Diverse functions of Polycomb group proteins during plant development

Polycomb group (PcG) proteins play essential roles in animal and plant life cycles by controlling the expression of important developmental regulators. These structurally heterogeneous proteins form multimeric protein complexes that control higher order chromatin structure and, thereby, the expression state of their target genes. Once established, PcG proteins maintain silent gene expression states over many cell divisions providing a molecular basis for a cellular 'memory.' PcG proteins are best known for their role in the control of homeotic genes in Drosophila and mammals. In addition, they play important roles in the control of cell proliferation in vertebrate and invertebrate systems. Recent studies in plants have shown that PcG proteins regulate diverse developmental processes and, as in animals, they affect both homeotic gene expression and cell proliferation. Thus, the function of PcG proteins has been widely conserved between the plant and animal kingdoms.     

Essential Role for Activation of the Polycomb Group (PcG) Protein Chromatin Silencing Pathway in Metastatic Prostate Cancer

The Polycomb-group (PcG) gene BMI1 is required for the proliferation and self-renewal of normal and leukemic stem cells. Overexpression of the BMI1 oncogene causes neoplastic transformation of lymphocytes and plays an essential role in the pathogenesis of myeloid leukemia. Another PcG protein, Ezh2, was implicated in metastatic prostate and breast cancers, suggesting that PcG pathway activation is relevant for epithelial malignancies. Whether an oncogenic role of the BMI1 and PcG pathway activation may be extended beyond leukemia and may affect progression of solid tumors as well remains unknown. Here we demonstrate that activation of the BMI1 oncogene-associated PcG pathway plays an essential role in metastatic prostate cancer, thus mechanistically linking the pathogenesis of leukemia, self-renewal of stem cells, and prostate cancer metastasis. To characterize the functional status of the PcG pathway in metastatic prostate cancer, we utilized advanced cell- and whole animal-imaging technologies, gene and protein expression profiling, stable siRNA gene targeting, and tissue microarray (TMA) analysis in relevant experimental and clinical settings. We demonstrate that in multiple experimental models of metastatic prostate cancer both the BMI1 and Ezh2 genes are amplified and gene amplification is associated with increased expression of corresponding mRNAs and proteins. For the first time, we provide images of human prostate carcinoma metastasis precursor cells isolated from the circulation which overexpress both the BMI1 and Ezh2 oncoproteins. Consistent with the PcG pathway activation hypothesis, increased BMI1 and Ezh2 expression in metastatic cancer cells is associated with elevated levels of H2AubiK119 and H3metK27 histones. Quantitative immunofluorescence colocalization analysis and expression profiling experiments documented increased the BMI1 and Ezh2 expression in clinical prostate carcinoma samples and demonstrated that high levels of BMI1 and Ezh2 expression are associated with markedly increased likelihood of therapy failure and disease relapse after radical prostatectomy. Gene-silencing analysis reveals that activation of the PcG pathway is mechanistically linked with highly malignant behavior of human prostate carcinoma cells and is essential for in vivo growth and metastasis of human prostate cancer. We conclude that the results of experimental and clinical analyses indicate important biological role of PcG pathway activation in metastatic prostate cancer. Our work suggests that the PcG pathway activation is a common oncogenic event in pathogenesis of metastatic solid tumors and provides justification for development of small molecule inhibitors of the PcG chromatin silencing pathway as a novel therapeutic modality for treatment of metastatic prostate cancer.     

PcG蛋白复合体对Hox基因调节的研究

PcG蛋白广泛参与到生长、发育、增殖、分化以及肿瘤发生等重要过程.而目前为止对PcG蛋白的靶基因研究最透彻的就是Hox家族. Hox基因存在于一个高度保守的基因簇内,在调控维持正常发育及肿瘤发生中有重要作用.一般认为,PcG蛋白复合物对Hox基因进行以组蛋白表观修饰为主的沉默作用,指导Hox基因适时适地发挥功能. 同时,这个过程还需要DNA连接蛋白、ncRNA等分子的辅助.本文对Hox基因和PcG蛋白的组成和功能进行介绍,并重点归纳总结了对二者关系的经典和最新认识.     

From flour to flower: how Polycomb group proteins influence multiple aspects of plant development

Cell identity and differentiation are determined by patterns of regulatory gene expression. Spatially and temporally regulated homeotic gene expression defines segment identities along the anterior-posterior axis of animal embryos. Polycomb group (PcG) proteins form a cellular memory system that maintains the repressed state of homeotic gene expression. Conserved PcG proteins control multiple aspects of Arabidopsis development and maintain homeotic gene repression. In animals, PcG proteins repress their target genes by modifying histone tails through deacetylation and methylation, generating a PcG-specific histone code that recruits other chromatin remodeling proteins to establish a stable, heritable mechanism of epigenetic expression control. Plant PcG proteins might function through a similar biochemical mechanism owing to their conserved structural and functional relationship to animal PcG proteins.     

Polycomb group and trithorax group proteins in Arabidopsis

Polycomb group (PcG) and trithorax group (trxG) proteins form molecular modules of a cellular memory mechanism that maintains gene expression states established by other regulators. In general, PcG proteins are responsible for maintaining a repressed expression state, whereas trxG proteins act in opposition to maintain an active expression state. This mechanism, first discovered in Drosophila and subsequently in mammals, has more recently been studied in plants. The characterization of several Polycomb Repressive Complex 2 (PRC2) components in Arabidopsis thaliana constituted a first breakthrough, revealing key roles of PcG proteins in the control of crucial plant developmental processes. Interestingly, the recent identification of plant homologues of the Drosophila trithorax protein suggests a conservation of both the PcG and trxG gene regulatory system in plants. Here, we review the current evidence for the role of PcG and trxG proteins in the control of plant development, their biochemical functions, their interplay in maintaining stable expression states of their target genes, and point out future directions which may help our understanding of PcG and trxG function in plants.     

Role of polycomb group proteins in stem cell self-renewal and cancer

Polycomb group proteins (PcG) form part of a gene regulatory mechanism that determines cell fate during normal and pathogenic development. The mechanism relies on epigenetic modifications on specific histone tails that are inherited through cell divisions, thus behaving de facto as a cellular memory. This cellular memory governs key events in organismal development as well as contributing to the control of normal cell growth and differentiation. Consequently, the dysregulation of PcG genes, such as Bmi1, Pc2, Cbx7, and EZH2 has been linked with the aberrant proliferation of cancer cells. Furthermore, at least three PcG genes, Bmi1, Rae28, and Mel18, appear to regulate self-renewal of specific stem cell types suggesting a link between the maintenance of cellular homeostasis and tumorigenesis. In this review, we will briefly summarize current views on PcG function and the evidence linking specific PcG proteins with the behavior of stem cells and cancer cells.     

Extra sex combs, chromatin, and cancer: exploring epigenetic regulation and tumorigenesis in Drosophila

Developmental genetic studies in Drosophila unraveled the importance of Polycomb group (PcG) and Trithorax group (TrxG) genes in controlling cellular identity.PcG and TrxG proteins form histone modifying complexes that catalyze repressive or activating histone modifications,respectively,and thus maintaining the expression status of homeotic genes.Human orthologs of PcG and TrxG genes are implicated in tumorigenesis as well as in determining the prognosis of individual cancers.Recent whole genome analyses of cancers also highlighted the importance of histone modifying proteins in controlling tumorigenesis.Comprehensive understanding of the mechanistic relationship between histone regulation and tumorigenesis holds the promise of significantly advancing our understanding and management of cancer.It is anticipated that Drosophila melanogaster,the model organism that contributed significantly to our understanding of the functional role of histone regulation in development,could also provide unique insight for our understanding of how histone dysregulation can lead to cancer.In this review,we will discuss several recent advances in this regard.     

Extra sex combs, chromatin, and cancer: Exploring epigenetic regulation and tumorigenesis in Drosophila

Developmental genetic studies in Drosophila unraveled the importance of Polycomb group (PcG) and Trithorax group (TrxG) genes in controlling cellular identity.PcG and TrxG proteins form histone modifying complexes that catalyze repressive or activating histone modifications,respectively,and thus maintaining the expression status of homeotic genes.Human orthologs of PcG and TrxG genes are implicated in tumorigenesis as well as in determining the prognosis of individual cancers.Recent whole genome analyses of cancers also highlighted the importance of histone modifying proteins in controlling tumorigenesis.Comprehensive understanding of the mechanistic relationship between histone regulation and tumorigenesis holds the promise of significantly advancing our understanding and management of cancer.It is anticipated that Drosophila melanogaster,the model organism that contributed significantly to our understanding of the functional role of histone regulation in development,could also provide unique insight for our understanding of how histone dysregulation can lead to cancer.In this review,we will discuss several recent advances in this regard.     

The Polyhomeotic protein induces hyperplastic tissue overgrowth through the activation of the JAK/STAT pathway

Epigenetic mechanisms controlling cellular proliferation are essential to animal development. Moreover, altered levels of expression of the epigenetic regulator proteins are associated with the development and progression of human diseases like cancer. We have studied the effects of high levels of Polyhomeotic (PH) protein, a member of the Polycomb Group (PcG), during the proliferation of the imaginal discs in Drosophila. Over expression of PH protein causes induction of proliferation, accompanied with induction of JNK-dependent apoptosis. As a result, massive hyperplastic overgrowth is produced and the corresponding differentiated tissues show phenotypes related with mis-regulation of homeotic gene expression. We have found that high levels of PH up-regulate the JAK/STAT pathway through the de-repression of Unpaired (UPD), the extracellular ligand of the Drosophila JAK/STAT signalling cascade. Moreover, inactivation of the JAK/STAT pathway in the presence of a large amount of PH protein greatly reduces the tissue overgrowth, demonstrating a functional role of JAK/STAT in PH-induced hyperplasia. Finally, we have observed that decapentaplegic and d-myc, two growth genes and putative targets of the JAK/STAT pathway, are also over expressed in the PH-induced tumors. We propose that during normal development, the PcG proteins act to maintain inactive the JAK/STAT pathway. Upon cellular stress, changes in the levels of PcG proteins expression are induced and JAK/STAT is activated leading to tumor development. Our results show a functional relationship between the PcG gene expression and the JAK/STAT pathway, both of which are found to be perturbed in tumorigenesis.     

Identification and characterization of Polycomb group genes in the silkworm, <Emphasis Type="Italic">Bombyx mori</Emphasis>

Polycomb group (PcG) proteins are involved in chromatin modifications for maintaining gene repression that play important roles in the regulation of gene expression, tumorigenesis, chromosome X-inactivation, and genomic imprinting in Drosophila melanogaster, mammals, and even plants. To characterize the orthologs of PcG genes in the silkworm, Bombyx mori, 13 candidates were identified from the updated silkworm genome sequence by using the fruit fly PcG genes as queries. Comparison of the silkworm PcG proteins with those from other insect species revealed that the insect PcG proteins shared high sequence similarity. High-level expressions of all the silkworm PcG genes were maintained through day 2 to day 7 of embryogenesis, and tissue microarray data on day 3 of the fifth instar larvae showed that their expression levels were relatively low in somatic tissues, except for Enhancer of zeste (E(Z)). In addition, knockdown of each PRC2 component, such as E(Z), Extra sex combs (ESC), and Suppressor of zeste 12 (SU(Z)12), considerably decreased the global levels of H3K27me3 but not of H3K27me2. Taken together, these results suggest that insect PcG proteins are highly conserved during evolution and might play similar roles in embryogenesis.     

Altered Expression of Polycomb Group Genes in Glioblastoma Multiforme

The Polycomb group (PcG) proteins play a critical role in histone mediated epigenetics which has been implicated in the malignant evolution of glioblastoma multiforme (GBM). By systematically interrogating The Cancer Genome Atlas (TCGA), we discovered widespread aberrant expression of the PcG members in GBM samples compared to normal brain. The most striking differences were upregulation of EZH2, PHF19, CBX8 and PHC2 and downregulation of CBX7, CBX6, EZH1 and RYBP. Interestingly, changes in EZH2, PHF19, CBX7, CBX6 and EZH1 occurred progressively as astrocytoma grade increased. We validated the aberrant expression of CBX6, CBX7, CBX8 and EZH2 in GBM cell lines by Western blotting and qRT-PCR, and further the aberrant expression of CBX6 in GBM tissue samples by immunohistochemical staining. To determine if there was functional significance to the diminished CBX6 levels in GBM, CBX6 was overexpressed in GBM cells resulting in decreased proliferative capacity. In conclusion, aberrant expression of PcG proteins in GBMs may play a role in the development or maintenance of the malignancy.     

Reconstitution of a functional core polycomb repressive complex

The opposing actions of polycomb (PcG) and trithorax group (trxG) gene products maintain essential gene expression patterns during Drosophila development. PcG proteins are thought to establish repressive chromatin structures, but the mechanisms by which this occurs are not known. Polycomb repressive complex 1 (PRC1) contains several PcG proteins and inhibits chromatin remodeling by trxG-related SWI/SNF complexes. We have defined a functional core of PRC1 by reconstituting a stable complex using four recombinant PcG proteins. One subunit, PSC, can also inhibit chromatin remodeling on its own. These PcG proteins create a chromatin structure that has normal nucleosome organization and is accessible to nucleases but excludes hSWI/SNF.     

Polycomb-group mediated epigenetic mechanisms through plant evolution

Polycomb Group (PcG) proteins form an epigenetic "memory system", conserved in both plants and animals, controlling global gene expression during development via histone modifications. The role of PcG proteins in plants was primarily explored in Arabidopsis thaliana, where PcG regulation of developmental processes was demonstrated throughout the plant life cycle. Our knowledge about the PcG machinery in terrestrial plants other than Arabidopsis began to accumulate only in recent years. In this review we summarize recent emerging data on the evolution and diversification of PcG mechanisms in various phyla, from early-diverging plants, including members of the Chlorophyte algae, through bryophytes and flowering plants. We describe the compositions of the PcG gene families, their so-far studied expression profiles, and finally summarize commonalities vs. differences among PcG functions across the various species. This article is part of a Special Issue entitled: Epigenetic control of cellular and developmental processes in plants.