Cloning and characterization of the Schizosaccharomyces pombe homologs of the human protein Translin and the Translin-associated protein TRAX

Translin facilitates RNA polymerase II dissociation and suppresses genome instability during RNase H2- and Dicer-deficiency

The conserved nucleic acid binding protein Translin contributes to numerous facets of mammalian biology and genetic diseases. It was first identified as a binder of cancer-associated chromosomal translocation breakpoint junctions leading to the suggestion that it was involved in genetic recombination. With a paralogous partner protein, Trax, Translin has subsequently been found to form a hetero-octomeric RNase complex that drives some of its functions, including passenger strand removal in RNA interference (RNAi). The Translin-Trax complex also degrades the precursors to tumour suppressing microRNAs in cancers deficient for the RNase III Dicer. This oncogenic activity has resulted in the Translin-Trax complex being explored as a therapeutic target. Additionally, Translin and Trax have been implicated in a wider range of biological functions ranging from sleep regulation to telomere transcript control. Here we reveal a Trax- and RNAi-independent function for Translin in dissociating RNA polymerase II from its genomic template, with loss of Translin function resulting in increased transcription-associated recombination and elevated genome instability. This provides genetic insight into the longstanding question of how Translin might influence chromosomal rearrangements in human genetic diseases and provides important functional understanding of an oncological therapeutic target.

Human genetic diseases, including cancers, are frequently driven by substantial changes to chromosomes, including translocations, where one arm of a chromosome is exchanged for another. The human nucleic acid binding protein Translin was first identified by its ability to bind to the chromosomal sites at which some of these translocations occur. This resulted in Translin being implicated in the mechanism that generated the translocation and thus the associated disease state. However, since its discovery there has been little evidence to directly indicate Translin does contribute to this process. It is, however, known to contribute to a number of biological functions including, amongst others, neurological regulation, sleep control, vascular stiffening, cancer immunomodulation and it has been recently identified as a potential therapeutic target in some cancers. Here we demonstrate that Translin has conserved function in genome stability maintenance when other primary pathways are defective, a function independent of a key binding partner protein, Trax. Specifically, we demonstrate that Translin contributes to minimizing the deleterious genome destabilizing effects of retaining gene expression machineries on chromosomes. This offers the first evidence for how Translin might contribute to genetic disease-causing chromosomal changes and offers insight to inform therapeutic design.

Translin: A multifunctional protein involved in nucleic acid metabolism

Translin, a highly conserved, DNA/RNA binding protein, is abundantly expressed in brain, testis and in certain malignancies. It was discovered initially in the quest to find proteins that bind to alternating polypurines-polypyrimidines repeats. It has been implicated to have a role in RNA metabolism (tRNA processing, RNAi, RNA transport, etc.), transcription, DNA damage response, etc. Studies from human, mice, drosophila and yeast have revealed that it forms an octameric ring, which is important for its function. Translin is a cytoplasmic protein, but under genotoxic stress, it migrates into the nucleus, binds to the break point hot spots and therefore, thought to be involved in chromosomal translocation events as well as DNA damage related response. Its structure is known and DNA binding regions, GTP binding region and regions responsible for homotypic and heterotypic interaction are known. It forms a ball like structure with open central channel for accommodating the substrate nucleic acids. Besides this, translin protein binds to 3' and 5' UTR of certain mRNAs and probably regulates their availability for translation. It is also involved in mRNA transport and cell cycle progression. It forms a heteromeric complex with translin associated factor-X (TRAX) to form C3PO complex which is involved in RNA silencing process. Recently, it has been shown that translin is upregulated under starvation conditions in Drosophila and is involved in the integration of sleep and metabolic rate of the flies. Earlier studies classified translin as a DNA repair protein; however subsequent studies showed that it is a multifunctional protein. With this background, in this review we have summarized the translin biochemical activities, cellular function as well as structural properties of this important protein.

Role of amino acid residues important for nucleic acid binding in human Translin

Translin is a multifunctional DNA/RNA binding protein involved in DNA repair and RNA metabolism. It has two basic regions and involvement of some residues in these regions in nucleic acid binding is established experimentally. Here we report the functional role of four residues of basic region II, Y85, R86, H88, R92 and one residue of C terminal region, K193 in nucleic acid binding using substitution mutant variants. CD analysis of the mutant proteins showed that secondary structure was maintained in all the mutant proteins in comparison to wild type protein. Octameric state was maintained in all the mutants of basic region as evidenced by TEM, DLS, native PAGE and gel filtration analyses. However, K193G mutation completely abolished the octameric state of Translin protein and consequently its ability to bind ssDNA/ssRNA. The mutants of the basic region II exhibited a differential effect on nucleic acid binding, with R86A and R92G as most deleterious. Interestingly, H88A mutant showed higher nucleic acid binding affinity in comparison to the wild type Translin. An in silico analysis of the mutant variant sequences predicted all the mutations to be destabilizing, causing increase in flexibility and also leading to disruption of local interactions. The differential effect of mutations on DNA/RNA binding where octameric state is maintained could be attributed to these predicted disturbances.

GSK3β negatively regulates TRAX, a scaffold protein implicated in mental disorders, for NHEJ-mediated DNA repair in neurons

Translin-associated protein X (TRAX) is a scaffold protein with various functions and has been associated with mental illnesses, including schizophrenia. We have previously demonstrated that TRAX interacts with a Gsα protein-coupled receptor, the A_2A adenosine receptor (A_2AR), and mediates the function of this receptor in neuritogenesis. In addition, stimulation of the A_2AR markedly ameliorates DNA damage evoked by elevated oxidative stress in neurons derived from induced pluripotent stem cells (iPSCs). Here, we report that glycogen synthase kinase 3 beta (GSK3β) and disrupted-in-schizophrenia 1 (DISC1) are two novel interacting proteins of TRAX. We present evidence to suggest that the stimulation of A_2AR markedly facilitated DNA repair through the TRAX/DISC1/GSK3β complex in a rat neuronal cell line (PC12), primary mouse neurons, and human medium spiny neurons derived from iPSCs. A_2AR stimulation led to the inhibition of GSK3β, thus dissociating the TRAX/DISC1/GSK3β complex and facilitating the non-homologous end-joining pathway (NHEJ) by enhancing the activation of a DNA-dependent protein kinase via phosphorylation at Thr²⁶⁰⁹. Similarly, pharmacological inhibition of GSK3β by SB216763 also facilitated the TRAX-mediated repair of oxidative DNA damage. Collectively, GSK3β binds with TRAX and negatively affects its ability to facilitate NHEJ repair. The suppression of GSK3β by A_2AR activation or a GSK3β inhibitor releases TRAX for the repair of oxidative DNA damage. Our findings shed new light on the molecular mechanisms underlying diseases associated with DNA damage and provides a novel target (i.e., the TRAX/DISC1/GSK3β complex) for future therapeutic development for mental disorders.

Translin and Trax differentially regulate telomere-associated transcript homeostasis

Translin and Trax proteins are highly conserved nucleic acid binding proteins that have been implicated in RNA regulation in a range of biological processes including tRNA processing, RNA interference, microRNA degradation during oncogenesis, spermatogenesis and neuronal regulation. Here, we explore the function of this paralogue pair of proteins in the fission yeast. Using transcript analysis we demonstrate a reciprocal mechanism for control of telomere-associated transcripts. Mutation of tfx1⁺ (Trax) elevates transcript levels from silenced sub-telomeric regions of the genome, but not other silenced regions, such as the peri-centromeric heterochromatin. In the case of some sub-telomeric transcripts, but not all, this elevation is dependent on the Trax paralogue, Tsn1 (Translin). In a reciprocal fashion, Tsn1 (Translin) serves to repress levels of transcripts (TERRAs) from the telomeric repeats, whereas Tfx1 serves to maintain these elevated levels. This reveals a novel mechanism for the regulation of telomeric transcripts. We extend this to demonstrate that human Translin and Trax also control telomere-associated transcript levels in human cells in a telomere-specific fashion.

C-terminal residues of rice translin are essential for octamer formation and nucleic acid binding

Translin is a DNA/RNA binding protein involved in DNA repair and RNA metabolism. Previously, we had shown that rice translin (221 amino acids) exhibits biochemical activities similar to that of the human translin protein. Here we report the role of the C-terminal random coil in rice translin function by analyzing truncation (after 215^th residue, Tra - 215) and substitution mutant proteins (Ser216Ala, Lys217Ala, Gln218Ala, Glu219Ala). Circular Dichroism (CD) analysis of Tra-215 showed deviations in comparison to Tra-WT. Truncation abolished the DNA binding activity and octamer formation as evidenced by the absence of ring like structures from TEM analysis. CD analysis of the substitution mutant proteins showed that the secondary structure was maintained in all the mutant proteins in comparison to wild type protein. Native PAGE and TEM analysis of the substitution mutants showed that Lys217Ala mutation completely abolished the octamer formation as rings and nucleic acid binding. Glu219Ala mutation also affected oligomerization but exhibited marginal RNA binding at higher protein concentrations and interestingly, failed to bind to DNA. However, Ser216Ala and Gln218Ala substitutions did not affect above mentioned activities of translin. Our results indicate that the C-terminal residues are one of the determinants of octamer formation in rice translin, with lysine at 217^th position being the most important. Therefore, in conclusion, although the C-terminal residues do not form any defined secondary structure in the translin monomer, they are definitely involved in octamer formation and hence important for its molecular function. We have attempted to find the critical residues in translin function, which will advance our understanding of translin in DNA repair process in general and of rice translin in particular.

The dynamic landscape of fission yeast meiosis alternative-splice isoforms

Alternative splicing increases the diversity of transcriptomes and proteomes in metazoans. The extent to which alternative splicing is active and functional in unicellular organisms is less understood. Here, we exploit a single-molecule long-read sequencing technique and develop an open-source software program called SpliceHunter to characterize the transcriptome in the meiosis of fission yeast. We reveal 14,353 alternative splicing events in 17,669 novel isoforms at different stages of meiosis, including antisense and read-through transcripts. Intron retention is the major type of alternative splicing, followed by alternate “intron in exon.” Seven hundred seventy novel transcription units are detected; 53 of the predicted proteins show homology in other species and form theoretical stable structures. We report the complexity of alternative splicing along isoforms, including 683 intra-molecularly co-associated intron pairs. We compare the dynamics of novel isoforms based on the number of supporting full-length reads with those of annotated isoforms and explore the translational capacity and quality of novel isoforms. The evaluation of these factors indicates that the majority of novel isoforms are unlikely to be both condition-specific and translatable but consistent with the possibility of biologically functional novel isoforms. Moreover, the co-option of these unusual transcripts into newly born genes seems likely. Together, the results of this study highlight the diversity and dynamics at the isoform level in the sexual development of fission yeast.

Structural basis for single-stranded RNA recognition and cleavage by C3PO

Translin and translin-associated factor-x are highly conserved in eukaroytes; they can form heteromeric complexes (known as C3POs) and participate in various nucleic acid metabolism pathways. In humans and Drosophila, C3POs cleave the fragmented siRNA passenger strands and facilitate the activation of RNA-induced silencing complex, the effector complex of RNA interference (RNAi). Here, we report three crystal structures of Nanoarchaeum equitans (Ne) C3PO. The apo-NeC3PO structure adopts an open form and unravels a potential substrates entryway for the first time. The NeC3PO:ssRNA and NeC3PO:ssDNA complexes fold like closed football with the substrates captured at the inner cavities. The NeC3PO:ssRNA structure represents the only catalytic form C3PO complex available to date; with mutagenesis and in vitro cleavage assays, the structure provides critical insights into the substrate binding and the two-cation-assisted catalytic mechanisms that are shared by eukaryotic C3POs. The work presented here further advances our understanding on the RNAi pathway.

A novel open-barrel structure of octameric translin reveals a potential RNA entryway

The single-stranded DNA (ssDNA)/RNA binding protein translin was suggested to be involved in chromosomal translocations, telomere metabolism, and mRNA transport and translation. Oligonucleotide binding surfaces map within a closed cavity of translin octameric barrels, raising the question as to how DNA/RNA gain access to this inner cavity, particularly given that, to date, none of the barrel structures reported hint to an entryway. Here, we argue against a mechanism by which translin octamers may "dissociate and reassemble" upon RNA binding and report a novel "open"-barrel structure of human translin revealing a feasible DNA/RNA entryway into the cavity. Additionally, we report that translin not only is confined to binding of ssDNA oligonucleotides, or single-stranded extensions of double-stranded DNA (dsDNA), but also can bind single-stranded sequences internally embedded in dsDNA molecules.

Characterization of a plant (rice) translin and its comparative analysis with human translin

For the first time, a plant (rice) translin was characterized. The rice translin protein, which was octameric in native state, bound efficiently to single-stranded DNA and RNA. Translin, a DNA-/RNA-binding protein, is expressed in brain, testis and in certain malignancies. It is involved in chromosomal translocation, mRNA metabolism, transcriptional regulation and telomere protection. Studies from human, mice, drosophila and yeast have revealed that it forms an octameric ring, which is important for its function. In spite of the absence of neuronal functions and cancer processes, translin is present in plant systems, but information on plant translin is lacking. Here we report the characterization of a plant (rice) translin. Translin cDNA from O. sativa was cloned into an expression vector; protein was over-expressed in E. coli and subsequently purified to homogeneity. Circular dichroism and homology-based modeling showed that the rice translin protein was similar to the other translin proteins. Native PAGE and gel-filtration analyses showed rice translin to form an octamer and this octameric assembly was independent of disulphide bonds. Rice translin bound to single-stranded DNA sequences like human translin, but not to the double-stranded DNA. Rice translin bound more efficiently to linear DNA (with staggered ends) than open or closed circular DNA. Rice translin also bound to RNA, like its human counterpart. Rice translin displays all the characteristic properties of the translin group of proteins and does indeed qualify as a bonafide "translin" protein. To our knowledge, this is the first report wherein the translin protein from a plant source has been functionally characterized. Understanding the translin biology from plant systems will give the new insights into its functional role during plant development.

Conformational transitions in human translin enable nucleic acid binding

Translin is a highly conserved RNA- and DNA-binding protein that plays essential roles in eukaryotic cells. Human translin functions as an octamer, but in the octameric crystallographic structure, the residues responsible for nucleic acid binding are not accessible. Moreover, electron microscopy data reveal very different octameric configurations. Consequently, the functional assembly and the mechanism of nucleic acid binding by the protein remain unclear. Here, we present an integrative study combining small-angle X-ray scattering (SAXS), site-directed mutagenesis, biochemical analysis and computational techniques to address these questions. Our data indicate a significant conformational heterogeneity for translin in solution, formed by a lesser-populated compact octameric state resembling the previously solved X-ray structure, and a highly populated open octameric state that had not been previously identified. On the other hand, our SAXS data and computational analyses of translin in complex with the RNA oligonucleotide (GU)₁₂ show that the internal cavity found in the octameric assemblies can accommodate different nucleic acid conformations. According to this model, the nucleic acid binding residues become accessible for binding, which facilitates the entrance of the nucleic acids into the cavity. Our data thus provide a structural basis for the functions that translin performs in RNA metabolism and transport.

The translin-TRAX complex (C3PO) is a ribonuclease in tRNA processing

The conserved Translin-TRAX complexes, also known as C3PO, have been implicated in many biological processes, but how they function remains unclear. Recently, C3PO was shown to be an endoribonuclease that promotes RNA interference in animal cells. Here we show that C3PO does not play a significant role in RNAi in the filamentous fungus Neurospora crassa. Instead, the Neurospora C3PO functions as a ribonuclease that removes the 5′ pre-tRNA fragments after the processing of pre-tRNAs by RNase P. In addition, the translin and trax mutants have elevated levels of tRNA and protein translation and are more resistant to a cell-death inducing agent. Finally, we showed that C3PO is also involved in tRNA processing in mouse embryonic fibroblast cells. Together, this study identified the endogenous RNA substrates of C3PO and provides a potential explanation for its roles in seemingly diverse biological processes.

Multimeric assembly and biochemical characterization of the Trax-translin endonuclease complex

Trax-translin heteromers, also known as C3PO, have been proposed to activate the RNA-induced silencing complex (RISC) by facilitating endonucleolytic cleavage of the siRNA passenger strand. We report on the crystal structure of hexameric Drosophila C3PO formed by truncated translin and Trax, along with electron microscopic and mass spectrometric studies on octameric C3PO formed by full-length translin and Trax. Our studies establish that Trax adopts the translin fold, possesses catalytic centers essential for C3PO's endoRNase activity and interacts extensively with translin to form an octameric assembly. The catalytic pockets of Trax subunits are located within the interior chamber of the octameric scaffold. Truncated C3PO, like full-length C3PO, shows endoRNase activity that leaves 3'-hydroxyl-cleaved ends. We have measured the catalytic activity of C3PO and shown it to cleave almost stoichiometric amounts of substrate per second.

Biological roles of translin and translin-associated factor-X: RNA metabolism comes to the fore

Translin, and its binding partner protein TRAX (translin-associated factor-X) are a paralogous pair of conserved proteins, which have been implicated in a broad spectrum of biological activities, including cell growth regulation, mRNA processing, spermatogenesis, neuronal development/function, genome stability regulation and carcinogenesis, although their precise role in some of these processes remains unclear. Furthermore, translin (with or without TRAX) has nucleic-acid-binding activity and it is apparent that controlling nucleic acid metabolism and distribution are central to the biological role(s) of this protein and its partner TRAX. More recently, translin and TRAX have together been identified as enhancer components of an RNAi (RNA interference) pathway in at least one organism and this might provide critical insight into the biological roles of this enigmatic partnership. In the present review we discuss the biological and the biochemical properties of these proteins that indicate that they play a central and important role in eukaryotic cell biology.

Mapping of interaction sites of the Schizosaccharomyces pombe protein Translin with nucleic acids and proteins: a combined molecular genetics and bioinformatics study

Translin is a single-stranded RNA- and DNA-binding protein, which has been highly conserved in eukaryotes, from man to Schizosaccharomyces pombe. TRAX is a Translin paralog associated with Translin, which has coevolved with it. We generated structural models of the S. pombe Translin (spTranslin), based on the solved 3D structure of the human ortholog. Using several bioinformatics computation tools, we identified in the equatorial part of the protein a putative nucleic acids interaction surface, which includes many polar and positively charged residues, mostly arginines, surrounding a shallow cavity. Experimental verification of the bioinformatics predictions was obtained by assays of nucleic acids binding to amino acid substitution variants made in this region. Bioinformatics combined with yeast two-hybrid assays and proteomic analyses of deletion variants, also identified at the top of the spTranslin structure a region required for interaction with spTRAX, and for spTranslin dimerization. In addition, bioinformatics predicted the presence of a second protein-protein interaction site at the bottom of the spTranslin structure. Similar nucleic acid and protein interaction sites were also predicted for the human Translin. Thus, our results appear to generally apply to the Translin family of proteins, and are expected to contribute to a further elucidation of their functions.

Crystal structures of Drosophila mutant translin and characterization of translin variants reveal the structural plasticity of translin proteins

Translin protein is highly conserved in eukaryotes. Human translin binds both ssDNA and RNA. Its nucleic acid binding site results from a combination of basic regions in the octameric structure. We report here the first biochemical characterization of wild-type Drosophila melanogaster (drosophila) translin and a chimeric translin, and present 3.5 A resolution crystal structures of drosophila P168S mutant translin from two crystal forms. The wild-type drosophila translin most likely exists as an octamer/decamer, and binds to the ssDNA Bcl-CL1 sequence. In contrast, ssDNA binding-incompetent drosophila P168S mutant translin exists as a tetramer. The structures of the mutant translin are identical in both crystal forms, and their C-terminal residues are disordered. The chimeric protein, possessing two nucleic acid binding motifs of drosophila translin, the C-terminal residues of human translin, and serine at position 168, attains the octameric state and binds to ssDNA. The present studies suggest that the oligomeric status of translin critically influences the DNA binding properties of translin proteins.

The Translin/Trax RNA binding complex: clues to function in the nervous system

Translin and Trax are components of an evolutionarily conserved RNA binding complex. Deletion of Translin in yeast, Drosophila and mouse produces a dramatic loss of Trax protein indicating that its stable expression is dependent on its association with Translin. Analysis of Translin KO mice has revealed multiple behavioral abnormalities and alterations in levels of transcripts encoding synaptic proteins. A confluence of localization, biochemical and RNA trafficking studies supports the view that this complex mediates dendritic trafficking of RNAs, a process thought to play a critical role in synaptic plasticity. However, further studies are needed to define its RNA cargoes, its precise role in this process, and how its binding activity and localization are regulated. Nevertheless, there is sufficient evidence to suggest that the Translin/Trax complex be included among the cadre of RNA binding complexes, such as Staufen and CPEB, that regulate dendritic trafficking of RNA in neurons.

Functional characterisation of the Schizosaccharomyces pombe homologue of the leukaemia-associated translocation breakpoint binding protein translin and its binding partner, TRAX

Translin is a conserved protein which associates with the breakpoint junctions of chromosomal translocations linked with the development of some human cancers. It binds to both DNA and RNA and has been implicated in mRNA metabolism and regulation of genome stability. It has a binding partner, translin-associated protein X (TRAX), levels of which are regulated by the translin protein in higher eukaryotes. In this study we find that this regulatory function is conserved in the lower eukaryotes, suggesting that translin and TRAX have important functions which provide a selective advantage to both unicellular and multi-cellular eukaryotes, indicating that this function may not be tissue-specific in nature. However, to date, the biological importance of translin and TRAX remains unclear. Here we systematically investigate proposals that suggest translin and TRAX play roles in controlling mitotic cell proliferation, DNA damage responses, genome stability, meiotic/mitotic recombination and stability of GT-rich repeat sequences. We find no evidence for translin and/or TRAX primary function in these pathways, indicating that the conserved biochemical function of translin is not implicated in primary pathways for regulating genome stability and/or segregation.

Expression pattern of Drosophila translin and behavioral analyses of the mutant

Translin is an evolutionarily conserved approximately 27-kDa protein that binds to specific DNA and RNA sequences and has diverse cellular functions. Here, we report the cloning and characterization of the translin orthologue from the fruit fly Drosophila melanogaster. Under protein-denaturing conditions, purified Drosophila translin exists as a mixture of dimers and monomers just like human translin. In contrast to human translin, the Drosophila translin dimers do not appear to be stabilized by disulfide interactions. Drosophila translin shows a ubiquitous cytoplasmic localization in early embryonal syncytial stage, with an enhanced staining in ventral neuroblasts at later stages (8-9), which are probably at metaphase. An elevated expression was seen in several other cell types, such as cells around the tracheal pits in the embryo and oenocytes in the third instar larva. RNA in situ hybridization showed an increased expression in the ventral midline cells of the larval brain, suggesting a neuronal expression, which was corroborated by protein immunostaining. In adult flies, Drosophila translin is localized in the brain neuronal cell bodies and in early spermatocytes. Interestingly, Drosophila translin mutants exhibit an impaired motor response which is sex specific. Taken together, the multiple cellular localizations, the high neuronal expression and the attendant locomotor defect of the Drosophila translin mutant suggest that Drosophila translin may have roles in neuronal development and behavior analogous to that of mouse translin.

Functional characterization of Drosophila Translin and Trax

The vertebrate RNA and ssDNA-binding protein Translin has been suggested to function in a variety of cellular processes, including DNA damage response, RNA transport, and translational control. The Translin-associated factor X (Trax) interacts with Translin, and Trax protein stability depends on the presence of Translin. To determine the function of the Drosophila Translin and Trax, we generated a translin null mutant and isolated a trax nonsense mutation. translin and trax single and double mutants are viable, fertile, and phenotypically normal. Meiotic recombination rates and chromosome segregation are also not affected in translin and trax mutants. In addition, we found no evidence for an increased sensitivity for DNA double-strand damage in embryos and developing larvae. Together with the lack of evidence for their involvement in DNA double-strand break checkpoints, this argues against a critical role for Translin and Trax in sensing or repairing such DNA damage. However, Drosophila translin is essential for stabilizing the Translin interaction partner Trax, a function that is surprisingly conserved throughout evolution. Conversely, trax is not essential for Translin stability as trax mutants exhibit normal levels of Translin protein.