Janelle L. Harris

Phosphorylation of EXO1 by CDKs 1 and 2 regulates DNA end resection and repair pathway choice

Resection of DNA double-strand breaks (DSBs) is a pivotal step during which the choice between NHEJ and HR DNA repair pathways is made. While CDKs are known to control initiation of resection, their role in regulating long-range resection remains elusive. Here we show that CDKs 1/2 phosphorylate the long-range resection nuclease EXO1 at four C-terminal S/TP sites during S/G2 phases of the cell cycle. Impairment of EXO1 phosphorylation attenuates resection, chromosomal integrity, cell survival, and HR, but augments NHEJ upon DNA damage. In contrast, cells expressing phospho-mimic EXO1 are proficient in resection even after CDK inhibition and favor HR over NHEJ. Mutation of cyclin-binding sites on EXO1 attenuates CDK binding and EXO1 phosphorylation, causing a resection defect that can be rescued by phospho-mimic mutations. Mechanistically, phosphorylation of EXO1 augments its recruitment to DNA breaks possibly via interactions with BRCA1. In sum, phosphorylation of EXO1 by CDKs is a novel mechanism regulating repair pathway choice.

Aprataxin Forms a Discrete Branch in the HIT (Histidine Triad) Superfamily of Proteins with Both DNA/RNA Binding and Nucleotide Hydrolase Activities

Ataxia with oculomotor apraxia type 1 (AOA1) is an early onset autosomal recessive spinocerebellar ataxia with a defect in the protein Aprataxin, implicated in the response of cells to DNA damage. We describe here the expression of a recombinant form of Aprataxin and show that it has dual DNA binding and nucleotide hydrolase activities. This protein binds to double-stranded DNA with high affinity but is also capable of binding double-stranded RNA and single-strand DNA, with increased affinity for hairpin structures. No increased binding was observed with a variety of DNA structures mimicking intermediates in DNA repair. The DNA binding observed here was not dependent on zinc, and the addition of exogenous zinc abolished DNA binding. We also demonstrate that Aprataxin hydrolyzes with similar efficiency the model histidine triad nucleotide-binding protein substrate, AMPNH2, and the Fragile histidine triad protein substrate, Ap4A. These activities were significantly reduced in the presence of duplex DNA and to a lesser extent in the presence of single-strand DNA, and removal of the N-terminal Forkhead associated domain did not alter activity. Finally, comparison of sequence relationships between the histidine triad superfamily members shows that Aprataxin forms a distinct branch in this superfamily. In addition to its capacity for nucleotide binding and hydrolysis, the observation that it also binds DNA and RNA adds a new dimension to this superfamily of proteins and provides further support for a role for Aprataxin in the cellular response to DNA damage.

Chromatinized Protein Kinase C-θ Directly Regulates Inducible Genes in Epithelial to Mesenchymal Transition and Breast Cancer Stem Cells

ABSTRACT Epithelial to mesenchymal transition (EMT) is activated during cancer invasion and metastasis, enriches for cancer stem cells (CSCs), and contributes to therapeutic resistance and disease recurrence. Signal transduction kinases play a pivotal role as chromatin-anchored proteins in eukaryotes. Here we report for the first time that protein kinase C-theta (PKC-θ) promotes EMT by acting as a critical chromatin-anchored switch for inducible genes via transforming growth factor β (TGF-β) and the key inflammatory regulatory protein NF-κB. Chromatinized PKC-θ exists as an active transcription complex and is required to establish a permissive chromatin state at signature EMT genes. Genome-wide analysis identifies a unique cohort of inducible PKC-θ-sensitive genes that are directly tethered to PKC-θ in the mesenchymal state. Collectively, we show that cross talk between signaling kinases and chromatin is critical for eliciting inducible transcriptional programs that drive mesenchymal differentiation and CSC formation, providing novel mechanisms to target using epigenetic therapy in breast cancer.

BMCC1 Is an AP-2 associated endosomal protein in prostate cancer cells

The prostate cancer antigen gene 3 (PCA3) is embedded in an intron of a second gene BMCC1 (Bcl2-/adenovirus E1B nineteen kDa-interacting protein 2 (BNIP-2) and Cdc42GAP homology BCH motif-containing molecule at the carboxyl terminal region 1) which is also upregulated in prostate cancer. BMCC1 was initially annotated as two genes (C9orf65/PRUNE and BNIPXL) on either side of PCA3 but our data suggest that it represents a single gene coding for a high molecular weight protein. Here we demonstrate for the first time the expression of a >300 kDa BMCC1 protein (BMCC1-1) in prostate cancer and melanoma cell lines. This protein was found exclusively in the microsomal fraction and localised to cytoplasmic vesicles. We also observed expression of BMCC1 protein in prostate cancer sections using immunohistology. GST pull down, immunoprecipitation and mass spectrometry protein interaction studies identified multiple members of the Adaptor Related Complex 2 (AP-2) as BMCC1 interactors. Consistent with a role for BMCC1 as an AP-2 interacting endosomal protein, BMCC1 co-localised with β-adaptin at the perinuclear region of the cell. BMCC1 also showed partial co-localisation with the early endosome small GTP-ase Rab-5 as well as strong co-localisation with internalised pulse-chase labelled transferrin (Tf), providing evidence that BMCC1 is localised to functional endocytic vesicles. BMCC1 knockdown did not affect Tf uptake and AP-2 knockdown did not disperse BMCC1 vesicular distribution, excluding an essential role for BMCC1 in canonical AP-2 mediated endocytic uptake. Instead, we posit a novel role for BMCC1 in post-endocytic trafficking. This study provides fundamental characterisation of the BMCC1 complex in prostate cancer cells and for the first time implicates it in vesicle trafficking.

Ssb1 and Ssb2 cooperate to regulate mouse hematopoietic stem and progenitor cells by resolving replicative stress

Hematopoietic stem and progenitor cells (HSPCs) are vulnerable to endogenous damage and defects in DNA repair can limit their function. The 2 single-stranded DNA (ssDNA) binding proteins SSB1 and SSB2 are crucial regulators of the DNA damage response; however, their overlapping roles during normal physiology are incompletely understood. We generated mice in which both Ssb1 and Ssb2 were constitutively or conditionally deleted. Constitutive Ssb1/Ssb2 double knockout (DKO) caused early embryonic lethality, whereas conditional Ssb1/Ssb2 double knockout (cDKO) in adult mice resulted in acute lethality due to bone marrow failure and intestinal atrophy featuring stem and progenitor cell depletion, a phenotype unexpected from the previously reported single knockout models of Ssb1 or Ssb2 Mechanistically, cDKO HSPCs showed altered replication fork dynamics, massive accumulation of DNA damage, genome-wide double-strand breaks enriched at Ssb-binding regions and CpG islands, together with the accumulation of R-loops and cytosolic ssDNA. Transcriptional profiling of cDKO HSPCs revealed the activation of p53 and interferon (IFN) pathways, which enforced cell cycling in quiescent HSPCs, resulting in their apoptotic death. The rapid cell death phenotype was reproducible in in vitro cultured cDKO-hematopoietic stem cells, which were significantly rescued by nucleotide supplementation or after depletion of p53. Collectively, Ssb1 and Ssb2 control crucial aspects of HSPC function, including proliferation and survival in vivo by resolving replicative stress to maintain genomic stability.

Enhanced dependency of KRAS‐mutant colorectal cancer cells on RAD51‐dependent homologous recombination repair identified from genetic interactions in Saccharomyces cerevisiae

Activating KRAS mutations drive colorectal cancer tumorigenesis and influence response to anti‐EGFR‐targeted therapy. Despite recent advances in understanding Ras signaling biology and the revolution in therapies for melanoma using BRAF inhibitors, no targeted agents have been effective in KRAS‐mutant cancers, mainly due to activation of compensatory pathways. Here, by leveraging the largest synthetic lethal genetic interactome in yeast, we identify that KRAS‐mutated colorectal cancer cells have augmented homologous recombination repair (HRR) signaling. We found that KRAS mutation resulted in slowing and stalling of the replication fork and accumulation of DNA damage. Moreover, we found that KRAS‐mutant HCT116 cells have an increase in MYC‐mediated RAD51 expression with a corresponding increase in RAD51 recruitment to irradiation‐induced DNA double‐strand breaks (DSBs) compared to genetically complemented isogenic cells. MYC depletion using RNA interference significantly reduced IR‐induced RAD51 foci formation and HRR. On the contrary, overexpression of either HA‐tagged wild‐type (WT) MYC or phospho‐mutant S62A increased RAD51 protein levels and hence IR‐induced RAD51 foci. Likewise, depletion of RAD51 selectively induced apoptosis in HCT116‐mutant cells by increasing DSBs. Pharmacological inhibition targeting HRR signaling combined with PARP inhibition selectivity killed KRAS‐mutant cells. Interestingly, these differences were not seen in a second isogenic pair of KRAS WT and mutant cells (DLD‐1), likely due to their nondependency on the KRAS mutation for survival. Our data thus highlight a possible mechanism by which KRAS‐mutant‐dependent cells drive HRR in vitro by upregulating MYC‐RAD51 expression. These data may offer a promising therapeutic vulnerability in colorectal cancer cells harboring otherwise nondruggable KRAS mutations, which warrants further investigation in vivo.

DNA-damage-induced degradation of EXO1 exonuclease limits DNA end resection to ensure accurate DNA repair

End resection of DNA double-strand breaks (DSBs) to generate 3′-single-stranded DNA facilitates DSB repair via error-free homologous recombination (HR) while stymieing repair by the error-prone non-homologous end joining (NHEJ) pathway. Activation of DNA end resection involves phosphorylation of the 5′ to 3′ exonuclease EXO1 by the phosphoinositide 3-kinase-like kinases ATM (ataxia telangiectasia-mutated) and ATR (ATM and Rad3-related) and by the cyclin-dependent kinases 1 and 2. After activation, EXO1 must also be restrained to prevent over-resection that is known to hamper optimal HR and trigger global genomic instability. However, mechanisms by which EXO1 is restrained are still unclear. Here, we report that EXO1 is rapidly degraded by the ubiquitin-proteasome system soon after DSB induction in human cells. ATR inhibition attenuated DNA-damage-induced EXO1 degradation, indicating that ATR-mediated phosphorylation of EXO1 targets it for degradation. In accord with these results, EXO1 became resistant to degradation when its SQ motifs required for ATR-mediated phosphorylation were mutated. We show that upon the induction of DNA damage, EXO1 is ubiquitinated by a member of the Skp1-Cullin1-F-box (SCF) family of ubiquitin ligases in a phosphorylation-dependent manner. Importantly, expression of degradation-resistant EXO1 resulted in hyper-resection, which attenuated both NHEJ and HR and severely compromised DSB repair resulting in chromosomal instability. These findings indicate that the coupling of EXO1 activation with its eventual degradation is a timing mechanism that limits the extent of DNA end resection for accurate DNA repair.

The breast cancer antigen 5T4 interacts with Rab11, and is a target and regulator of Rab11 mediated trafficking

BACKGROUND AND AIMS 5T4 is a transmembrane glycoprotein with limited expression in normal adult tissues and expression in some solid tumours. It is unclear whether 5T4 is preferentially expressed by stem or differentiated cell types. Modes of 5T4 regulation are unknown despite its ongoing development as a cancer immunotherapy target. Our aims were to clarify the differentiation status of 5T4 expressing cells in breast cancer and to understand the mechanism underlying 5T4 membrane presentation. METHODS AND RESULTS We analysed 5T4 expression in breast cancer cell populations by flow cytometery and found that 5T4 is highly expressed on differentiated cells, where it localizes to focal adhesions. Using immunoprecipitation and mass spectrometry, we identified interactions between 5T4 and the membrane trafficking proteins Rab11, Rab18 and ARF6. Mechanistically we found that Rab11 and Rab18 have oppositional roles in controlling expression and surface presentation of 5T4. 5T4 depletion stabilizes Rab11 protein expression with a consequent stimulation transferrin surface labelling, indicating that 5T4 represses endocytic activity. IMPLICATIONS Successful immunotherapeutic targeting of 5T4 requires surface presentation and different immunotherapy strategies require surface presentation versus endocytosis. While breast cancer cells with high 5T4 surface expression and rapid cell surface turnover would be susceptible to antibody-drug conjugates that rely on intracellular release, 5T4 positive cells with lower expression or lower turnover may still be responsive to T-cell mediated approaches. We find that endocytosis of 5T4 is strongly Rab11 dependent and as such Rab11 activity could affect the success or failure of 5T4-targetted immunotherapy, particularly for antibody-drug conjugate approaches. In fact, 5T4 itself represses Rab11 expression. This newly uncovered relationship between Rab11 and 5T4 suggests that breast tumours with high 5T4 expression may not have efficient endocytic uptake of 5T4-targetted immunotherapeutics. This should be considered when selecting amongst the different types of immunotherapies.

Identification of ATM-Interacting Proteins by Co-immunoprecipitation and Glutathione-S-Transferase (GST) Pull-Down Assays

The ATM kinase is a master regulator of the DNA damage response, and can interact with more than 700 proteins in response to DNA damage. These interactions play a critical role in fine-tuning the response of ATM to multiple cellular stressors, and can play both a positive or negative role in regulating its activity. Here, we detail using protein-protein interaction methods, including co-immunoprecipitation and Glutathione-S-transferase (GST) fusion protein pull-down assays to understand the molecular interactions of ATM. These assays give valuable functional insights into the role of ATM, as they are easy to establish within the laboratory, are not overly laborious, and are easily reproducible.