Fang-Tsyr Lin

Regulation of E2F1 by BRCT Domain-Containing Protein TopBP1

ABSTRACT The E2F transcription factor integrates cellular signals and coordinates cell cycle progression. Our prior studies demonstrated selective induction and stabilization of E2F1 through ATM-dependent phosphorylation in response to DNA damage. Here we report that DNA topoisomerase IIβ binding protein 1 (TopBP1) regulates E2F1 during DNA damage. TopBP1 contains eight BRCT (BRCA1 carboxyl-terminal) motifs and upon DNA damage is recruited to stalled replication forks, where it participates in a DNA damage checkpoint. Here we demonstrated an interaction between TopBP1 and E2F1. The interaction depended on the amino terminus of E2F1 and the sixth BRCT domain of TopBP1. It was specific to E2F1 and was not observed in E2F2, E2F3, or E2F4. This interaction was induced by DNA damage and phosphorylation of E2F1 by ATM. Through this interaction, TopBP1 repressed multiple activities of E2F1, including transcriptional activity, induction of S-phase entry, and apoptosis. Furthermore, TopBP1 relocalized E2F1 from diffuse nuclear distribution to discrete punctate nuclear foci, where E2F1 colocalized with TopBP1 and BRCA1. Thus, the specific interaction between TopBP1 and E2F1 during DNA damage inhibits the known E2F1 activities but recruits E2F1 to a BRCA1-containing repair complex, suggesting a direct role of E2F1 in DNA damage checkpoint/repair at stalled replication forks.

MCPH1/BRIT1 cooperates with E2F1 in the activation of checkpoint, DNA repair and apoptosis

Microcephalin (MCPH1) has a crucial role in the DNA damage response by promoting the expression of Checkpoint kinase 1 (CHK1) and Breast cancer susceptibility gene 1 (BRCA1); however, the mechanism of this regulation remains unclear. Here, we show that MCPH1 regulates CHK1 and BRCA1 through the interaction with E2F1 on the promoters of both genes. MCPH1 also regulates other E2F target genes involved in DNA repair and apoptosis such as RAD51, DDB2, TOPBP1, p73 and caspases. MCPH1 interacts with E2F1 on the p73 promoter, and regulates p73 induction and E2F1‐induced apoptosis as a result of DNA damage. MCPH1 forms oligomers through the second and third BRCT domains. An MCPH1 mutant containing only its oligomerization domain has a dominant‐negative role by blocking MCPH1 binding to E2F1. It also inhibits p73 induction in DNA damage and E2F1‐dependent apoptosis. Taken together, MCPH1 cooperates with E2F1 to regulate genes involved in DNA repair, checkpoint and apoptosis, and might participate in the maintenance of genomic integrity.

Regulation of TopBP1 oligomerization by Akt/PKB for cell survival

Regulation of E2F1‐mediated apoptosis is essential for proper cellular growth. This control requires TopBP1, a BRCT (BRCA1 carboxyl‐terminal) domain‐containing protein, which interacts with E2F1 but not other E2Fs and represses its proapoptotic activity. We now show that the regulation of E2F1 by TopBP1 involves the phosphoinositide 3‐kinase (PI3K)–Akt signaling pathway, and is independent of pocket proteins. Akt phosphorylates TopBP1 in vitro and in vivo. Phosphorylation by Akt induces oligomerization of TopBP1 through its seventh and eighth BRCT domains. The Akt‐dependent oligomerization is crucial for TopBP1 to interact with and repress E2F1. Akt phosphorylation is also required for interaction between TopBP1 and Miz1 or HPV16 E2, and repression of Miz1 transcriptional activity, suggesting a general role for TopBP1 oligomerization in the control of transcription factors. Together, this study defines a novel pathway involving PI3K–Akt–TopBP1 for specific control of E2F1 apoptosis, in parallel with cyclin–Cdk–Rb for general control of E2F activities.

ATM-Mediated Stabilization of hMutL DNA Mismatch Repair Proteins Augments p53 Activation during DNA Damage

ABSTRACT Human DNA mismatch repair (MMR) proteins correct DNA errors and regulate cellular response to DNA damage by signaling apoptosis. Mutations of MMR genes result in genomic instability and cancer development. Nonetheless, how MMR proteins are regulated has not yet been determined. While hMLH1, hPMS2, and hMLH3 are known to participate in MMR, the function of another member of MutL-related proteins, hPMS1, remains unclear. Here we show that DNA damage induces the accumulation of hPMS1, hPMS2, and hMLH1 through ataxia-telangiectasia-mutated (ATM)-mediated protein stabilization. The subcellular localization of PMS proteins is also regulated during DNA damage, which induces nuclear localization of hPMS1 and hPMS2 in an hMLH1-dependent manner. The induced levels of hMLH1 and hPMS1 are important for the augmentation of p53 phosphorylation by ATM in response to DNA damage. These observations identify hMutL proteins as regulators of p53 response and demonstrate for the first time a function of hMLH1-hPMS1 complex in controlling the DNA damage response.

Regulation of E2F1 by APC/CCdh1 via K11 linkage-specific ubiquitin chain formation

E2F1 is a eukaryotic transcription factor that is known to regulate various cellular pathways such as cell cycle progression, DNA replication, DNA damage responses and induction of apoptosis. Given its versatile roles, a precise and tight regulation of E2F1 is very critical to maintain genomic stability. E2F1 is regulated both at transcriptional and posttranslational levels during cell cycle and upon DNA damage. After S phase, E2F1 is targeted for degradation and is kept at low levels or in an inactive state until the next G1/S phase transition. Our studies show that APC/C ubiquitin ligase in conjunction with its co-activator Cdh1 (APC/CCdh1) can downregulate E2F1. We also identify an APC/C subunit APC5 that binds to E2F1 and is essential for E2F1 ubiquitination. We confirm an interaction between E2F1 and Cdh1 as well as an interaction between E2F1 and APC5 both in vivo and in vitro. In vitro GST pull-down assays have mapped the C-terminal 79 a.a. of E2F1 as Cdh1 interacting residues. Ectopically expressed Cdh1 downregulates the expression of E2F1–4. Our studies have also shown for the first time that E2F1 can be modified by K11-linkage specific ubiquitin chain formation (Ub-K11). The formation of Ub-K11 chains on E2F1 is increased in the presence of Cdh1 and accumulated in the presence of proteasome inhibitor, suggesting that APC/CCdh1 targets E2F1 for degradation by forming Ub-K11 chains. We also show that the effect of Cdh1 on E2F1 degradation is blocked upon DNA damage. Interestingly, Ub-K11-linked E2F1 accumulates after treatment of DNA damaging agents. The data suggest that DNA damage signaling processes do not inhibit APC/CCdh1 to ubiquitinate E2F1. Instead, they block the proteasomal degradation of Ub-K11-linked E2F1, and therefore lead to its accumulation.

Targeting TopBP1 at a convergent point of multiple oncogenic pathways for cancer therapy

The progression of many solid tumors is driven by de-regulation of multiple common pathways, particularly Rb, PI (3) K/Akt and p53. Prior studies identified TopBP1as a key mediator for the oncogenic gain-of-function activities of mutant p53 (mutp53) in cancer. In Akt-hyperactive cancer, TopBP1 forms oligomers and represses E2F1-dependent apoptosis. Here we perform a molecular docking screening and identify a lead compound, calcein, capable of blocking TopBP1 oligomerization and p53 binding, resulting in re-activation of E2F1-dependent apoptosis and blockade of mutp53 gain-of-function. Calcein AM, the cell permeable derivative of calcein, shows significant anti-tumor activity in a wide-spectrum of cultured cancer cells harboring high TopBP1 levels. These biochemical findings are recapitulated in breast cancer xenograft models. Thus, our study provides proof-of-concept evidence for targeting TopBP1, a convergent point of multiple pathways, as a cancer therapy.

Mutant p53 perturbs DNA replication checkpoint control through TopBP1 and Treslin

Significance Mutant form of p53 (mutp53) proteins are expressed at high levels in many human cancers and can promote tumor cell growth. However, their mechanisms of action have not been fully understood. Elucidation of the mechanisms may identify new therapeutic strategies for treating many cancers that contain mutp53s. We describe a role for several hotspot mutp53s in reducing the checkpoint response to replication stress through interacting with TopBP1. This finding provides a rationale for a synthetic lethality strategy to treat mutp53-harboring cancer cells with inhibitors of another ATR activator, DNA2. We also find that certain mutp53s directly promote DNA replication by bridging the interaction between TopBP1 and Treslin. These results uncover mechanisms by which mutp53 enhances DNA replication. Accumulating evidence supports the gain-of-function of mutant forms of p53 (mutp53s). However, whether mutp53 directly perturbs the DNA replication checkpoint remains unclear. Previously, we have demonstrated that TopBP1 forms a complex with mutp53s and mediates their gain-of-function through NF-Y and p63/p73. Akt phosphorylates TopBP1 and induces its oligomerization, which inhibits its ATR-activating function. Here we show that various contact and conformational mutp53s bypass Akt to induce TopBP1 oligomerization and attenuate ATR checkpoint response during replication stress. The effect on ATR response caused by mutp53 can be exploited in a synthetic lethality strategy, as depletion of another ATR activator, DNA2, in mutp53-R273H–expressing cancer cells renders cells hypersensitive to cisplatin. Expression of mutp53-R273H also makes cancer cells more sensitive to DNA2 depletion or DNA2 inhibitors. In addition to ATR-activating function during replication stress, TopBP1 interacts with Treslin in a Cdk-dependent manner to initiate DNA replication during normal growth. We find that mutp53 also interferes with TopBP1 replication function. Several contact, but not conformational, mutp53s enhance the interaction between TopBP1 and Treslin and promote DNA replication despite the presence of a Cdk2 inhibitor. Together, these data uncover two distinct mechanisms by which mutp53 enhances DNA replication: (i) Both contact and conformational mutp53s can bind TopBP1 and attenuate the checkpoint response to replication stress, and (ii) during normal growth, contact (but not conformational) mutp53s can override the Cdk2 requirement to promote replication by facilitating the TopBP1/Treslin interaction.

TRIP6 antagonizes the recruitment of A20 and CYLD to TRAF6 to promote the LPA2 receptor-mediated TRAF6 activation

The elevated lysophosphatidic acid signaling has been causally linked to cancer-associated inflammation and tumorigenesis through upregulation of nuclear factor-κB signaling. However, how this signaling event is regulated has not yet been fully understood. Here we demonstrate that TRIP6, an LPA2 receptor-interacting adaptor protein, functions as a positive regulator of nuclear factor-κB and JNK signaling through direct binding to and activation of the E3 ligase TRAF6. Upon lysophosphatidic acid stimulation, TRIP6 recruits TRAF6 to the LPA2 receptor and promotes lysophosphatidic acid-induced JNK and nuclear factor-κB activation in a TRAF6-dependent manner. TRIP6 antagonizes the recruitment of deubiquitinases A20 and CYLD to TRAF6, thus sustaining the E3 ligase activity of TRAF6 and augmenting lysophosphatidic acid-activated nuclear factor-κB signaling. In contrast, depletion of TRIP6 by TRIP6-specific shRNA or Cas9/sgRNA greatly enhances the association of TRAF6 with A20 and CYLD, and attenuates lysophosphatidic acid-induced muclear factor-κB and JNK/p38 activation in ovarian cancer cells. On the other hand, TRAF6 also regulates TRIP6 by facilitating its binding to nuclear factor-κB p65 and phosphorylation by c-Src. Together, TRIP6 cooperates with TRAF6 to regulate the LPA2 receptor signaling, which may ultimately contribute to chronic inflammation, apoptotic resistance and cell invasion.

Abstract POSTER-BIOL-1333: TRIP6 regulates p27KIP1 to promote ovarian tumorigenesis

Although the nuclear p27KIP1 functions as a negative regulator of G1/S cell cycle progression by binding to and inhibiting cyclin-CDK complexes, the cytosolic p27KIP1 has been shown to promote adhesion disassembly and tumor invasion. Loss of nuclear p27KIP1 and cytosolic mislocalization of p27KIP1 are frequently found during cancer progression, and these events correlate with poor clinical outcome in many types of cancers, including ovarian cancer. However, the mechanisms underlying this dysregulation are not yet fully understood. TRIP6 is an adaptor protein that is highly expressed in ovarian serous cystadenocarcinoma. It serves as a platform to recruit a number of molecules, such as NF-κB p65, c-Src, p130cas, Crk, LPA2 and Fas/CD95 receptors, to promote cell motility and antiapoptotic signaling. Using an ovarian cancer xenograft mouse model, we find that TRIP6 knockdown significantly reduces ovarian tumor proliferation. We determine that this effect is in part through the regulation of p27KIP1. Our data show that TRIP6 serves as a bridge to promote the recruitment of p27KIP1 to AKT in the cytosol. TRIP6 regulates the membrane translocation and activation of AKT, and facilitates AKT-mediated recognition and phosphorylation of p27KIP1 specifically at T157, thereby promoting the cytosolic mislocalization of p27KIP1. This is required for p27KIP1 to enhance LPA-induced ovarian cancer cell migration. TRIP6 also promotes serum-induced reduction of nuclear p27KIP1 expression through Skp2-dependent and -independent mechanisms. Consequently, knockdown of TRIP6 in ovarian cancer xenografts restores nuclear p27KIP1 expression and impairs tumor proliferation. Since the expression of TRIP6 and the activity of AKT are significantly higher in ovarian cancer, restoring the expression of nuclear p27KIP1 and inhibiting the migratory effect of phospho-T157-p27KIP1 by targeting TRIP6 may prove to be an effective approach to reduce ovarian cancer progression. Citation Format: Fang-Tsyr Lin, Victor T. G. Lin, Vivian Y. Lin, Yun-Ju Lai, Chen-Shan Chen, Kang Liu, Weei-Chin Lin. TRIP6 regulates p27KIP1 to promote ovarian tumorigenesis [abstract]. In: Proceedings of the 10th Biennial Ovarian Cancer Research Symposium; Sep 8-9, 2014; Seattle, WA. Philadelphia (PA): AACR; Clin Cancer Res 2015;21(16 Suppl):Abstract nr POSTER-BIOL-1333.

Erratum for Xiao et al., 14-3-3τ Promotes Breast Cancer Invasion and Metastasis by Inhibiting RhoGDIα

14-3-3τ is frequently overexpressed in breast cancer; however, whether it contributes to breast cancer progression remains undetermined. Here, we identify a critical role for 14-3-3τ in promoting breast cancer metastasis, in part through binding to and inhibition of RhoGDIα, a negative regulator of Rho GTPases and a metastasis suppressor. 14-3-3τ binds Ser174-phosphorylated RhoGDIα and blocks its association with Rho GTPases, thereby promoting epidermal growth factor (EGF)-induced RhoA, Rac1, and Cdc42 activation. When 14-3-3τ is overexpressed in MCF7 breast cancer cells that express 14-3-3τ at low levels, it increases motility, reduces adhesion, and promotes metastasis in mammary fat pad xenografts. On the other hand, depletion of 14-3-3τ in MCF7 cells and in an invasive cell line, MDA-MB231, inhibits Rho GTPase activation and blocks breast cancer migration and invasion. Moreover, 14-3-3τ overexpression in human breast tumors is associated with the activation of ROCK (a Rho GTPase effector), high metastatic rate, and shorter survival, underscoring a clinically significant role for 14-3-3τ in breast cancer progression. Our work indicates that 14-3-3τ is a novel therapeutic target to prevent breast cancer metastasis.