Differential toxicity of TAR DNA‐binding protein 43 isoforms depends on their submitochondrial localization in neuronal cells

TAR DNA ‐binding protein 43 (TDP ‐43) is an RNA ‐binding protein and a major component of protein aggregates found in amyotrophic lateral sclerosis and several other neurodegenerative diseases. TDP ‐43 exists as a full‐length protein and as two shorter forms of 25 and 35 kD a. Full‐length mutant TDP ‐43s found in amyotrophic lateral sclerosis patients re‐localize from the nucleus to the cytoplasm and in part to mitochondria, where they exert a toxic role associated with neurodegeneration. However, induction of mitochondrial damage by TDP ‐43 fragments is yet to be clarified. In this work, we show that the mitochondrial 35 kD a truncated form of TDP ‐43 is restricted to the intermembrane space, while the full‐length forms also localize in the mitochondrial matrix in cultured neuronal NSC ‐34 cells. Interestingly, the full‐length forms clearly affect mitochondrial metabolism and morphology, possibly via their ability to inhibit the expression of Complex I subunits encoded by the mitochondrial‐transcribed mRNA s, while the 35 kD a form does not. In the light of the known differential contribution of the full‐length and short isoforms to generate toxic aggregates, we propose that the presence of full‐length TDP ‐43s in the matrix is a primary cause of mitochondrial damage. This in turn may cause oxidative stress inducing toxic oligomers formation, in which short TDP ‐43 forms play a major role.

     

Critical roles of tyrosyl‐DNA phosphodiesterases in cell tolerance to carnosol‐induced DNA damage

Carnosol is a natural compound with pharmacological action due to its anti‐cancer properties. However, the precise mechanism for its anti‐carcinogenic effect remains elusive. In this study, we used lymphoblastoid TK6 cell lines to identify the DNA damage and repair mechanisms of carnosol. Our results showed that carnosol induced DNA double‐strand breaks (DSBs). We also found that cells lacking tyrosyl‐DNA phosphodiesterase 1 (TDP1), an enzyme related to topoisomerase 1 (TOP1), and tyrosyl‐DNA phosphodiesterase 2 (TDP2), an enzyme related to topoisomerase 2 (TOP2), were supersensitive to carnosol. Carnosol was found to induce the formation of the TOP1‐DNA cleavage complex (TOP1cc) and TOP2‐DNA cleavage complex (TOP2cc). When comparing the accumulation of γ‐H2AX foci and the number of chromosomal aberrations (CAs) with wild‐type (WT) cells, the susceptivity of the TDP1^?/? and TDP2^?/? cells were associated with an increased DNA damage. Our results provided evidence of carnosol inducing DNA lesions in TK6 cells and demonstrated that the damage induced by carnosol was associated with abnormal topoisomerase activity. We conclude that TDP1 and TDP2 play important roles in the anti‐cancer effect of carnosol.     

The S‐phase checkpoint: targeting the replication fork

The S‐phase checkpoint is a surveillance mechanism, mediated by the protein kinases Mec1 and Rad53 in the budding yeast Saccharomyces cerevisiae (ATR and Chk2 in human cells, respectively) that responds to DNA damage and replication perturbations by co‐ordinating a global cellular response necessary to maintain genome integrity. A key aspect of this response is the stabilization of DNA replication forks, which is critical for cell survival. A defective checkpoint causes irreversible replication‐fork collapse and leads to genomic instability, a hallmark of cancer cells. Although the precise mechanisms by which Mec1/Rad53 maintain functional replication forks are currently unclear, our knowledge about this checkpoint function has significantly increased during the last years. Focusing mainly on the advances obtained in S. cerevisiae, the present review will summarize our understanding of how the S‐phase checkpoint preserves the integrity of DNA replication forks and discuss the most recent findings on this topic.     

Non‐apoptotic function of caspases in a cellular model of hydrogen peroxide‐associated colitis

Oxidative stress, caused by reactive oxygen species (ROS), is a major contributor to inflammatory bowel disease (IBD)‐associated neoplasia. We mimicked ROS exposure of the epithelium in IBD using non‐tumour human colonic epithelial cells (HCEC) and hydrogen peroxide (H₂O₂). A population of HCEC survived H₂O₂‐induced oxidative stress via JNK‐dependent cell cycle arrests. Caspases, p21^WAF1 and γ‐H2AX were identified as JNK‐regulated proteins. Up‐regulation of caspases was linked to cell survival and not, as expected, to apoptosis. Inhibition using the pan‐caspase inhibitor Z‐VAD‐FMK caused up‐regulation of γ‐H2AX, a DNA‐damage sensor, indicating its negative regulation via caspases. Cell cycle analysis revealed an accumulation of HCEC in the G₁‐phase as first response to oxidative stress and increased S‐phase population and then apoptosis as second response following caspase inhibition. Thus, caspases execute a non‐apoptotic function by promoting cells through G₁‐ and S‐phase by overriding the G₁/S‐ and intra‐S checkpoints despite DNA‐damage. This led to the accumulation of cells in the G₂/M‐phase and decreased apoptosis. Caspases mediate survival of oxidatively damaged HCEC via γ‐H2AX suppression, although its direct proteolytic inactivation was excluded. Conversely, we found that oxidative stress led to caspase‐dependent proteolytic degradation of the DNA‐damage checkpoint protein ATM that is upstream of γ‐H2AX. As a consequence, undetected DNA‐damage and increased proliferation were found in repeatedly H₂O₂‐exposed HCEC. Such features have been associated with neoplastic transformation and appear here to be mediated by a non‐apoptotic function of caspases. Overexpression of upstream p‐JNK in active ulcerative colitis also suggests a potential importance of this pathway in vivo.     

Condensin recruitment to chromatin is inhibited by Chk2 kinase in response to DNA damage

The DNA damage checkpoint, when activated in response to genotoxic damage during S phase, arrests cells in G2 phase of the cell cycle. ATM, ATR, Chk1 and Chk2 kinases are the main effectors of this checkpoint pathway. The checkpoint kinases prevent the onset of mitosis by eliciting well characterized inhibitory phosphorylation of Cdk1. Since Cdk1 is required for the recruitment of condensin, it is thought that upon DNA damage the checkpoint also indirectly blocks chromosome condensation via Cdk1 inhibition. Here we report that the G2 damage checkpoint prevents stable recruitment of the chromosome-packaging-machinery components condensin complex I and II onto the chromatin even in the presence of an active Cdk1. DNA damage-induced inhibition of condensin subunit recruitment is mediated specifically by the Chk2 kinase, implying that the condensin complexes are targeted by the checkpoint in response to DNA damage, independently of Cdk1 inactivation. Thus, the G2 checkpoint directly prevents stable recruitment of condensin complexes to actively prevent chromosome compaction during G2 arrest, presumably to ensure efficient repair of the genomic damage.     

Parkin reverses TDP‐43‐induced cell death and failure of amino acid homeostasis

The E3 ubiquitin ligase Parkin plays a central role in the pathogenesis of many neurodegenerative diseases. Parkin promotes specific ubiquitination and affects the localization of transactivation response DNA‐binding protein 43 (TDP‐43), which controls the translation of thousands of mRNAs. Here we tested the effects of lentiviral Parkin and TDP‐43 expression on amino acid metabolism in the rat motor cortex using high frequency ¹³C NMR spectroscopy. TDP‐43 expression increased glutamate levels, decreased the levels of other amino acids, including glutamine, aspartate, leucine and isoleucine, and impaired mitochondrial tricarboxylic acid cycle. TDP‐43 induced lactate accumulation and altered the balance between excitatory (glutamate) and inhibitory (GABA) neurotransmitters. Parkin restored amino acid levels, neurotransmitter balance and tricarboxylic acid cycle metabolism, rescuing neurons from TDP‐43‐induced apoptotic death. Furthermore, TDP‐43 expression led to an increase in 4E‐BP levels, perhaps altering translational control and deregulating amino acid synthesis; while Parkin reversed the effects of TDP‐43 on the 4E‐BP signaling pathway. Taken together, these data suggest that Parkin may affect TDP‐43 localization and mitigate its effects on 4E‐BP signaling and loss of amino acid homeostasis.

     

TDP‐43 associates with stalled ribosomes and contributes to cell survival during cellular stress

TAR DNA‐binding protein 43 (TDP‐43) has emerged as an important contributor to amyotrophic lateral sclerosis and frontotemporal lobar degeneration. To understand the physiological roles of TDP‐43 in the complex translational regulation mechanisms, we exposed cultured cells to oxidative stress induced by sodium arsenite (ARS) for different periods of time, leading to non‐lethal or sublethal injury. Polysome profile analysis revealed that ARS‐induced stress caused the association of TDP‐43 with stalled ribosomes via binding to mRNA, which was not found under the steady‐state condition. When the cells were exposed to short‐term/non‐lethal stress, TDP‐43 associating with ribosomes localized to stress granules (SGs); this association was transient because it was immediately dissolved by the removal of the stress. In contrast, when the cells were exposed to long‐term/sublethal stress, TDP‐43 was excluded from SGs and shifted to the heavy fractions independent of any binding to mRNA. In these severely stressed cells, biochemical alterations of TDP‐43, such as increased insolubility and disulfide bond formation, were irreversible. TDP‐43 was finally phosphorylated via the ARS‐induced c‐jun N‐terminal kinase pathway. In TDP‐43‐silenced cells, stalled mRNA and poly (A)⁺ RNA stability was disturbed and cytotoxicity increased under sublethal stress. Thus, TDP‐43 associates with stalled ribosomes and contributes to cell survival during cellular stress.     

“Ready,Set, Go”: Checkpoint regulation by Cdk1 inhibitory phosphorylation

ABSTRACT

Cell cycle checkpoints prevent mitosis from occurring before DNA replication and repair are completed during S and G2 phases. The checkpoint mechanism involves inhibitory phosphorylation of Cdk1, a conserved kinase that regulates the onset of mitosis. Metazoans have two distinct Cdk1 inhibitory kinases with specialized developmental functions: Wee1 and Myt1. Ayeni et al used transgenic Cdk1 phospho-acceptor mutants to analyze how the distinct biochemical properties of these kinases affected their functions. They concluded from their results that phosphorylation of Cdk1 on Y15 was necessary and sufficient for G2/M checkpoint arrest in imaginal wing discs, whereas phosphorylation on T14 promoted chromosome stability by a different mechanism. A curious relationship was also noted between Y15 inhibitory phosphorylation and T161 activating phosphorylation. These unexpected complexities in Cdk1 inhibitory phosphorylation demonstrate that the checkpoint mechanism is not a simple binary “off/on” switch, but has at least three distinct states: “Ready”, to prevent chromosome damage and apoptosis, “Set”, for developmentally regulated G2 phase arrest, and “Go”, when Cdc25 phosphatases remove inhibitory phosphates to trigger Cdk1 activation at the G2/M transition.     

TDP‐43 loss of function increases TFEB activity and blocks autophagosome–lysosome fusion

Amyotrophic lateral sclerosis (ALS) is a fatal neurodegenerative disease that is characterized by selective loss of motor neurons in brain and spinal cord. TAR DNA‐binding protein 43 (TDP‐43) was identified as a major component of disease pathogenesis in ALS, frontotemporal lobar degeneration (FTLD), and other neurodegenerative disease. Despite the fact that TDP‐43 is a multi‐functional protein involved in RNA processing and a large number of TDP‐43 RNA targets have been discovered, the initial toxic effect and the pathogenic mechanism underlying TDP‐43‐linked neurodegeneration remain elusive. In this study, we found that loss of TDP‐43 strongly induced a nuclear translocation of TFEB, the master regulator of lysosomal biogenesis and autophagy, through targeting the mTORC1 key component raptor. This regulation in turn enhanced global gene expressions in the autophagy–lysosome pathway (ALP) and increased autophagosomal and lysosomal biogenesis. However, loss of TDP‐43 also impaired the fusion of autophagosomes with lysosomes through dynactin 1 downregulation, leading to accumulation of immature autophagic vesicles and overwhelmed ALP function. Importantly, inhibition of mTORC1 signaling by rapamycin treatment aggravated the neurodegenerative phenotype in a TDP‐43‐depleted Drosophila model, whereas activation of mTORC1 signaling by PA treatment ameliorated the neurodegenerative phenotype. Taken together, our data indicate that impaired mTORC1 signaling and influenced ALP may contribute to TDP‐43‐mediated neurodegeneration.     

Unmasking the skiptic task of TDP‐43

The mechanism by which mutations in TAR DNA‐binding protein 43 (TDP‐43) cause neurodegeneration remains incompletely understood. In this issue of The EMBO Journal, Fratta et al ( 2018 ) describe how a point mutation in the C‐terminal low complexity domain of TDP‐43 leads to the skipping of otherwise constitutively conserved exons. In vivo, this mutation triggers late‐onset progressive neuromuscular disturbances, as seen in amyotrophic lateral sclerosis (ALS), suggesting that TDP‐43 splicing gain‐of‐function contributes to ALS pathogenesis.     

A single N‐terminal phosphomimic disrupts TDP‐43 polymerization,phase separation,and RNA splicing

TDP‐43 is an RNA‐binding protein active in splicing that concentrates into membraneless ribonucleoprotein granules and forms aggregates in amyotrophic lateral sclerosis (ALS) and Alzheimer's disease. Although best known for its predominantly disordered C‐terminal domain which mediates ALS inclusions, TDP‐43 has a globular N‐terminal domain (NTD). Here, we show that TDP‐43 NTD assembles into head‐to‐tail linear chains and that phosphomimetic substitution at S48 disrupts TDP‐43 polymeric assembly, discourages liquid–liquid phase separation (LLPS) in vitro, fluidizes liquid–liquid phase separated nuclear TDP‐43 reporter constructs in cells, and disrupts RNA splicing activity. Finally, we present the solution NMR structure of a head‐to‐tail NTD dimer comprised of two engineered variants that allow saturation of the native polymerization interface while disrupting higher‐order polymerization. These data provide structural detail for the established mechanistic role of the well‐folded TDP‐43 NTD in splicing and link this function to LLPS. In addition, the fusion‐tag solubilized, recombinant form of TDP‐43 full‐length protein developed here will enable future phase separation and in vitro biochemical assays on TDP‐43 function and interactions that have been hampered in the past by TDP‐43 aggregation.