Nuclear expression of diacylglycerol kinases: possible involvement in DNA replication

The existence of intranuclear lipid-dependent signal transduction systems has been demonstrated by several independent groups. Remarkably, intranuclear lipid-dependent signal transduction pathways are regulated independently from their membrane/cytosolic counterparts. A sizable body of evidence suggests that nuclear lipid signaling controls critical biological functions such as cell proliferation, differentiation, and apoptosis. Diacylglycerol (DG) is a fundamental lipid second messenger which is produced in the nucleus. Since the levels of nuclear DG fluctuate during the cell cycle progression, it has been suggested that this lipid second messenger has important regulatory roles. Most likely, nuclear DG serves as a chemoattractant for some isoforms of protein kinase C that migrate to the nucleus in response to a variety of agonists. The nucleus also contains diacylglycerol kinases (DGKs), i.e. the enzymes that, by converting DG into phosphatidic acid (PA), terminate DG-dependent events. This review aims at highlighting the different isozymes of DGKs present within the nucleus as well as at discussing their potential functions with particular emphasis placed on DNA replication.     

Nuclear diacylglycerol kinase-theta is activated in response to alpha-thrombin

Currently, there is substantial evidence that nuclear lipid metabolism plays a critical role in a number of signal transduction cascades. Previous work from our laboratory showed that stimulation of quiescent fibroblasts with alpha-thrombin leads to the production of two lipid second messengers in the nucleus: an increase in nuclear diacylglycerol mass and an activation of phospholipase D, which catalyzes the hydrolysis of phosphatidylcholine to generate phosphatidic acid. Diacylglycerol kinase (DGK) catalyzes the conversion of diacylglycerol to phosphatidic acid, making it an attractive candidate for a signal transduction component. There is substantial evidence that this activity is indeed regulated in a number of signaling cascades (reviewed by van Blitterswijk, W. J., and Houssa, B. (1999) Chem. Phys. Lipids 98, 95-108). In this report, we show that the addition of alpha-thrombin to quiescent IIC9 fibroblasts results in an increase in nuclear DGK activity. The examination of nuclei isolated from quiescent IIC9 cells indicates that DGK-theta and DGK-delta are both present. We took advantage of the previous observations that phosphatidylserine inhibits DGK-delta (reviewed by Sakane, F., Imai, S., Kai, M., Wada, I., and Kanoh, H. (1996) J. Biol. Chem. 271, 8394-8401), and constitutively active RhoA inhibits DGK-theta (reviewed by Houssa, B., de Widt, J., Kranenburg, O., Moolenaar, W. H., and van Blitterswijk, W. J. (1999) J. Biol. Chem. 274, 6820-6822) to identify the activity induced by alpha-thrombin. Constitutively active RhoA inhibited the nuclear stimulated activity, whereas phosphatidylserine did not have an inhibitory effect. In addition, a monoclonal anti-DGK-theta antibody inhibited the alpha-thrombin-stimulated nuclear activity in vitro. These results demonstrate that DGK-theta is the isoform responsive to alpha-thrombin stimulation. Western blot and immunofluorescence microscopy analyses showed that alpha-thrombin induced the translocation of DGK-theta to the nucleus, implicating that this translocation is at least partly responsible for the increased nuclear activity. Taken together, these data are the first to demonstrate an agonist-induced activity of nuclear DGK-theta activity and a nuclear localization of DGK-delta.     

核受体与脂质代谢

核受体是配体活化的转录因子,能调控大量的靶基因。近年来核受体调节脂质代谢的研究已成为国内外研究的热点。由于核受体在调节脂质代谢、糖代谢以及炎症反应方面发挥重要作用,它们是治疗心血管疾病理想的靶标。本文简要地介绍了核受体在调节脂质代谢方面的研究进展。     

Nuclear inositol lipid signaling and its potential involvement in malignant transformation

Growth, differentiation, and apoptosis of eukaryotic cells are mediated by extremely complex signaling pathways and a high degree of coordination is required for regulating cell proliferation.In multicellular organisms homeostasis is achieved through signal transduction events. If these homeostatic mechanisms are interrupted, a disease, such as cancer, may ensue. Lipid second messengers, particularly those derived from polyphosphoinositide cycle, play a pivotal role in several cell signaling networks. Evidence accumulated over the past 15 years has highlighted the presence of an autonomous nuclear inositol lipid metabolism, and suggests that lipid signaling molecules are important components of signaling pathways operating within the nucleus. Recent findings are starting to elucidate how the nuclear phosphoinositide cycle is regulated and what down-stream molecules are targeted through this cycle. In this review, we shall summarize the most updated data about inositol lipid-dependent nuclear signaling pathways that might have a relevance for the development of cancer. In the near future, this knowledge might also prove to have relevance for the diagnosis and treatment of the neoplastic disease.     

Nuclear lipids: New functions for old molecules?

It is becoming increasingly evident that stimulation of nuclear lipid metabolism plays a central role in many signal transduction pathways that ultimately result in various cell responses including proliferation and differentiation. Nuclear lipid metabolism seems to be at least as complex as that existing at the plasma membrane. However, a distinctive feature of nuclear lipid biochemical pathways is their operational independence from their cell periphery counterparts. Although initially it was thought that nuclear lipids would serve as a source for second messengers, recent evidence points to the likelihood that lipids present in the nucleus also fulfil other roles. The aim of this review is to highlight the most intriguing advances made in the field over the last year, such as the production of new probes for the in situ mapping of nuclear phosphoinositides, the identification of two sources for nuclear diacylglycerol production, the emerging details about the peculiar regulation of nuclear phosphoinositide synthesizing enzymes, and the distinct possibility that nuclear lipids are involved in processes such as chromatin organization and pre-mRNA splicing.     

Nuclear inositide signaling in myelodysplastic syndromes

Myelodysplastic syndromes (MDS) are defined as clonal hematopoietic stem‐cell disorders characterized by ineffective hematopoiesis in one or more of the lineages of the bone marrow. Although distinct morphologic subgroups exist, the natural history of MDS is progression to acute myeloid leukemia (AML). However, the molecular the mechanisms the underlying MDS evolution to AML are not completely understood. Inositides are key cellular second messengers with well‐established roles in signal transduction pathways, and nuclear metabolism elicited by phosphoinositide‐specific phospholipase C (PI‐PLC) β1 and Akt plays an important role in the control of the balance between cell cycle progression and apoptosis in both normal and pathologic conditions. Recent findings evidenced the role played by nuclear lipid signaling pathways, which could become promising therapeutic targets in MDS. This review will provide a concise and updated revision of the state of art on this topic. J. Cell. Biochem. 109: 1065–1071, 2010. © 2010 Wiley‐Liss, Inc.     

脂滴:与肿瘤发展密切相关的特殊细胞器

脂滴(Lipid droplet,LD)存在于从酵母菌到人类的大多数细胞中,是储存中性脂的主要场所。近年来提出脂滴是一种高度活跃的细胞脂类代谢细胞器,是脂质代谢、转运以及信号传递的主要调控因子。脂滴作为脂质中心,可以参与细胞内的脂质合成与代谢,其代谢与肿瘤密切联系在一起,并在各种肿瘤细胞中大量积累。本文从脂滴的生物发生、结构和功能等方面进行了详细的描述,进一步探讨了脂滴在不同类型肿瘤发展过程中的作用,以期为肿瘤的临床诊疗提供参考依据。     

Nuclear phosphoinositide kinases and inositol phospholipids

The presence of inositol phospholipids in the nuclei of mammalian cells has by now been well established, as has the presence of the enzymes responsible for their metabolism. However, our understanding of the role of these nuclear phosphoinositides in regulating cellular events has lagged far behind that for its cytosolic counterpart. It is clear, though, that the nuclear phosphoinositide pool is independent of the cytosolic pool and is, therefore, likely to be regulating a unique set of cellular events. As with its cytosolic phosphoinositides, many nuclear phosphoinositides and their metabolic enzymes are located at distinct sub-cellular structures. This arrangement spatially limits the production and activity of inositol phospholipids and is believed to be a major mechanism for regulating their function. Here, we will introduce the components of nuclear inositol phospholipid signal transduction and discuss how their spatial arrangement may dictate which nuclear functions they are modulating.     

Nuclear lipid metabolism and signaling

Evidence has been accumulating that nuclear lipid metabolism is involved in the regulation of nuclear functions. Here I describe an autonomous nuclear lipid signaling that has been found to be associated with the metabolism of such lipids as phosphoinositides, choline phospholipids, and the acylation and deacylation cycle. Some lipid signals from the plasma membrane ultimately reach the nucleus and regulate the nuclear function. In this case, however, generated lipids and their metabolites may not directly act on the nuclear factors involved in nuclear function. The unique and direct effects of nuclear lipids and their metabolites on nuclear factors are also discussed.     

Bioactive lipids in cancer stem cells

Tumours are known to be a heterogeneous group of cells, which is why they are difficult to eradicate. One possible cause for this is the existence of slow-cycling cancer stem cells (CSCs) endowed with stem cell-like properties of self-renewal, which are responsible for resistance to chemotherapy and radiotherapy. In recent years, the role of lipid metabolism has garnered increasing attention in cancer. Specifically, the key roles of enzymes such as stearoyl-CoA desaturase-1 and 3-hydroxy-3-methyl-glutaryl-coenzyme A reductase in CSCs, have gained particular interest. However, despite accumulating evidence on the role of proteins in controlling lipid metabolism, very little is known about the specific role played by lipid products in CSCs. This review highlights recent findings on the role of lipid metabolism in CSCs, focusing on the specific mechanism by which bioactive lipids regulate the fate of CSCs and their involvement in signal transduction pathways.     

Phosphatidylinositol transfer proteins: negotiating the regulatory interface between lipid metabolism and lipid signaling in diverse cellular processes

Phosphoinositides represent only a small percentage of the total cellular lipid pool. Yet, these molecules play crucial roles in diverse intracellular processes such as signal transduction at membrane-cytosol interface, regulation of membrane trafficking, cytoskeleton organization, nuclear events, and the permeability and transport functions of the membrane. A central principle in such lipid-mediated signaling is the appropriate coordination of these events. Such an intricate coordination demands fine spatial and temporal control of lipid metabolism and organization, and consistent mechanisms for specifically coupling these parameters to dedicated physiological processes. In that regard, recent studies have identified Sec14-like phosphatidylcholine transfer protein (PITPs) as "coincidence detectors," which spatially and temporally link the diverse aspects of the cellular lipid metabolome with phosphoinositide signaling. The integral role of PITPs in eukaryotic signal transduction design is amply demonstrated by the mammalian diseases associated with the derangements in the function of these proteins, to stress response and developmental regulation in plants, to fungal dimorphism and pathogenicity, to membrane trafficking in yeast, and higher eukaryotes. This review updates the recent advances made in the understanding of how these proteins, specifically PITPs of the Sec14-protein superfamily, operate at the molecular level and further describes how this knowledge has advanced our perception on the diverse biological functions of PITPs.     

An Integrated Model of Eicosanoid Metabolism and Signaling Based on Lipidomics Flux Analysis

There is increasing evidence for a major and critical involvement of lipids in signal transduction and cellular trafficking, and this has motivated large-scale studies on lipid pathways. The Lipid Metabolites and Pathways Strategy consortium is actively investigating lipid metabolism in mammalian cells and has made available time-course data on various lipids in response to treatment with KDO₂-lipid A (a lipopolysaccharide analog) of macrophage RAW 264.7 cells. The lipids known as eicosanoids play an important role in inflammation. We have reconstructed an integrated network of eicosanoid metabolism and signaling based on the KEGG pathway database and the literature and have developed a kinetic model. A matrix-based approach was used to estimate the rate constants from experimental data and these were further refined using generalized constrained nonlinear optimization. The resulting model fits the experimental data well for all species, and simulated enzyme activities were similar to their literature values. The quantitative model for eicosanoid metabolism that we have developed can be used to design experimental studies utilizing genetic and pharmacological perturbations to probe fluxes in lipid pathways.     

Nuclear diacylglycerol kinases: emerging downstream regulators in cell signaling networks

There exists an active lipid metabolism in the nucleus, which is regulated differentially from the lipid metabolism taking place elsewhere in the cell. Evidence has been accumulated that nuclear lipid metabolism is closely involved in a variety of cell responses, including proliferation, differentiation, and apoptosis. A fundamental lipid second messenger which is generated in the nucleus is diacylglycerol, that is mainly known for its role as an activator of some protein kinase C isoforms. Diacylglycerol kinases attenuate diacylglycerol signaling by converting this lipid to phosphatidic acid, which also has signaling functions. Ten mammalian diacylglycerol kinase isoforms have been cloned so far, and some of them are found also in the nucleus, either as resident proteins or after migration from cytoplasm in response to various agonists. Experiments using cultured cells have demonstrated that nuclear diacylglycerol kinases have prominent roles in cell cycle regulation and differentiation. In this review, the emerging roles played by diacylglycerol kinases in the nucleus, such as the control of G1/S phase transition, are discussed.     

Nuclear receptors in renal disease

Diabetes is the leading cause of end-stage renal disease in developed countries. In spite of excellent glucose and blood pressure control, including administration of angiotensin converting enzyme inhibitors and/or angiotensin II receptor blockers, diabetic nephropathy still develops and progresses. The development of additional protective therapeutic interventions is, therefore, a major priority. Nuclear hormone receptors regulate carbohydrate metabolism, lipid metabolism, the immune response, and inflammation. These receptors also modulate the development of fibrosis. As a result of their diverse biological effects, nuclear hormone receptors have become major pharmaceutical targets for the treatment of metabolic diseases. The increasing prevalence of diabetic nephropathy has led intense investigation into the role that nuclear hormone receptors may have in slowing or preventing the progression of renal disease. This role of nuclear hormone receptors would be associated with improvements in metabolism, the immune response, and inflammation. Several nuclear receptor activating ligands (agonists) have been shown to have a renal protective effect in the context of diabetic nephropathy. This review will discuss the evidence regarding the beneficial effects of the activation of several nuclear, especially the vitamin D receptor (VDR), farnesoid X receptor (FXR), and peroxisome-proliferator-associated receptors (PPARs) in preventing the progression of diabetic nephropathy and describe how the discovery and development of compounds that modulate the activity of nuclear hormone receptors may provide potential additional therapeutic approaches in the management of diabetic nephropathy. This article is part of a Special Issue entitled: Translating nuclear receptors from health to disease.     

Nuclear localization activity of phytochrome B

Phytochromes are soluble red/far-red-light photoreceptor proteins which mediate various photomorphogenic responses of plants. Despite much effort, the signal transduction mechanism of phytochrome has remained obscure. Phytochromes are encoded by a small multigene family in Arabidopsis . Among the members of the family, phytochrome A (phyA) and B (phyB) are the best characterized. PhyB contains putative nuclear localization signals within its C-terminal region. Transgenic Arabidopsis plants were produced which expressed a fusion protein consisting of GUS and C-terminal fragments of phyB. GUS staining from the fusion protein in these transgenic plants was observed in the nucleus, which suggests that the nuclear localization signal of the fragment is functional. Next, it was examined whether the endogenous phyB was detected in the nucleus. Nuclei were isolated from the light-grown wild-type Arabidopsis leaves and subjected to the immunoblot analysis. The result indicated that a substantial fraction of total phyB was recovered in the isolated nuclei. This result was further confirmed by the immunocytochemical analysis of the protoplasts. Finally, the effects of light treatments on the levels of phyB in the isolated nuclei were examined. Dark adaptation of the plants before the nuclear isolation reduced the levels of phyB. The reduction was accelerated by irradiation of plants with far-red light before the transfer to darkness. Thus, nuclear localization of phyB was suggested to be light-dependent.     

Nuclear transportation of diacylglycerol kinase gamma and its possible function in the nucleus

Diacylglycerol kinases (DGKs) convert diacylglycerol (DG) to phosphatidic acid, and both lipids are known to play important roles in lipid signal transduction. Thereby, DGKs are considered to be a one of the key players in lipid signaling, but its physiological function remains to be solved. In an effort to investigate one of nine subtypes, we found that DGKgamma came to be localized in the nucleus with time in all cell lines tested while seen only in the cytoplasm at the early stage of culture, indicating that DGKgamma is transported from the cytoplasm to the nucleus. The nuclear transportation of DGKgamma didn't necessarily need DGK activity, but its C1 domain was indispensable, suggesting that the C1 domain of DGKgamma acts as a nuclear transport signal. Furthermore, to address the function of DGKgamma in the nucleus, we produced stable cell lines of wild-type DGKgamma and mutants, including kinase negative, and investigated their cell size, growth rate, and cell cycle. The cells expressing the kinase-negative mutant of DGKgamma were larger in size and showed slower growth rate, and the S phase of the cells was extended. These findings implicate that nuclear DGKgamma regulates cell cycle.     

Nuclear magnetic resonance monitoring of treatment and prediction of outcome in multiple sclerosis

Magnetic resonance (MR) techniques provide an objective, sensitive and quantitative assessment of the evolving pathology in multiple sclerosis. There is an increasing definition of the pathological specificity of newer techniques, and more robust correlations with clinical evolution are emerging. As the pathophysiological basis of in vivo nuclear MR signal abnormalities is further elucidated, it is likely that the importance of MR as a tool to monitor new therapies will increase.