NSC243928 Treatment Induces Anti-Tumor Immune Response in Mouse Mammary Tumor Models.

NSC243928 induces cell death in triple-negative breast cancer cells in a LY6K-dependent manner. NSC243928 has been reported as an anti-cancer agent in the NCI small molecule library. The molecular mechanism of NSC243928 as an anti-cancer agent in the treatment of tumor growth in the syngeneic mouse model has not been established. With the success of immunotherapies, novel anti-cancer drugs that may elicit an anti-tumor immune response are of high interest in the development of novel drugs to treat solid cancer. Thus, we focused on studying whether NSC243928 may elicit an anti-tumor immune response in the in vivo mammary tumor models of 4T1 and E0771. We observed that NSC243928 induced immunogenic cell death in 4T1 and E0771 cells. Furthermore, NSC243928 mounted an anti-tumor immune response by increasing immune cells such as patrolling monocytes, NKT cells, B1 cells, and decreasing PMN MDSCs in vivo. Further studies are required to understand the exact mechanism of NSC243928 action in inducing an anti-tumor immune response in vivo, which can be used to determine a molecular signature associated with NSC243928 efficacy. NSC243928 may be a good target for future immuno-oncology drug development for breast cancer.

Lymphocyte antigen 6K signaling to aurora kinase promotes advancement of the cell cycle and the growth of cancer cells, which is inhibited by LY6K-NSC243928 interaction.

Lymphocyte antigen 6K (LY6K) is a small GPI-linked protein that is normally expressed in testes. Increased expression of LY6K is significantly associated with poor survival outcomes in many solid cancers, including cancers of the breast, ovary, gastrointestinal tract, head and neck, brain, bladder, and lung. LY6K is required for ERK-AKT and TGF-ß pathways in cancer cells and is required for in vivo tumor growth. In this report, we describe a novel role for LY6K in mitosis and cytokinesis through aurora B kinase and its substrate histone H3 signaling axis. Further, we describe the structural basis of the molecular interaction of small molecule NSC243928 with LY6K protein and the disruption of LY6K-aurora B signaling in cell cycle progression due to LY6K-NSC243928 interaction. Overall, disruption of LY6K function via NSC243928 led to failed cytokinesis, multinucleated cells, DNA damage, senescence, and apoptosis of cancer cells. LY6K is not required for vital organ function, thus inhibition of LY6K signaling is an ideal therapeutic approach for hard-to-treat cancers that lack targeted therapy such as triple-negative breast cancer.

Tumor suppressive effect of lysyl oxidase proenzyme.

Lysyl oxidase acts as both a matrix modifying enzyme and an oncogene suppressor. It is synthesized as a 50-kDa proenzyme, secreted, and processed into an approximately 30 kDa mature, active enzyme and an 18-kDa propeptide. The tumor suppressive effect of lysyl oxidase appears to be exerted within the cell, so the subcellular localization of protein forms was investigated. Propeptide-specific antibody detected 50-kDa proenzyme in cytoplasmic and nuclear extracts of non-transformed mouse fibroblasts, but free 18-kDa propeptide was not detected in any extract. Antibody to epitope near the N-terminus of mature lysyl oxidase detected the proenzyme product in non-transformed cells, and a 30-kDa cytoplasmic protein in both non-transformed and transformed cells. RNA interference reduced the expression of lysyl oxidase mRNA and 50-kDa proenzyme in non-transformed cells, but had no effect on 30-kDa protein, indicating that although this protein displays a lysyl oxidase epitope, it is not derived from lysyl oxidase message. The absence of both free 18-kDa propeptide and mature lysyl oxidase within non-transformed cells suggests that cellular reversion after restoration of lysyl oxidase gene expression is mediated by the 50-kDa proenzyme within cells.

Mechanisms of deregulation of IFN regulatory factor-1 in ras-transformed fibroblasts.

Interferon (IFN) regulatory factor-1 (IRF-1) deregulation in ras-transformed mouse fibroblasts (RS485) was studied. Treatment with the proteasome inhibitor MG132 did not alter the constitutive IRF-1 protein levels in RS485 but significantly increased them in nontransformed NIH 3T3 cells at 4 h after serum stimulation of synchronized cultures. Because IRF-1 protein levels in NIH 3T3 are minimal at 4 h after serum starvation, the cyclic expression of IRF-1 in NIH 3T3 appears to be partially due to proteasome activity; however, proteasome activity in RS485 did not appear to be defective. In NIH 3T3 and RS485 cells treated with cycloheximide, there were similar rapid drops in IRF-1 protein levels, and the addition of MG132 along with cycloheximide prevented protein loss in both cell lines. Northern blot analyses of synchronized cultures showed that the IRF-1 message closely mirrored the protein expression pattern in both NIH 3T3 and RS485 cells. In synchronized cells treated with the transcription inhibitor actinomycin D, IRF-1 mRNA half-life was only marginally longer in ras-transformed fibroblasts than in the nontransformed cells, and this difference would contribute minimally to protein overexpression. These findings indicate that IRF-1 deregulation in RS485 cells occurs primarily at the transcriptional level.

Deregulated expression of interferon regulatory factor-1 in oncogene-transformed mouse fibroblasts.

Interferon (IFN) regulatory factor-1 (IRF-1) is a transcription factor that has been historically associated with type I IFN activation and antioncogenic properties. We studied IRF-1 expression and DNA-binding capacity in nontransformed and transformed mouse fibroblasts. A 43-kDa nuclear IRF-1 protein was expressed biphasically during the cell cycle in primary mouse embryo fibroblasts, nontransformed NIH 3T3 cells, and ras revertants. IRF-1 expression became constitutive in ras-transformed NIH 3T3 cells and in cells transformed by oncogenes ets, fes, fos, her-2/neu, met, mos, raf, or trk, suggesting that deregulated IRF-1 expression may be associated with loss of growth control. Lysyl oxidase (LO), a ras suppressor that is downregulated in ras transformants, is an IRF-1 target gene, but it is not stimulated by abundant IRF-1 present in transformants, while another IRF-1 target gene (iNOS) is transcribed. IRF-1 from either normal or ras-transformed cells bound to IRF elements in the IFN-beta and LO promoters. IRF-1 in transformants can, therefore, bind to but not transactivate the LO promoter, and the presence of IRF-1 is not sufficient to suppress ras transformation. LO expression may effect the regulated expression of IRF-1: a ras revertant, which was generated by stable transfection of LO cDNA, regained the normal biphasic IRF-1 pattern. A mainly cytoplasmic, constitutively expressed 46-kDa protein with immunologic identity to the 43-kDa nuclear IRF-1 was also present in normal and transformed cells, but as it did not bind to the IRF elements, its function is unclear.

H-ras localizes to cell nuclei and varies with the cell cycle.

H-Ras functions as a signal switch molecule in numerous signaling pathways in the cytoplasm, requiring H-Ras localization to the inner surface of the cytoplasmic membrane, and H-Ras is considered to be a cytoplasmic protein. Immunoblot studies of cells transformed by overexpression of c-H-ras indicated that H-Ras protein was present in both cytoplasmic and nuclear extracts, suggesting a possible correlation of nuclear H-Ras and cellular transformation. Unexpectedly, additional studies revealed that H-Ras protein was also present in the nuclei of nontransformed and primary mouse cells, which do not overexpress H-Ras. Mouse fibroblast NIH 3T3 cells, L cells, and a primary fibroblast line all had H-Ras present in both cytoplasmic and nuclear extracts. Nuclear extracts of cells synchronized by growth without serum displayed an increasing amount of H-Ras and cyclin D1 as cells grew after serum addition. Treatment with farnesyltransferase inhibitor caused loss of H-Ras from the nucleus. Immunofluorescence in situ studies of nuclei from synchronized cultures showed that H-Ras protein appeared in and disappeared from the nuclei as the cells moved through the growth cycle. This cycling occurred in both nontransformed and ras-transformed cells. Flow cytometry measurements on parallel cultures revealed that the time point at which the greatest percentage of cells were in S phase, for each line, corresponded to appearance of a noticeably stronger in situ signal for H-Ras. H-Ras may participate in nuclear signaling pathways associated with replication in addition to its cytoplasmic signaling functions.

Treatment of hepatitis C infections with interferon: a historical perspective.

Interferons were first described in 1957, but it was not until 34 years after their discovery that sufficient quantities of it were available for treatment of hepatitis C virus (HCV) infections, Clinicians now have an excellent understanding of the basis for the effectiveness of interferon alpha (IFN-α) in the therapy of this disease. Treatment with IFN-α is more efficient when it complemented by the antiviral ribavirin and the IFN-α is conjugated with polyethylene glycol to form peginterferon. In the near future treatment of HCV with IFN-α may involve new anti-HCV agents that are currently under development.

Interferons as Therapy for Viral and Neoplastic Diseases: From Panacea to Pariah to Paragon.

For more than 20 years after the excitement engendered by their discovery in 1957 as antiviral agents, there were no significant clinical uses of interferons; however, following their cloning they have been employed as effective treatment for several viral, autoimmune, and neoplastic diseases.

Identification of proteins immunologically related to interferon regulatory factor-1 that bind with interferon regulatory factor element.

Interferon regulatory factor (IRF)-1 expression was surveyed in nontransformed and oncogene-transformed mouse fibroblasts, using Western immunoblot with an IRF-1-specific antiserum, to examine possible differences resulting from cellular transformation. Ten additional proteins that reacted with the IRF-1 antibody and that underwent specific competition by peptide antigen were observed in extracts of both nontransformed and oncogene-transformed cell lines. Cross-reacting proteins were also observed in mouse macrophage extracts. Protein was captured from fibroblast nuclear extracts, using oligonucleotides representing IRF-binding sequences linked to magnetic beads. Captured proteins were eluted and analyzed by immunoblot with anti-IRF-1. Along with 43-kDa IRF-1, 4 of the 7 nuclearly located cross-reacting proteins (97, 90, 66, and 33 kDa) were found to complex with the IRF binding element. These proteins, with an epitope in common with the IRF-1 C-terminal region and IRF element DNA sequence-binding capability, may represent new members of the IRF family.

Transformation of revertant murine cells by 5-azacytidine results in rapid inhibition of lysyl oxidase expression.

Lysyl oxidase (LO) is synthesized intracellularly as a proenzyme that is secreted and then processed extracellularly to a mature form. LO is expressed in NIH3T3 cells, but only very low levels are observed after NIH 3T3 is transformed by c-H-ras or one of several other oncogenes. LO functions as a tumor suppressor. Treatment of ras-transformed cells with interferon-alpha with or without retinoic acid results in their persistent reversion to a non-transformed state that is dependent on the restoration of LO expression. When such revertant cells are treated with 5-azacytidine (5-azaC), they undergo rapid morphological retransformation. Within one passage after addition of 5-azaC, there was a down regulation of LO mRNA and proenzyme protein. These data suggest a direct relationship between the transformed state and LO expression.