Intrinsic S phase checkpoint enforced by an antiproliferative oncosuppressor cytokine.

The cell cycle is strictly programmed with control mechanisms that dictate order in cell cycle progression to ensure faithful DNA replication, whose deviance may lead to cancer. Checkpoint control at the G1/S, S/G2 and G2/M portals have been defined but no statutory time-programmed control for securing orderly transition through S phase has so far been identified. Here we report that in normal cells DNA synthesis is controlled by a checkpoint sited within the early part of S phase, enforced by the ßGBP cytokine an antiproliferative molecule otherwise known for its oncosuppressor properties that normal cells constitutively produce for self-regulation. Suppression of active Ras and active MAPK, block of cyclin A gene expression and suppression of CDK2-cyclin A activity are events which while specific to the control of a cell cycle phase in normal cells are part of the apoptotic network in cancer cells.

Sourcing the immune system to induce immunogenic cell death in Kras-colorectal cancer cells.

BACKGROUND: Current approaches aimed at inducing immunogenic cell death (ICD) to incite an immune response against cancer neoantigens are based on the use of chemotherapeutics and other agents. Results are hampered by issues of efficacy, combinatorial approaches, dosing and toxicity. Here, we adopted a strategy based on the use of an immunomolecule that overcomes pharmachemical limitations. METHODS: Cytofluorometry, electron microscopy, RT-PCR, western blotting, apotome immunofluorescence, MLR and xenografts. RESULTS: We report that an ICD process can be activated without the use of pharmacological compounds. We show that in Kras-mut/TP53-mut colorectal cancer cells the 15 kDa ßGBP cytokine, a T cell effector with onco-suppressor properties and a potential role in cancer immunosurveillance, induces key canonical events required for ICD induction. We document ER stress, autophagy that extends from cancer cells to the corresponding xenograft tumours, CRT cell surface shifting, ATP release and evidence of dendritic cell activation, a process required for priming cytotoxic T cells into a specific anticancer immunogenic response. CONCLUSIONS: Our findings provide experimental evidence for a rationale to explore a strategy based on the use of an immunomolecule that as a single agent couples oncosuppression with the activation of procedures necessary for the induction of long term response to cancer.

The end of KRAS, and other, cancers? A new way forward.

Mutant KRAS, as well as other mutant driver genes and epidriver genes, is a dominant determinant of resistance to cancer therapeutics. The recent introduction of targeting therapies based on drugs that inhibit the kinase catalytic function of nodal points along the Ras/extracellular-signal-regulated kinase (ERK) and the phosphatidylinositol-3-kinase (PI3K)/Akt cascades is meeting with limited success. Against this background, recent evidence shows that the ß-galactoside-binding protein (ßGBP) molecule, a physiological PI3K inhibitor, is a potent inducer of apoptosis in KRAS-mutant cancer cells (along with other aggressive cancer cells of different genetic makeup) and that it is therapeutically effective in vivo. Absence of p53 or phosphatase and tensin homolog (PTEN) tumor suppressor function or added activating PI3K mutations does not affect ßGBP function. In contrast to the concept of one drug against one target, ßGBP operates through alternative physiological routes.

Killing of Kras-mutant colon cancer cells via Rac-independent actin remodeling by the ßGBP cytokine, a physiological PI3K inhibitor therapeutically effective in vivo.

Activating mutations in Kras are the most frequent mutations in human cancer. They define a subset of patients who do not respond to current therapies and for whom prognosis is poor. Oncogenic Kras has been shown to deregulate numerous signaling pathways of which the most intensively studied are the Ras/extracellular signal-regulated kinase cascade and the phosphoinositide 3-kinase (PI3K)/Akt cascade. However, to date, there are no effective targeted therapies in the clinic against Kras-mutant cancers. Here, we report that the ß-galactoside-binding protein (ßGBP) cytokine, a physiologic inhibitor of class I PI3Ks, is a potent activator of apoptosis in Kras-mutant colorectal cancer cells, even when coharboring mutant-activated PIK3CA. Our study unveils an elective route to intrinsic and extrinsic apoptosis, which involves the cytoskeleton. Early events are inhibition of PI3K activity and Rac-independent actin rearrangement assignable to phosphoinositide changes at the plasma membrane. Cyclin E deregulation, arrest of DNA synthesis, and checkpoint kinase 2 activation underscore events critical to the activation of an intrinsic apoptotic program. Clustering of CD95/Fas death receptors underscore events critical to the activation of extrinsic apoptosis. In nude mice, we present the first evidence that xenograft tumor development is strongly inhibited by Hu-r-ßGBP. Taken together, our results open a new therapeutic opportunity to a subset of patients refractive to current treatments. This first demonstration of therapeutic efficacy against Kras-mutant colon cancer suggests that Hu-r-ßGBP may also be therapeutically effective against other cancers harboring activating Ras mutations as well as PIK3CA mutations.

Tregs utilize beta-galactoside-binding protein to transiently inhibit PI3K/p21ras activity of human CD8+ T cells to block their TCR-mediated ERK activity and proliferation.

Regulatory T cells (Tregs) and beta-galactoside-binding protein (betaGBP), a regulatory protein often found expressed at sites of immunological privilege, have similar functions. Their presence affects the outcome of harmful autoimmunity and cancers, including experimental autoimmune encephalomyelitis and malignant gliomas. Here we report a novel pathway by which Tregs express and utilize betaGBP to control CD8(+) T cell responses partially activating TCR signaling but blocking PI3K activity. As a result, this leads to a loss of p21(ras), ERK and Akt activities despite activation of TCR proximal signals, such as phosphorylation of CD3zeta, Zap70, Lat and PKCtheta. Although non-processive TCR signaling often leads to cell anergy, Tregs/betaGBP did not affect cell viability. Instead, betaGBP/Tregs transiently prevented activation of CD8(+) T cells with self-antigens, while keeping their responses to xenogeneic antigens unaffected.

Phosphoinositide 3-kinase targeting by the beta galactoside binding protein cytokine negates akt gene expression and leads aggressive breast cancer cells to apoptotic death.

INTRODUCTION: Phosphoinositide 3-kinase (PI3K)-activated signalling has a critical role in the evolution of aggressive tumourigenesis and is therefore a prime target for anticancer therapy. Previously we have shown that the beta galactoside binding protein (betaGBP) cytokine, an antiproliferative molecule, induces functional inhibition of class 1A and class 1B PI3K. Here, we have investigated whether, by targeting PI3K, betaGBP has therapeutic efficacy in aggressive breast cancer cells where strong mitogenic input is fuelled by overexpression of the ErbB2 (also known as HER/neu, for human epidermal growth factor receptor 2) oncoprotein receptor and have used immortalised ductal cells and non-aggressive mammary cancer cells, which express ErbB2 at low levels, as controls. METHODS: Aggressive BT474 and SKBR3 cancer cells where ErbB2 is overexpressed, MCF10A immortalised ductal cells and non-invasive MCF-7 cancer cells which express low levels of ErbB2, both in their naive state and when forced to mimic aggressive behaviour, were used. Class IA PI3K was immunoprecipitated and the conversion of phosphatidylinositol (4,5)-biphosphate (PIP2) to phosphatidylinositol (3,4,5)-trisphosphate (PIP3) assessed by ELISA. The consequences of PI3K inhibition by betaGBP were analysed at proliferation level, by extracellular signal-regulated kinase (ERK) activation, by akt gene expression and by apoptosis. Apoptosis was documented by changes in mitochondrial membrane potential, alteration of the plasma membrane, caspase 3 activation and DNA fragmentation. Phosphorylated and total ERK were measured by Western blot analysis and akt mRNA levels by Northern blot analysis. The results obtained with the BT474 and SKBR3 cells were validated in the MCF10A ductal cells and in non-invasive MCF-7 breast cancer cells forced into mimicking the in vitro behaviour of the BT474 and SKBR3 cells. RESULTS: In aggressive breast cancer cells, where mitogenic signalling is enforced by the ErbB2 oncoprotein receptor, functional inhibition of the catalytic activity of PI3K by the betaGBP cytokine and loss of akt mRNA results in apoptotic death. A functional correlation between ERK and the kt gene was also found. The relationship between ERK, akt mRNA, PI3K and cell vulnerability to betaGBP challenge was sustained both in mammary ductal cells forced to mimic an aggressive behaviour and in non-aggressive breast cancer cells undergoing an enforced shift into an aggressive phenotype. CONCLUSIONS: betaGBP, a newly discovered physiological inhibitor of PI3K, is a selective and potent inducer of apoptosis in aggressive breast cancer cells. Due to its physiological nature, which carries no chemotherapeutic disadvantages, betaGBP has the potential to be safely tested in clinical trials.

Potential role of the antiproliferative cytokine beta-galactoside binding protein in cancer therapy.

This review highlights the discovery of beta-galactoside binding protein (betaGBP), an antiproliferative cytokine, as a potent and selective anticancer agent. Unlike drugs designed to block receptor tyrosine kinases or specific control points along signaling pathways, betaGBP does not harm normal cells. As a physiological effector molecule, betaGBP can selectively induce death in cancer cells by enforcing its regulatory functions to which normal and cancer cells respond differently, and thus exploit the genetic and molecular deviations developed by cancer cells.

Circumventing multidrug resistance in cancer by beta-galactoside binding protein, an antiproliferative cytokine.

We report here that beta-galactoside binding protein (betaGBP), an antiproliferative cytokine which can program cancer cells to undergo apoptosis, exhibits equal therapeutic efficacy against cancer cells that display diverse mechanisms of drug resistance and against their parental cells. The mechanisms of drug resistance in the cancer cells that we have examined include overexpression of P-glycoprotein, increased efficiency of DNA repair, and altered expression and mutation in the topoisomerase I and II enzymes. We also report that betaGBP exerted its effect by arresting the cells in S phase prior to the activation of programmed cell death. The uniquely similar profile of response to betaGBP by these drug-resistant cells and their parental cells extends the therapeutic potential of this cytokine in the treatment of cancers and offers a promising alternative to patients whose tumors are refractory to the currently available cadre of chemotherapeutic agents.

Turning cell cycle controller genes into cancer drugs. A role for an antiproliferative cytokine (betaGBP).

Cancer therapies based on drugs designed to interfere with specific targets within the molecular circuitry of cancer cells are currently under intense experimentation. Our strategy is based on the use of a naturally occurring immunomolecule which can selectively kill cancer cells, based on its ability to exploit genetic differences between normal and cancer cells. The betaGBP cytokine has previously been shown to negatively regulate the cell cycle by blocking cells in late S phase. In tumour cells, but not in normal cells, the S phase block has been shown to be followed by apoptosis. Mechanisms involved in S phase arrest have been pinpointed to downregulation of signalling and altered expression of cell cycle controller proteins, including E2F1, a transcription factor with ability to play a part in apoptosis. Here we discuss the use of betaGBP within the context of cancer surveillance and cancer therapeutics focussing on E2F1 as one mechanistic aspect relevant to betaGBP's selective induction of programmed cell death in cancer.