Retroviruses are among the most extensively studied viral families, both historically and in contemporary research. They are primarily investigated in the fields of viral oncogenesis, reverse transcription mechanisms, and other infection-specific aspects. These include the integration of endogenous retroviruses (ERVs) into host genomes, a process widely utilized in genetic engineering, and the ongoing search for HIV/AIDS treatment. G-quadruplexes (G4) have emerged as potential therapeutic targets in antiviral therapy and have been identified in important regulatory regions of viral genomes. In this study, we examine the presence of potential G-quadruplex-forming sequences (PQS) across all currently available unique retroviral genomes. Given that these retroviral genomes typically consist of single-stranded RNA (ssRNA) molecules, we also investigated whether the localization of PQSs is strand-dependent. This is particularly relevant since antisense transcripts have been detected in HIV, and ERV integration into the host genome involves reverse transcription from genomic positive strand ssRNA to double-stranded DNA (dsDNA), implicating both strands in this process. We show that in most mammalian retroviruses, including human retroviruses, PQSs are significantly more prevalent on the negative (antisense) strand, with some notable exceptions such as HIV-1. In sharp contrast, avian retroviruses exhibit a higher prevalence of PQSs on the positive (sense) strand.

• Keywords
• Bioinformatics, G-quadruplex, G4Hunter, Persistent infection, Retroviral genome,
• MeSH
• Endogenous Retroviruses genetics   MeSH
• G-Quadruplexes * MeSH
• Genome, Viral * MeSH
• Humans MeSH
• Retroviridae * genetics   MeSH
• Animals MeSH
• Check Tag
• Humans MeSH
• Animals MeSH
• Publication type
• Journal Article MeSH
• Research Support, Non-U.S. Gov't MeSH

Current methods of processing archaeological samples combined with advances in sequencing methods lead to disclosure of a large part of H. neanderthalensis and Denisovans genetic information. It is hardly surprising that the genome variability between modern humans, Denisovans and H. neanderthalensis is relatively limited. Genomic studies may provide insight on the metabolism of extinct human species or lineages. Detailed analysis of G-quadruplex sequences in H. neanderthalensis and Denisovans mitochondrial DNA showed us interesting features. Relatively similar patterns in mitochondrial DNA are found compared to modern humans, with one notable exception for H. neanderthalensis. An interesting difference between H. neanderthalensis and H. sapiens corresponds to a motif found in the D-loop region of mtDNA, which is responsible for mitochondrial DNA replication. This area is directly responsible for the number of mitochondria and consequently for the efficient energy metabolism of cell. H. neanderthalensis harbor a long uninterrupted run of guanines in this region, which may cause problems for replication, in contrast with H. sapiens, for which this run is generally shorter and interrupted. One may propose that the predominant H. sapiens motif provided a selective advantage for modern humans regarding mtDNA replication and function.

• Publication type
• Journal Article MeSH

Non-canonical secondary structures in DNA are increasingly being revealed as critical players in DNA metabolism, including modulating the accessibility and activity of promoters. These structures comprise the so-called G-quadruplexes (G4s) that are formed from sequences rich in guanine bases. Using a well-defined transcriptional reporter system, we sought to systematically investigate the impact of the presence of G4 structures on transcription in yeast Saccharomyces cerevisiae. To this aim, different G4 prone sequences were modeled to vary the chance of intramolecular G4 formation, analyzed in vitro by Thioflavin T binding test and circular dichroism and then placed at the yeast ADE2 locus on chromosome XV, downstream and adjacent to a P53 response element (RE) and upstream from a minimal CYC1 promoter and Luciferase 1 (LUC1) reporter gene in isogenic strains. While the minimal CYC1 promoter provides basal reporter activity, the P53 RE enables LUC1 transactivation under the control of P53 family proteins expressed under the inducible GAL1 promoter. Thus, the impact of the different G4 prone sequences on both basal and P53 family protein-dependent expression was measured after shifting cells onto galactose containing medium. The results showed that the presence of G4 prone sequences upstream of a yeast minimal promoter increased its basal activity proportionally to their potential to form intramolecular G4 structures; consequently, this feature, when present near the target binding site of P53 family transcription factors, can be exploited to regulate the transcriptional activity of P53, P63 and P73 proteins.

• Keywords
• G-quadruplex, p53, transcriptional activity, yeast,
• MeSH
• DNA metabolism   MeSH
• G-Quadruplexes * MeSH
• Tumor Suppressor Protein p53 genetics   MeSH
• Promoter Regions, Genetic MeSH
• Saccharomyces cerevisiae * genetics   metabolism   MeSH
• Publication type
• Journal Article MeSH
• Research Support, Non-U.S. Gov't MeSH
• Names of Substances
• DNA MeSH
• Tumor Suppressor Protein p53 MeSH

Guanine-quadruplex structures (G4) are unusual nucleic acid conformations formed by guanine-rich DNA and RNA sequences and known to control gene expression mechanisms, from transcription to protein synthesis. So far, a number of molecules that recognize G4 have been developed for potential therapeutic applications in human pathologies, including cancer and infectious diseases. These molecules are called G4 ligands. When the biological effects of G4 ligands are studied, the analysis is often limited to nucleic acid targets. However, recent evidence indicates that G4 ligands may target other cellular components and compartments such as lysosomes and mitochondria. Here, we summarize our current knowledge of the regulation of lysosome by G4 ligands, underlying their potential functional impact on lysosome biology and autophagic flux, as well as on the transcriptional regulation of lysosomal genes. We outline the consequences of these effects on cell fate decisions and we systematically analyzed G4-prone sequences within the promoter of 435 lysosome-related genes. Finally, we propose some hypotheses about the mechanisms involved in the regulation of lysosomes by G4 ligands.

• Keywords
• Autophagy, TFEB, guanine-quadruplex, lysosome membrane permeabilization, transcriptional regulation,
• MeSH
• Autophagy * MeSH
• DNA metabolism   MeSH
• G-Quadruplexes * MeSH
• Guanine MeSH
• Humans MeSH
• Ligands MeSH
• Check Tag
• Humans MeSH
• Publication type
• Journal Article MeSH
• Research Support, Non-U.S. Gov't MeSH
• Names of Substances
• DNA MeSH
• Guanine MeSH
• Ligands MeSH

Although the impact of telomeres on physiology stands well established, a question remains: how do telomeres impact cellular functions at a molecular level? This is because current understanding limits the influence of telomeres to adjacent subtelomeric regions despite the wide-ranging impact of telomeres. Emerging work in two distinct aspects offers opportunities to bridge this gap. First, telomere-binding factors were found with non-telomeric functions. Second, locally induced DNA secondary structures called G-quadruplexes are notably abundant in telomeres, and gene regulatory regions genome wide. Many telomeric factors bind to G-quadruplexes for non-telomeric functions. Here we discuss a more general model of how telomeres impact the non-telomeric genome - through factors that associate at telomeres and genome wide - and influence cell-intrinsic functions, particularly aging, cancer, and pluripotency.

• Keywords
• G-quadruplex, TRF2, aging, cancer, gene-regulation, non-telomeric function, pluripotency, telomere signaling, telomeric factors,
• MeSH
• DNA metabolism   MeSH
• G-Quadruplexes * MeSH
• Heterochromatin MeSH
• Telomere * genetics   metabolism   MeSH
• Publication type
• Journal Article MeSH
• Research Support, Non-U.S. Gov't MeSH
• Review MeSH
• Names of Substances
• DNA MeSH
• Heterochromatin MeSH

Cruciforms occur when inverted repeat sequences in double-stranded DNA adopt intra-strand hairpins on opposing strands. Biophysical and molecular studies of these structures confirm their characterization as four-way junctions and have demonstrated that several factors influence their stability, including overall chromatin structure and DNA supercoiling. Here, we review our understanding of processes that influence the formation and stability of cruciforms in genomes, covering the range of sequences shown to have biological significance. It is challenging to accurately sequence repetitive DNA sequences, but recent advances in sequencing methods have deepened understanding about the amounts of inverted repeats in genomes from all forms of life. We highlight that, in the majority of genomes, inverted repeats are present in higher numbers than is expected from a random occurrence. It is, therefore, becoming clear that inverted repeats play important roles in regulating many aspects of DNA metabolism, including replication, gene expression, and recombination. Cruciforms are targets for many architectural and regulatory proteins, including topoisomerases, p53, Rif1, and others. Notably, some of these proteins can induce the formation of cruciform structures when they bind to DNA. Inverted repeat sequences also influence the evolution of genomes, and growing evidence highlights their significance in several human diseases, suggesting that the inverted repeat sequences and/or DNA cruciforms could be useful therapeutic targets in some cases.

• Keywords
• DNA base sequence, DNA structure, DNA supercoiling, cruciform, epigenetics, genome stability, inverted repeat, replication, transcription,
• MeSH
• DNA genetics   MeSH
• Nucleic Acid Conformation MeSH
• DNA, Cruciform MeSH
• Humans MeSH
• Nucleic Acids * MeSH
• Inverted Repeat Sequences MeSH
• Repetitive Sequences, Nucleic Acid genetics   MeSH
• Check Tag
• Humans MeSH
• Publication type
• Journal Article MeSH
• Review MeSH
• Names of Substances
• DNA MeSH
• DNA, Cruciform MeSH
• Nucleic Acids * MeSH