Co-expressed recombinant human Translin-Trax complex binds DNA

Trax, expressed alone aggregates into insoluble complexes, whereas upon co-expression with Translin becomes readily soluble and forms a stable heteromeric complex ( approximately 430 kDa) containing both proteins at nearly equimolar ratio. Based on the subunit molecular weights, estimated by MALDI-TOF-MS, the purified complex appears to comprise of either an octameric Translin plus a hexameric Trax (calculated MW 420 kDa) or a heptamer each of Trax and Translin (calculated MW 425 kDa) or a hexameric Translin plus an octameric Trax (calculated MW 431 kDa). The complex binds single-stranded/double-stranded DNA. ssDNA gel-shifted complex shows both proteins at nearly equimolar ratio, suggesting that Translin "chaperones" Trax and forms heteromeric complex that is DNA binding competent.     

Somatodendritic localization of Translin, a component of the Translin/Trax RNA binding complex

Recent studies implicating dendritic protein synthesis in synaptic plasticity have focused attention on identifying components of the molecular machinery involved in processing dendritic RNA. Although Translin was originally identified as a protein capable of binding single-stranded DNA, subsequent studies have demonstrated that it also binds RNA in vitro. Because previous studies indicated that Translin-containing RNA/single-stranded DNA binding complexes are highly enriched in brain, we and others have proposed that it may be involved in dendritic RNA processing. To assess this possibility, we have conducted studies aimed at defining the localization of Translin and its partner protein, Trax, in brain. In situ hybridization studies demonstrated that both Translin and Trax are expressed in neurons with prominent staining apparent in cerebellar Purkinje cells and neuronal layers of the hippocampus. Subcellular fractionation studies demonstrated that both Translin and Trax are highly enriched in the cytoplasmic fraction compared with nuclear extracts. Furthermore, immunohistochemical studies with Translin antibodies revealed prominent staining in Purkinje neuron cell bodies that extends into proximal and distal dendrites. A similar pattern of somatodendritic localization was observed in hippocampal and neocortical pyramidal neurons. These findings demonstrate that Translin is expressed in neuronal dendrites and therefore support the hypothesis that the Translin/Trax complex may be involved in dendritic RNA processing.     

Trax is a component of the Translin-containing RNA binding complex

Translin is a nucleic acid binding protein that has been implicated in regulating the targeting and translation of dendritic RNA. In previous studies, we found that Translin and its partner protein, Trax, are components of a gel-shift complex that is highly enriched in brain extracts. In those studies, we employed a DNA oligonucleotide, GS1, as a probe to label the complex. Translin has also been identified as a component of a gel-shift complex detected using an RNA oligonucleotide probe, derived from the 3' UTR of protamine-2 mRNA. Although we had assumed that these probes labeled the same complex, recent studies indicate that association of Trax with Translin suppresses its RNA binding activity. As these findings challenge this assumption and suggest that the native RNA binding complex does not contain Trax, we have re-examined this issue. We have found that the gel-shift complexes labeled with either GS1 or protamine-2 probes are "supershifted" by addition of Trax antibodies, indicating that both are heteromeric Translin/Trax complexes. In addition, cross-competition studies provide additional evidence that these probes label the same complex. Furthermore, analysis of recombinant Translin/Trax complexes generated by co-transfection of Trax with Translin in hEK293T demonstrates that they are labeled with either probe. Although recombinant Translin forms a homomeric nucleic acid binding complex in vitro, our findings indicate that both Trax and Translin are components of the native gel-shift complex labeled with either GS1 or protamine-2 probes.     

The polymerization mechanism of the bacterial cell division protein FtsZ

Translin and Trax are components of an RNA binding complex initially detected in extracts of brain and testes. Although other tissues appear to contain much lower or negligible levels of the Translin/Trax gel-shift complex, we found, unexpectedly, that several of these peripheral tissues express Translin and Trax proteins at levels comparable to those present in brain. In this study, we demonstrate that the paradoxically low levels of the Translin/Trax complex in kidney and other peripheral tissues are due to masking of these sites by endogenous RNA. Thus, these findings indicate that the Translin/Trax complex is involved in RNA processing in a broader range of tissues than previously recognized.     

Identification of Translin and Trax as Components of the GS1 Strand-Specific DNA Binding Complex Enriched in Brain

Abstract: In previous gel-shift assays, we identified a protein complex, referred to as GS1, that binds in a sequence-specific manner to single-stranded DNA and is highly enriched in brain. As an initial step in clarifying the function of this complex, we have undertaken studies aimed at defining its protein components. In particular, we focused on identifying two protein bands that were covalently labeled when the GS1-DNA complex was subjected to UV irradiation to induce cross-linking between the radiolabeled probe and GS1 components. By following GS1 binding activity through a series of conventional chromatographic steps, as well as an affinity column based on the DNA oligonucleotide used for gel-shift assays, we were able to achieve ∼500,000-fold enrichment of GS1 compared with that in crude cerebellar extracts used as starting material. This highly purified fraction contained both protein bands detected by UV cross-linking in crude extracts. Sequencing of peptides derived from these proteins led to their identification as Translin and Trax, interacting proteins identified in studies of DNA recombination in lymphocytes. A distinct line of research has provided evidence that a complex containing Translin can bind to specific mRNAs and block their translation. Whether one or both of these proposed functions of the Translin/Trax complex explains the high basal level of GS1 binding activity present in the brain remains to be determined.     

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.