Phosphorothioate (PT) modification of DNA, with sulfur replacing a nonbridging phosphate oxygen, was recently discovered as a product of the dnd genes found in bacteria and archaea. Given our limited understanding of the biological function of PT modifications, including sequence context, genomic frequencies, and relationships to the diversity of dnd gene clusters, we undertook a quantitative study of PT modifications in prokaryotic genomes using a liquid chromatography-coupled tandem quadrupole mass spectrometry approach. The results revealed a diversity of unique PT sequence contexts and three discrete genomic frequencies in a wide range of bacteria. Metagenomic analyses of PT modifications revealed unique ecological distributions, and a phylogenetic comparison of dnd genes and PT sequence contexts strongly supports the horizontal transfer of dnd genes. These results are consistent with the involvement of PT modifications in a type of restriction-modification system with wide distribution in prokaryotes.DNA modification | bioanalytical chemistry | sulfur P hosphorothioate (PT) modification of DNA, in which sulfur replaces a nonbridging phosphate oxygen, was originally developed as an artificial means to stabilize oligodeoxynucleotides against nuclease degradation (1). However, we recently discovered that the dnd gene products incorporate sulfur into the DNA backbone as a PT in a sequence-and stereo-specific manner (2). Beginning with the original observation in Streptomyces lividans 1326 that the five-gene dnd cluster (dndA-E) caused DNA degradation during electrophoresis (3), the presence of dnd genes has been established in dozens of different bacteria and archaea (4). An emerging picture of Dnd protein function reveals that DndA acts as a cysteine desulfurase and assembles DndC as a 4Fe-4S cluster protein (5). DndC possesses ATP pyrophosphatase activity and is predicted to have PAPS reductase activity, whereas DndB has homology to a group of transcriptional regulators (4, 6). A DndD homologue in Pseudomonas fluorescens Pf0-1, SpfD, has ATPase activity possibly related to DNA structure alteration or nicking during PT incorporation (7).This progress in defining the biochemistry of PT modifications belies a lack of understanding of the biological function of PT modifications, such as the variety of sequence contexts, the distribution of modifications across prokaryotic genomes, and the relationship of PT sequence contexts to the diversity of known dnd gene clusters (4). We have approached this problem with a highly quantitative study of PT modifications in prokaryotic genomes using a liquid chromatography-coupled tandem quadrupole mass spectrometry (LC-MS/MS) approach. The results reveal a diversity of quantized PT sequence contexts consistent with a role for PT modifications as part of a restrictionmodification system. Results and DiscussionDevelopment of a Sensitive Method to Quantify PT Modifications in Bacterial Genomes. We approached the problem of defining the biological function of PT modifications by q...
The chemical diversity of physiological DNA modifications has expanded with the identification of phosphorothioate (PT) modification in which the nonbridging oxygen in the sugar-phosphate backbone of DNA is replaced by sulfur. Together with DndFGH as cognate restriction enzymes, DNA PT modification, which is catalyzed by the DndABCDE proteins, functions as a bacterial restriction-modification (R-M) system that protects cells against invading foreign DNA. However, the occurrence of systems across a large number of bacterial genomes and their functions other than R-M are poorly understood. Here, a genomic survey revealed the prevalence of bacterial systems: 1,349 bacterial systems were observed to occur sporadically across diverse phylogenetic groups, and nearly half of these occur in the form of a solitary gene cluster that lacks the restriction counterparts. A phylogenetic analysis of 734 complete PT R-M pairs revealed the coevolution of M and R components, despite the observation that several PT R-M pairs appeared to be assembled from M and R parts acquired from distantly related organisms. Concurrent epigenomic analysis, transcriptome analysis, and metabolome characterization showed that a solitary PT modification contributed to the overall cellular redox state, the loss of which perturbed the cellular redox balance and induced to reconfigure its metabolism to fend off oxidative stress. An in vitro transcriptional assay revealed altered transcriptional efficiency in the presence of PT DNA modification, implicating its function in epigenetic regulation. These data suggest the versatility of PT in addition to its involvement in R-M protection.
Topographical guidance and chemotaxis are crucial factors for peripheral nerve regeneration. This study describes the preparation of highly aligned poly(ε-caprolactone) (PCL) fiber conduits coated with a concentration gradient of nerve growth factor (NGF) (A/G-PCL) using a newly designed electrospinning receiving device. The A/G-PCL conduits are confirmed in vitro to enhance and attract the neurite longitudinal growth of dorsal root ganglion (DRG) neurons toward their high-concentration gradient side. In vivo, the A/G-PCL conduits are observed to direct a longitudinal stronger attraction of axons and migration of Schwann cells in 15 mm rat sciatic nerve defects. At 12 weeks, rats transplanted with A/G-PCL conduits show satisfactory morphological and functional improvements in g-ratio, total number, and area of myelinated nerve fibers as well as the sciatic function index, compound muscle action potentials, and muscle wet weight ratio as compared to aligned PCL fibers conduits with uniform NGF (A/U-PCL). The performance of A/G-PCL is similar to that of autografts. Moreover, mRNA-seq and RT-PCR results reveal that Rap1, MAPK, and cell adhesion molecules signaling pathways are closely associated with axon chemotactic response and attraction. Altogether, by combining structural guidance with axon chemotaxis, the NGF-gradient/ aligned PCL fiber conduits represent a promising approach for peripheral nerve defect repair.
Mitochondrial cristae are critical for efficient oxidative phosphorylation, however, how cristae architecture is precisely organized remains largely unknown. Here, we discovered that Mic19, a core component of MICOS (mitochondrial contact site and cristae organizing system) complex, can be cleaved at N-terminal by mitochondrial protease OMA1 under certain physiological stresses. Mic19 directly interacts with mitochondrial outer-membrane protein Sam50 (the key subunit of SAM complex) and inner-membrane protein Mic60 (the key component of MICOS complex) to form Sam50-Mic19-Mic60 axis, which dominantly connects SAM and MICOS complexes to assemble MIB (mitochondrial intermembrane space bridging) supercomplex for mediating mitochondrial outer-and inner-membrane contact. OMA1-mediated Mic19 cleavage causes Sam50-Mic19-Mic60 axis disruption, which separates SAM and MICOS and leads to MIB disassembly. Disrupted Sam50-Mic19-Mic60 axis, even in the presence of SAM and MICOS complexes, causes the abnormal mitochondrial morphology, loss of mitochondrial cristae junctions, abnormal cristae distribution and reduced ATP production. Importantly, Sam50 displays punctate distribution at mitochondrial outer membrane, and acts as an anchoring point to guide the formation of mitochondrial cristae junctions. Therefore, we propose that Sam50-Mic19-Mic60 axis-mediated SAM-MICOS complexes integration determines mitochondrial cristae architecture.
Explosive growth in the study of microbial epigenetics has revealed a diversity of chemical structures and biological functions of DNA modifications in restriction-modification (R-M) and basic genetic processes. Here, we describe the discovery of shared consensus sequences for two seemingly unrelated DNA modification systems, 6m A methylation and phosphorothioation (PT), in which sulfur replaces a nonbridging oxygen in the DNA backbone. Mass spectrometric analysis of DNA from Escherichia coli B7A and Salmonella enterica serovar Cerro 87, strains possessing PT-based R-M genes, revealed d(G PS 6m A) dinucleotides in the G PS 6m AAC consensus representing ∼5% of the 1,100 to 1,300 PT-modified d(G PS A) motifs per genome, with 6m A arising from a yet-to-be-identified methyltransferase. To further explore PT and 6m A in another consensus sequence, G PS 6m ATC, we engineered a strain of E. coli HST04 to express Dnd genes from Hahella chejuensis KCTC2396 (PT in G PS ATC) and Dam methyltransferase from E. coli DH10B ( 6m A in G 6m ATC). Based on this model, in vitro studies revealed reduced Dam activity in G PS ATC-containing oligonucleotides whereas single-molecule real-time sequencing of HST04 DNA revealed 6m A in all 2,058 G PS ATC sites (5% of 37,698 total GATC sites). This model system also revealed temperature-sensitive restriction by DndFGH in KCTC2396 and B7A, which was exploited to discover that 6m A can substitute for PT to confer resistance to restriction by the DndFGH system. These results point to complex but unappreciated interactions between DNA modification systems and raise the possibility of coevolution of interacting systems to facilitate the function of each.T he emergence of convergent technologies has led to a growing appreciation for the diversity of DNA modifications in microbial epigenetics and restriction-modification (R-M) systems (1-3). DNA methylation, the most extensively studied genetic modification, was originally discovered in bacteria in the context of R-M systems involving a methyltransferase (MTase) that modifies "self" DNA at specific target sites and a cognate restriction endonuclease (REase) that discriminates and destroys unmodified invading DNA (3-5). R-M systems are ubiquitous in prokaryotes and are classified into four types (I, II, III, and IV) based on their molecular structure, sequence recognition, cleavage position, and cofactor requirements (3, 6, 7). However, some MTases exist alone, without an apparent cognate REase partner. These so-called "orphan" MTases include DNA adenine methylase (Dam), which modifies the adenine N-6 in the GATC motif, DNA cytosine methylase (Dcm), which methylates C-5 of the second cytosine in CC(A/T) GG sequences, and cell cycle-regulated methylase (CcrM), which methylates the N-6 of adenine in GANTC (N = A, T, C, or G) (8). Despite the absence of cognate REases, orphan MTases still confer immunity against the virulence of a parasitic R-M complex with the same target sites (9). In addition to defense against bacteriophages and transposons, DNA m...
Phosphorothioate (PT) DNA modifications—in which a nonbonding phosphate oxygen is replaced with sulfur—represent a widespread, horizontally transferred epigenetic system in prokaryotes and have a highly unusual property of occupying only a small fraction of available consensus sequences in a genome. Using Salmonella enterica as a model, we asked a question of fundamental importance: How do the PT-modifying DndA-E proteins select their GPSAAC/GPSTTC targets? Here, we applied innovative analytical, sequencing, and computational tools to discover a novel behavior for DNA-binding proteins: The Dnd proteins are “parked” at the G6mATC Dam methyltransferase consensus sequence instead of the expected GAAC/GTTC motif, with removal of the 6mA permitting extensive PT modification of GATC sites. This shift in modification sites further revealed a surprising constancy in the density of PT modifications across the genome. Computational analysis showed that GAAC, GTTC, and GATC share common features of DNA shape, which suggests that PT epigenetics are regulated in a density-dependent manner partly by DNA shape-driven target selection in the genome.
Tssk4 belongs to the Testis Specific Serine/threonine protein Kinase (TSSK) family, members of which play an important role in spermatogenesis and/or spermiogenesis. Several Tssk family proteins have extensively been studied. However, the exact function of Tssk4 remains unclear. A Tssk4 knockout mouse model was generated and the males were subfertile due to seriously decreased sperm motility. The ultrastructure of the Tssk4(-/-)sperm tail is disorganized at the midpiece-principal piece junction, leading to a severe bend in the sperm flagellum. One or more axonemal microtubule doublets are absent and the midpiece is fused with the principal piece. Furthermore, we identified the association between Tssk4 and Odf2, a prominent cytoskeletal protein of the outer dense fiber (ODF) in sperm flagellum. Tssk4 can change the phosphorylation state of Odf2 and conversely Odf2 potentiates the autophosphorylation activity of Tssk4. These findings reveal that Tssk4 is required for maintaining the structural integrity of sperm flagellum and male fertility.
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