Zinc finger proteins containing the Kruppel associated box (KRAB-ZFPs) constitute the largest individual family of transcriptional repressors encoded by the genomes of higher organisms. KRAB domain, positioned at the NH2 terminus of the KRAB-ZFPs, interacts with a scaffold protein, KAP-1, which is able to recruit various transcriptional factors causing repression of genes to which KRAB ZFPs bind. The relevance of such repression is reflected in the large number of the KRAB zinc finger protein genes in the human genome. However, in spite of their numerical abundance little is currently known about the gene targets and the physiological functions of KRAB- ZFPs. However, emerging evidence links the transcriptional repression mediated by the KRAB-ZFPs to cell proliferation, differentiation, apoptosis and cancer. Moreover, the fact that KRAB containing proteins are vertebrate-specific suggests that they have evolved recently, and that their key roles lie in some aspects of vertebrate development. In this review, we will briefly discuss some regulatory functions of the KRAB-ZFPs in different physiological and pathological states, thus contributing to better understand their biological roles.
Myeloid leukemic cells are intrinsically under oxidative stress due to impaired reactive oxygen species (ROS) homeostasis, a common signature of several hematological malignancies. The present review focuses on the molecular mechanisms of aberrant ROS production in myeloid leukemia cells as well as on the redox-dependent signaling pathways involved in the leukemogenic process. Finally, the relevance of new chemotherapy options that specifically exert their pharmacological activity by altering the cellular redox imbalance will be discussed as an effective strategy to eradicate chemoresistant cells.
The transcription factor Wilms' tumor gene 1, WT1, is implicated both in normal developmental processes and in the generation of a variety of solid tumors and hematological malignancies. Physical interactions of other cellular proteins with WT1 are known to modulate its function. We previously identified the Krüppel-like zinc-finger protein, ZNF224, as a novel human WT1-associating protein that enhances the transcriptional activation of the human vitamin D receptor promoter by WT1. Here, we have analyzed the effects of WT1-ZNF224 interaction on the expression of apoptosis-regulating genes in the chronic myelogenous leukemia (CML) K562 cell line. The results demonstrated that ZNF224 acts in fine tuning of WT1-dependent control of gene expression, acting as a co-activator of WT1 in the regulation of proapoptotic genes and suppressing WT1 mediated transactivation of antiapoptotitc genes. Moreover, the DNA damaging drug cytosine arabinoside (ara-C) induces expression of ZNF224 in K562 cells and this induction enhances cell apoptotic response to ara-C. These findings suggest that ZNF224 can be a mediator of DNA damage-induced apoptosis in leukemia cells.
Wilms' tumour suppressor gene, WT1, is mutated/deleted in approximately 15% of Wilms' tumours, highly expressed in the majority of other cancers and is essential for normal embryonic development. The gene encodes multiple isoforms of a zinc-finger (ZF) protein with diverse cellular functions, in particular participating in both transcriptional and post-transcriptional gene regulation. Physical interactions of other cellular proteins with WT1 are known to modulate its function. However, despite the isolation of several WT1-binding proteins, the mechanisms involved in regulating WT1 activities are not clearly understood. In this study, we report the identification of the Krüppel-like ZF protein, ZNF224, as a novel human WT1-associating protein and demonstrate that ZNF224 and its isoform ZNF255 show a specific pattern of interaction with the WT1 splicing variants WT1(-KTS) and WT1(+KTS). These interactions occur in different subcellular compartments and are devoted to control different cellular pathways. The nuclear interaction between ZNF224 and WT1(-KTS) results in an increase in trascriptional activation mediated by WT1, implying that ZNF224 acts as a co-regulator of WT1, whereas, on the contrary, the results obtained for ZNF255 suggest a role for this protein in RNA processing together with WT1. Moreover, our data give the first functional information about the involvement of ZNF255 in a specific molecular pathway, RNA maturation and processing.
Gene transcription in eukaryotes is modulated by the coordinated recruitment of specific transcription factors and chromatin-modulating proteins. Indeed, gene activation and/or repression is/are regulated by histone methylation status at specific arginine or lysine residues. In this work, by co-immunoprecipitation experiments, we demonstrate that PRMT5, a type II protein arginine methyltransferase that monomethylates and symmetrically dimethylates arginine residues, is physically associated with the Kruppel-like associated box-zinc finger protein ZNF224, the aldolase A gene repressor. Moreover, chromatin immunoprecipitation assays show that PRMT5 is recruited to the L-type aldolase A promoter and that methylation of the nucleosomes that surround the L-type promoter region occurs in vivo on the arginine 3 of histone H4. Consistent with its association to the ZNF224 repressor complex, the decrease of PRMT5 expression produced by RNA interference positively affects L-type aldolase A promoter transcription. Finally, the alternating occupancy of the L-type aldolase A promoter by the ZNF224-PRMT5 repression complex in proliferating and growth-arrested cells suggests that these regulatory proteins play a significant role during the cell cycle modulation of human aldolase A gene expression. Our data represent the first experimental evidence that protein arginine methylation plays a role in ZNF224-mediated transcriptional repression and provide novel insight into the chromatin modifications required for repression of gene transcription by Kruppel-like associated box-zinc finger proteins.Gene transcription is controlled by the interplay of several transacting factors and chromatin-modifying activities that are sequentially recruited to the promoter region. Post-translational modifications of histone and non-histone chromosomal proteins are considered to be additional mechanisms that contribute to the epigenetic inheritance of phenotypic alterations. The temporal and combinatorial recruitment of the histonemodifying activities can determine differential outcomes in gene expression (1-3).Histone methylation, which usually occurs on arginine or lysine residues, is involved in regulation of chromatin structure, which in turn either stimulates or inhibits gene transcription. In fact, methylation of Lys-4 and Arg-17 of histone H3 and Arg-3 of histone H4 has been associated with transcriptional activation, whereas methylation of Lys-9 and Lys-27 of histone H3 has been related to gene repression (4, 5). Arginine methylation of nucleosomal histones is catalyzed by a homogenous class of enzymes that are known as "protein arginine methyltransferases" (PRMTs). 4 In this reaction the methyl group, which is provided by the S-adenosyl-L-methionine, is transferred to one of the guanidinium nitrogens of arginine residues. PRMTs are divided into type I PRMTs, which catalyze monomethylation and asymmetric dimethylation of arginine residues, and type II PRMTs, which also catalyze monomethylation and, in addition, symmetric dimethylation of a...
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