon: Assaying the material properties of biological condensates

RNA polymerase I (Pol I) transcription takes place at the border of the fibrillar center (FC) and the dense fibrillar component (DFC) in the nucleolus. Here, we report that individual spherical FC/DFC units are coated by the DEAD-box RNA helicase DDX21 in human cells. The long noncoding RNA (lncRNA) SLERT binds to DDX21 RecA domains to promote DDX21 to adopt a closed conformation at a substoichiometric ratio through a molecular chaperone-like mechanism resulting in the formation of hypomultimerized and loose DDX21 clusters that coat DFCs, which is required for proper FC/DFC liquidity and Pol I processivity. Our results suggest that SLERT is an RNA regulator that controls the biophysical properties of FC/DFCs and thus ribosomal RNA production.

lncRNA SLERT controls phase separation of FC/DFCs to facilitate Pol I transcription.

Mesoscale DNA feature in antibody-coding sequence facilitates somatic hypermutation

DNA mismatch repair (MMR) is accomplished by highly conserved MutS and MutL homologs. MutS proteins recognize mismatch nucleotides and in the presence of ATP form a stable sliding clamp on the DNA. The MutS sliding clamp then promotes the cascade assembly of a MutL sliding clamp, which ultimately coordinates downstream mismatch excision. The MutS clamp-loader mechanics are unknown. Here we have examined a conserved positively charged cleft (PCC) located on the MutL N-terminal domain (NTD) proposed to mediate stable DNA binding events in several MMR models. We show that MutL does not bind DNA in physiological ionic conditions. Instead, the MutS sliding clamps and DNA together exploit the PCC to position the MutL NTD for clamp loading. Once in a sliding clamp form, the MutL PCC aids in UvrD helicase capture but not interactions with MutH during mismatch excision. The MutS-DNA clamp-loader progressions are significantly different from the replication clamp-loaders that attach polymerase processivity factors such as beta-clamp and PCNA to the DNA. These studies underlining the breadth of mechanisms for stably linking crucial genome maintenance proteins to the DNA.

/pdf/muts-and-dna-function-as-a-clamp-loader-for-the-mutl-sliding-40nulyc7xd.pdf

MutS and DNA Function as a Clamp Loader for the MutL Sliding Clamp During Mismatch Repair

Abstract Highly conserved MutS and MutL homologs operate as protein dimers in mismatch repair (MMR). MutS recognizes mismatched nucleotides forming ATP-bound sliding clamps, which subsequently load MutL sliding clamps that coordinate MMR excision. Several MMR models envision static MutS-MutL complexes bound to mismatched DNA via a positively charged cleft (PCC) located on the MutL N-terminal domains (NTD). We show MutL-DNA binding is undetectable in physiological conditions. Instead, MutS sliding clamps exploit the PCC to position a MutL NTD on the DNA backbone, likely enabling diffusion-mediated wrapping of the remaining MutL domains around the DNA. The resulting MutL sliding clamp enhances MutH endonuclease and UvrD helicase activities on the DNA, which also engage the PCC during strand-specific incision/excision. These MutS clamp-loader progressions are significantly different from the replication clamp-loaders that attach the polymerase processivity factors β-clamp/PCNA to DNA, highlighting the breadth of mechanisms for stably linking crucial genome maintenance proteins onto DNA. 

/pdf/muts-functions-as-a-clamp-loader-by-positioning-mutl-on-the-5pd5vqi7.pdf

MutS functions as a clamp loader by positioning MutL on the DNA during mismatch repair

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Papers

lncRNA SLERT controls phase separation of FC/DFCs to facilitate Pol I transcription.

Mesoscale DNA feature in antibody-coding sequence facilitates somatic hypermutation

MutS and DNA Function as a Clamp Loader for the MutL Sliding Clamp During Mismatch Repair

MutS functions as a clamp loader by positioning MutL on the DNA during mismatch repair