FCHSD2 predicts response to chemotherapy in acute myeloid leukemia patients.

Acute myeloid leukemia (AML) is characterized by the growth and accumulation of cells blocked in their ability to differentiate, and blocks production of normal blood cells. The response to induction chemotherapy is heterogeneous, therefore biomarkers that predict for the outcome of such treatment are of potential value. FCHSD2 in a sensitized screen was identified as a potential chemo-protector (TW Mak, unpublished). In the present study, we found that FCHSD2 knockdown by shRNA could enhance chemosensitivity of U937 cells. This coincided with the increased expression of p21 and PUMA as well as the decreased expression of Bcl-2, c-myc and hTERT. In contrast, over-expression of FCHSD2 significantly increased cellular chemoresistance. To see if there was potential clinical relevance of FCHSD2 expression in leukemia we used qRT-PCR to assess FCHSD2 expression levels in peripheral blood or bone marrow blasts of 71 AML patients. There was an inverse correlation between the level of FCHSD2 with overall survival time (r=-0.7647, p<0.0001) and relapse free time (r=-0.8165, p<0.0001). By dividing patients into high and low expression groups using a FCHSD2 expression threshold value of 0.001, the median survival of the high expression group (72 days) was shorter than in the low expression group (2472 days). The average FCHSD2 expression level in 41 patients with complete remission was significantly lower than that in 30 non-responder patients (p<0.0001). Moreover, in 32 de novo AML patients receiving initial remission-induction chemotherapy, we confirmed that the patients with lower FCHSD2 expression prior to the treatment had an increased chance of attaining remission compared to patients with high level FCHSD2. In conclusion, our study, for the first time, demonstrates FCHSD2 as a predictor of outcome for AML patient. The determination of FCHSD2 expression at the time of diagnosis could help to identify the responses of AML patients to chemotherapy.

HUNK suppresses metastasis of basal type breast cancers by disrupting the interaction between PP2A and cofilin-1.

Metastasis leads to the death of most cancer patients, and basal breast cancer is the most aggressive breast tumor type. Metastasis involves a complex cell migration process dependent on cytoskeletal remodeling such that targeting such remodeling in tumor cells could be clinically beneficial. Here we show that Hormonally Up-regulated Neu-associated Kinase (HUNK) is dramatically down-regulated in tumor samples and cell lines derived from basal breast cancers. Reconstitution of HUNK expression in basal breast cancer cell lines blocked actin polymerization and reduced cell motility, resulting in decreased metastases in two in vivo murine cancer models. Mechanistically, HUNK overexpression sustained the constitutive phosphorylation and inactivation of cofilin-1 (CFL-1), thereby blocking the incorporation of new actin monomers into actin filaments. HUNK reconstitution in basal breast cancer cell lines prevented protein phosphatase 2-A (PP2A), a phosphatase putatively acting on CFL-1, from binding to CFL-1. Our investigation of HUNK suggests that the interaction between PP2A and CFL-1 may be a target for antimetastasis therapy, particularly for basal breast cancers.

The development of inflammatory T(H)-17 cells requires interferon-regulatory factor 4.

Interferon-regulatory factor 4 (IRF4) is essential for the development of T helper type 2 cells. Here we show that IRF4 is also critical for the generation of interleukin 17-producing T helper cells (T(H)-17 cells), which are associated with experimental autoimmune encephalomyelitis. IRF4-deficient (Irf4(-/-)) mice did not develop experimental autoimmune encephalomyelitis, and T helper cells from such mice failed to differentiate into T(H)-17 cells. Transfer of wild-type T helper cells into Irf4(-/-) mice rendered the mice susceptible to experimental autoimmune encephalomyelitis. Irf4(-/-) T helper cells had less expression of RORgammat and more expression of Foxp3, transcription factors important for the differentiation of T(H)-17 and regulatory T cells, respectively. Altered regulation of both transcription factors contributed to the phenotype of Irf4(-/-) T helper cells. Our data position IRF4 at the center of T helper cell development, influencing not only T helper type 2 but also T(H)-17 differentiation.

Abelson-interactor-1 promotes WAVE2 membrane translocation and Abelson-mediated tyrosine phosphorylation required for WAVE2 activation.

WAVE2 is a member of the Wiskott-Aldrich syndrome protein family of cytoskeletal regulatory proteins shown to link Rac activation to actin remodeling via induction of Arp 2/3 activity. WAVE2 is thought to be regulated by its positioning in a macromolecular complex also containing the Abelson-(Abl) interactor-1 (Abi-1) adaptor, but the molecular basis and biologic relevance of WAVE2 inclusion in this complex are ill defined. Here we show that Abi-1 binding to WAVE2 is mediated by discrete motifs in the Abi-1 coiled-coil and WAVE2 WAVE-homology domains and increases markedly in conjunction with Abi-1-WAVE2 translocation and colocalization at the leading edge in B16F1 cells after fibronectin stimulation. Abi-1 also couples WAVE2 to Abl after cell stimulation, an interaction that triggers Abl membrane translocation with WAVE2, Abi-1, and activated Rac, as well as Abl-mediated tyrosine phosphorylation and WAVE2 activation. By contrast, mutation of tyrosine residue Y150, identified here as the major site of Abl-mediated WAVE2 tyrosine phosphorylation, as well as disruption of WAVE2-Abi-1 binding, impairs induction of WAVE2-driven actin polymerization and its membrane translocation in association with activated Rac. Similarly, WAVE2 tyrosine phosphorylation and induction of membrane actin rearrangement are abrogated in fibroblasts lacking the Abl family kinase. Together, these data reveal that Abi-1-mediated coupling of Abl to WAVE2 promotes Abl-evoked WAVE2 tyrosine phosphorylation required to link WAVE2 with activated Rac and with actin polymerization and remodeling at the cell periphery.

ICA69(null) nonobese diabetic mice develop diabetes, but resist disease acceleration by cyclophosphamide.

ICA69 (islet cell Ag 69 kDa) is a diabetes-associated autoantigen with high expression levels in beta cells and brain. Its function is unknown, but knockout of its Caenorhabditis elegans homologue, ric-19, compromised neurotransmission. We disrupted the murine gene, ica-1, in 129-strain mice. These animals aged normally, but speed-congenic ICA69(null) nonobese diabetic (NOD) mice developed mid-life lethality, reminiscent of NOD-specific, late lethal seizures in glutamic acid decarboxylase 65-deficient mice. In contrast to wild-type and heterozygous animals, ICA69(null) NOD congenics fail to generate, even after immunization, cross-reactive T cells that recognize the dominant Tep69 epitope in ICA69, and its environmental mimicry Ag, the ABBOS epitope in BSA. This antigenic mimicry is thus driven by the endogenous self Ag, and not initiated by the environmental mimic. Insulitis, spontaneous, and adoptively transferred diabetes develop normally in ICA69(null) NOD congenics. Like glutamic acid decarboxylase 65, ICA69 is not an obligate autoantigen in diabetes. Unexpectedly, ICA69(null) NOD mice were resistant to cyclophosphamide (CY)-accelerated diabetes. Transplantation experiments with hemopoietic and islet tissue linked CY resistance to ICA69 deficiency in islets. CY-accelerated diabetes involves not only ablation of lymphoid cells, but ICA69-dependent drug toxicity in beta cells that boosts autoreactivity in the regenerating lymphoid system.