The wide and growing range of lamin B‑related diseases: from laminopathies to cancer

B-type lamins are fundamental components of the nuclear lamina, a complex structure that acts as a scafold for organization and function of the nucleus. Lamin B1 and B2, the most represented isoforms, are encoded by LMNB1 and LMNB2 gene, respectively. All B-type lamins are synthesized as precursors and undergo sequential post-translational modifcations to generate the mature protein. B-type lamins are involved in a wide range of nuclear functions, including DNA replication and repair, regulation of chromatin and nuclear stifness. Moreover, lamins B1 and B2 regulate several cellular processes, such as tissue development, cell cycle, cellular proliferation, senescence, and DNA damage response. During embryogenesis, B-type lamins are essential for organogenesis, in particular for brain development. As expected from the numerous and pivotal functions of B-type lamins, mutations in their genes or fuctuations in their expression levels are critical for the onset of several diseases. Indeed, a growing range of human disorders have been linked to lamin B1 or B2, increasing the complexity of the group of diseases collectively known as laminopathies. This review highlights the recent fndings on the biological role of B-type lamins under physiological or pathological conditions, with a particular emphasis on brain disorders and cancer

Specific ablation of phospholipase Cγ1 in forebrain causes manic-like behavior

It is well known that manic episodes are one of the major diagnostic symptoms in a spectrum of neuropsychiatric disorders that include schizophrenia, obsessive-compulsive disorder and bipolar disorder (BD). Despite a possible association between BD and the gene encoding phospholipase Cγ1 (PLCG1), its etiological basis remains unclear. Here, we report that mice lacking phospholipase Cγ1 (PLCγ1) in the forebrain (Plcg1f/f; CaMKII) exhibit hyperactivity, decreased anxiety-like behavior, reduced depressive-related behavior, hyperhedonia, hyperphagia, impaired learning and memory and exaggerated startle responses. Inhibitory transmission in hippocampal pyramidal neurons and striatal dopamine receptor D1-expressing neurons of Plcg1-deficient mice was significantly reduced. The decrease in inhibitory transmission is likely due to a reduced number of γ-aminobutyric acid (GABA)-ergic boutons, which may result from impaired localization and/or stabilization of postsynaptic CaMKII (Ca2+/calmodulin-dependent protein kinase II) at inhibitory synapses. Moreover, mutant mice display impaired brain-derived neurotrophic factor-tropomyosin receptor kinase B-dependent synaptic plasticity in the hippocampus, which could account for deficits of spatial memory. Lithium and valproate, the drugs presently used to treat mania associated with BD, rescued the hyperactive phenotypes of Plcg1f/f; CaMKII mice. These findings provide evidence that PLCγ1 is critical for synaptic function and plasticity and that the loss of PLCγ1 from the forebrain results in manic-like behavior

Nuclear DGKα regulates cell cycle progression in K562 cells

The existence of an independent nuclear inositide pathway distinct from the cytoplasmic one has been demonstrated in different physiological systems and in diseases (1). Phosphatidylinositols (PIs) play an important role in nuclear function regulation and behave differently from their counterparts in the cytoplasm. The autonomous nuclear PI cycle in eukaryotic cells is involved in different regulation processes, from cell proliferation to differentiation and many others (2). At nuclear level an array of kinases and phosphatases can modulate PIs. Among these, Diacylglycerol Kinases (DGKs) are a class of phosphotransferases that phosphorylate diacylglycerol (DAG) and induce the synthesis of phosphatidic acid. We Investigated DGKα localization and function in human erythroleukemia cell line K562. Synchronization experiments at different cell cycle checkpoints showed an important expression of DGKα in the nuclear fraction of this cell model, slightly peaking at G2/M. This suggested that DGKα might have a function in nuclear signaling. In particular, nuclear DGKα expression can modulate cell cycle progression, leading to changes in the phosphorylated status of the Retinoblastoma protein (pRb), thus, regulating G1/S transition: DGKα silencing or downregulation leads to impaired G1/S transition and its overexpression leads to S phase progression. The molecular mechanism by which nuclear DGKα controls pRb phosphorylation and therefore cell cycle regulation in K562 cell line are still unclear. Further studies are needed to better understand the role of DGKα in relation to other pivotal PIs involved in cell cycle regulation in the hematopoietic system

Phospholipase c beta 1 (PLCb1) in acute myeloid leukemia (AML): a novel potential therapeutic target

Acute myeloid leukemia (AML) is the most common type of leukemia in adults in which leukemic myeloid derived cells replace normal blood cells leading to a loss in systemic function. Once initiated the disease develops rapidly and is typically fatal within weeks or months if left untreated. AML is a complex disease and although, the exact causes of the development of AML are unknown, risk factors include age, pre-leukemic diseases such as myelodysplastic syndrome, exposure to chemicals and radiation and genetics. The mainstay treatment is still chemotherapy together with stem cell replacement therapy and while life expectancy has increased slowly, the 5 year survival rates range between 12 and 70% with relapse rates as high as 70% depending on the subtype (canceruk). These statistics illustrate the urgent requirement for the development of novel targeted therapeutics. Phospholipases C (PLC) are critical intracellular signaling enzymes that control a wide range of cellular functions including proliferation and apoptosis that have been implicated in myelodysplastic diseases and in leukemia (Faenza et al., 2013; Shah et al.). Importantly they constitute a highly druggable family of enzymes distinct from other well established drug development targets such as protein kinases. Using the human leukemic cell line THP1, we carried out a small targeted RNAi screen to establish a role of all known PLCs in cell growth, differentiation and maintenance of the transformed phenotype. We discovered that silencing of PLCb1 or PLCH2 resulted in a strong growth arrest. PLCb1 knockdown also initiated apoptosis and attenuated growth of THP1 cells in semisolid culture, which is known to reflect the ability of cells to induce leukemia in vivo. Accordingly, we found that knockdown of PLCb1 strongly attenuated THP1-mediated development of leukemia in mice. These growth inhibitory effects of PLCb1 knockdown were extended to a mouse model of human leukaemia induced by the MLL-AF9 translocation and to human primary leukemia cells. Of direct importance to the consideration for drug development we observed that PLCb1 knockdown selectively attenuated the growth of primary human AML cells, without effecting cell growth and differentiation of normal CD34+ hematopoietic stem and progenitor cells from healthy donors. We therefore propose PLCb1 as a novel candidate for a therapeutic target in AML

Epigenetic Regulation of Nuclear PI-PLC beta1 Signalling Pathway in Low-Risk MDS Patients During Azacitidine Treatment

Myelodysplastic syndromes (MDS) are a heterogeneous group of hematological malignancies characterized by epigenetic abnormalities and therefore treated with demethylating agents [1]. PI-PLCbeta1 has been reported to be a specific target for demethylating therapy in high-risk MDS patients, since azacitidine treatment can be associated with a PI-PLCbeta1 specific promoter demethylation and induction of both PI-PLCbeta1 gene and protein expression [1]. In the present study we investigated the role of epigenetic regulation of PI-PLCbeta1, mainly focusing on the functional role of azacitidine on the structure of the PI-PLCbeta1 promoter. We firstly examined the effect of azacitidine on PI-PLCbeta1 promoter methylation and gene expression in low-risk MDS. Moreover, we studied the expression of key molecules involved in the nuclear inositide signalling pathway, such as Cyclin D3. We also studied the correlation between the demethylating effect of azacitidine and the degree of recruitment to PI-PLCbeta1 promoter of some transcription factors implicated in hematopoietic stem cell proliferation and differentiation, as well as of the Methyl-CpG binding domain proteins (MBDs), which specifically interact with methylated DNA. Taken together, our results hint at a specific involvement of PI-PLCbeta1 in epigenetic mechanisms, and are particularly consistent with the hypothesis of a role for PI-PLCbeta1 in azacitidine- induced myeloid differentiation

Phosphoinositide-dependent signaling in cancer: A focus on phospholipase C isozymes

Phosphoinositides (PI) form just a minor portion of the total phospholipid content in cells but are significantly involved in cancer development and progression. In several cancer types, phosphatidylinositol 3,4,5-trisphosphate [PtdIns(3,4,5)P3] and phosphatidylinositol 4,5-bisphosphate [PtdIns(4,5)P2] play significant roles in regulating survival, proliferation, invasion, and growth of cancer cells. Phosphoinositide-specific phospholipase C (PLC) catalyze the generation of the essential second messengers diacylglycerol (DAG) and inositol 1,4,5 trisphosphate (InsP3) by hydrolyzing PtdIns(4,5)P2. DAG and InsP3 regulate Protein Kinase C (PKC) activation and the release of calcium ions (Ca2+) into the cytosol, respectively. This event leads to the control of several important biological processes implicated in cancer. PLCs have been extensively studied in cancer but their regulatory roles in the oncogenic process are not fully understood. This review aims to provide up-to-date knowledge on the involvement of PLCs in cancer. We focus specifically on PLC\u3b2, PLC\u3b3, PLC\u3b4, and PLC\u3c9 isoforms due to the numerous evidence of their involvement in various cancer types

Nuclear Inositides and Inositide-Dependent Signaling Pathways in Myelodysplastic Syndromes

Myelodysplastic syndromes (MDS) are a heterogeneous group of hematological malignancies characterized by peripheral blood cytopenia and abnormal myeloproliferation, as well as a variable risk of evolution into acute myeloid leukemia (AML). The nucleus is a highly organized organelle with several distinct domains where nuclear inositides localize to mediate essential cellular events. Nuclear inositides play a critical role in the modulation of erythropoiesis or myelopoiesis. Here, we briefly review the nuclear structure, the localization of inositides and their metabolic enzymes in subnuclear compartments, and the molecular aspects of nuclear inositides in MDS

Differential activation of nuclear inositide-dependent signalling pathways during erythropoiesis and myelopoiesis induced by lenalidomide and azacitidine in myelodysplastic syndromes (MDS)

Inositide-dependent signalling pathways regulated by phosphoinositide-specific phospholi- pase C (PI-PLC) beta1 have been demonstrated to play important roles in MDS pathogenesis and in cell differentiation (1). Moreover, the MDS therapy aims at inducing myeloid and/or erythroid differentiation of MDS stem cells. Indeed, azacitidine is a demethylating agent that can induce myeloid differentiation. On the other hand, lenalidomide may restore a normal erythropoiesis. The exact molecular mechanisms underlying the effect of azacitidine and lenalidomide in MDS cells are still unclear, although it is clear that these therapies regulate stem cell proliferation, differentiation and apoptosis (2). The combination of azacitidine and lenalidomide in MDS therapy is now under considera- tion, given the capability of both drugs to balance proliferation and differentiation processes (3). In this study we analyzed the molecular effect of this combination therapy on PI-PLC isoenzymes, not only studying PI-PLCbeta1, but also PI-PLCgamma1, that can be associated with erythropoiesis. We analyzed 44 patients diagnosed with high-risk MDS who were given azacitidine and lenalidomide. Given the limited number of cells, we quantified the expression of these molecules by Real-Time PCR analyses and immunocytochemical experiments. Moreover, we carried out cell cycle analyses and studied both PI-PLCbeta1 methylation status and the expression of Globin genes. In our case series, 28/44 patients were evaluable, with an overall response rate of 78.6% (22/28 cases). At a molecular level, a significant increase of PI-PLCbeta1 and/or PI-PLCgamma1 expression was associated with a favourable clinical response to the combination therapy. Responder cases also showed an increase of Beta-globin expression, hinting at a specific contri- bution of lenalidomide on erythroid activation, whilst the frequent demethylation of PI-PLCbeta1 promoter could be specifically linked to azacitidine. Taken together, our results show that the combination of azacitidine and lenalidomide can be important for activating PI-PLC isoenzymes, therefore regulating myeloid and erythroid dif- ferentiation in MDS cells

Response of high-risk MDS to azacitidine and lenalidomide is impacted by baseline and acquired mutations in a cluster of three inositide-specific genes

Specific myeloid-related and inositide-specific gene mutations can be linked to myelodysplastic syndromes (MDS) pathogenesis and therapy. Here, 44 higher-risk MDS patients were treated with azacitidine and lenalidomide and mutations analyses were performed at baseline and during the therapy. Results were then correlated to clinical outcome, overall survival (OS), leukemia-free-survival (LFS) and response to therapy. Collectively, 34/44 patients were considered evaluable for response, with an overall response rate of 76.25% (26/34 cases): 17 patients showed a durable response, 9 patients early lost response and 8 patients never responded. The most frequently mutated genes were ASXL1, TET2, RUNX1, and SRSF2. All patients early losing response, as well as cases never responding, acquired the same 3 point mutations during therapy, affecting respectively PIK3CD (D133E), AKT3 (D280G), and PLCG2 (Q548R) genes, that regulate cell proliferation and differentiation. Moreover, Kaplan–Meier analyses revealed that this mutated cluster was significantly associated with a shorter OS, LFS, and duration of response. All in all, a common mutated cluster affecting 3 inositide-specific genes is significantly associated with loss of response to azacitidine and lenalidomide therapy in higher risk MDS. Further studies are warranted to confirm these data and to further analyze the functional role of this 3-gene cluster

Epigenetic regulation of nuclear PLCbeta1 and Cyclin D3 during Azacitidine treatment

The Myelodysplastic Syndromes (MDS) are a heterogeneous group of bone marrow disorders characterized by alterations of the hematopoietic stem cells that lead to anemia, neutropenia, bleeding problems and infections. The evidence of a clinical correlation between the presence of a monoallelic gene deletion of Phospholipase Cβ1 (PLCβ1) and the progression of MDS to Acute Myeloid Leukemia (AML) opened new perspectives of research and treatments. Patients affected by MDS with a higher risk of AML evolution have a reduction in the expression of the nuclear PLCβ1, which is also epigenetically relevant in MDS. This strengthens the importance of PLCβ1 localization. In fact, PLCβ1 is a molecular target for hypomethylating agents, such Azacitidine (AZA)(1). High-risk MDS patients that respond to the drug showed an increased expression of nuclear PLCβ1 and its downstream target Cyclin D3 (CCND3), an induction of normal myeloid differentiation, and a better prognosis. Stemming from these data, our goal was to analyze the correlation between CCND3, PLCβ1 and AZA treatment. Firstly, we treated two different cellular lines, AML HL60 and histiocytic lymphoma U937, with AZA 5μM (Ec50 for HL60 cells) for 24 hours. Then, we used Real-Time PCR and Western blot to quantify both gene and protein expression. Moreover, we showed that CCND3 promoter has one CpG island. For this reason, it is possible that AZA could directly affect both PLCβ1 and CCND3 promoters. Therefore, we studied PLCβ1 binding to CCND3 promoter by chromatin immunoprecipitation (CHIP), before and after AZA treatment. Our results evidenced that the recruitment of PLCβ1 to CCND3 promoter is specifically increased after AZA treatment, leading to suppose that PLCβ1 could have a pivotal role in MDS with either a direct or indirect effect on cell cycle, proliferation and differentiation. These complicate relations need future deepening in order to demonstrate how PLCβ1 binding actually regulates CCND3 expression and how much this expression depends on CCND3 direct promoter demethylation and PLCβ1 control