Structure and expression of TIS21, a primary response gene induced by growth factors and tumor promoters

Cloning of PC3B, a novel member of the PC3/BTG/TOB family of growth inhibitory genes, highly expressed in the olfactory epithelium

We identified in the EST database murine and human sequences similar, but not identical, to the members of the PC3/BTG/TOB family of cell cycle inhibitors. A conserved domain (aa 50-68) of the PC3 protein, the prototype member of the family, was used as a query. That domain has been shown by us to be necessary for the antiproliferative activity of PC3. A murine EST clone and a highly homologous human EST clone, containing the entire ORF, were chosen for sequencing. Comparison to databases and a phylogenetic tree analysis indicated that these EST clones are the mouse and human homologues of a gene that represents a novel member of the PC3/BTG/TOB family. This gene, named PC3B, is endowed with marked antiproliferative activity, being able to induce G(1) arrest, and is highly expressed in testis, in oocyte, and in preimplantation embryos. Analysis of its expression during murine development indicated a specific localization in the olfactory epithelium at midgestation, suggesting that PC3B might be involved in the differentiation of this neuronal structure. Human PC3B mapped to chromosome 11q23, as indicated by radiation hybrid analysis.

Identification and molecular analysis of BANP

BTG3 belongs to a family of structurally related genes whose biochemical functions remain elusive. In order to investigate the mechanism underlying BTG3-mediated functions, we tried to identify BTG3 potential partners. The use of the yeast 'two-hybrid system', with BTG3 as bait, enabled us to isolate BANP (BTG3 Associated Nuclear Protein). Other commonly used protein-binding assays did not confirm this yeast interaction. However, BANP had never been described before, and this prompted us to further characterise this gene. In this paper, we present data on its molecular organization in mouse, then we speculate on the nature of this nuclear protein, and finally we localise BANP on the human chromosome 16q24 subregion; we discuss the fact that frequent loss of heterozygosity within this region has been observed in different tumours.

Cloning and characterization of the mouse tob2 gene

Human Tob2 is a member of the Tob/BTG1 anti-proliferative family of proteins. Here, we report the molecular cloning and characterization of the mouse tob2 gene. The tob2 gene contains an open reading frame of 345 amino acids with an 89% identity to its human counterparts. The coding region of mouse tob2 is not interrupted by introns. The tob2 transcript is 4.2kb long, the size being similar to that of the human tob2 transcript, and detected ubiquitously in various tissues of adult mice. In addition, in situ hybridization shows that tob2 is ubiquitously expressed in embryo, the level of expression being especially high in skeletal muscle. Collectively, Tob2 is suggested to play roles both during embryogenesis and in adults.

Protein-arginine methyltransferase I, the predominant protein-arginine methyltransferase in cells, interacts with and is regulated by interleukin enhancer-binding factor 3

Arginine methylation is a common post-translation modification found in many proteins. Protein-arginine methyltransferase I (PRMT1) contributes >90% of type I protein-arginine methyltransferase activity in cells and tissues. To expand our knowledge on the regulation and role of PRMT1 in cells, we used the yeast two-hybrid system to identify proteins that interact with PRMT1. One of the interacting proteins we cloned is interleukin enhancer-binding factor 3 (ILF3), also known as M phase phosphoprotein 4. ILF3 is closely related to nuclear factor 90 (NF90). Using an immunofluorescence analysis, we determined that ILF3 and PRMT1 co-localize in the nucleus. Moreover, PRMT1 and ILF3 co-precipitate in immunoprecipitation assays and can be isolated together in "pull-down" experiments using recombinant fusion proteins. ILF3 is a robust substrate for methylation by PRMT1 and can modulate PRMT1 activity in in vitro methylation assays. Deletion studies demonstrated that the COOH-terminal region of ILF3, which is rich in arginine, glycine, and serine, is responsible for the strong interaction between PRMT1 and ILF3 and is the site of ILF3 methylation by PRMT1. Although ILF3 and NF90 are highly similar, they differ in their carboxyl-terminal regions. Because of this difference, NF90 does not interact with PRMT1, is a much poorer substrate than ILF3 for PRMT1-dependent methylation, and does not modulate PRMT1 enzyme activity.

Arrest of G(1)-S progression by the p53-inducible gene PC3 is Rb dependent and relies on the inhibition of cyclin D1 transcription

The p53-inducible gene PC3 (TIS21, BTG2) is endowed with antiproliferative activity. Here we report that expression of PC3 in cycling cells induced accumulation of hypophosphorylated, growth-inhibitory forms of pRb and led to G(1) arrest. This latter was not observed in cells with genetic disruption of the Rb gene, indicating that the PC3-mediated G(1) arrest was Rb dependent. Furthermore, (i) the arrest of G(1)-S transition exerted by PC3 was completely rescued by coexpression of cyclin D1 but not by that of cyclin A or E; (ii) expression of PC3 caused a significant down-regulation of cyclin D1 protein levels, also in Rb-defective cells, accompanied by inhibition of CDK4 activity in vivo; and (iii) the removal from the PC3 molecule of residues 50 to 68, a conserved domain of the PC3/BTG/Tob gene family, which we term GR, led to a loss of the inhibition of proliferation as well as of the down-regulation of cyclin D1 levels. These data point to cyclin D1 down-regulation as the main factor responsible for the growth inhibition by PC3. Such an effect was associated with a decrease of cyclin D1 transcript and of cyclin D1 promoter activity, whereas no effect of PC3 was observed on cyclin D1 protein stability. Taken together, these findings indicate that PC3 impairs G(1)-S transition by inhibiting pRb function in consequence of a reduction of cyclin D1 levels and that PC3 acts, either directly or indirectly, as a transcriptional regulator of cyclin D1.

The leukemia-associated protein Btg1 and the p53-regulated protein Btg2 interact with the homeoprotein Hoxb9 and enhance its transcriptional activation

BTG1 and BTG2 belong to a family of functionally related genes involved in the control of the cell cycle. As part of an ongoing attempt to understand their biological functions, we used a yeast two-hybrid screening to look for possible functional partners of Btg1 and Btg2. Here we report the physical and functional association between these proteins and the homeodomain protein Hoxb9. We further show that Btg1 and Btg2 enhance Hoxb9-mediated transcription in transfected cells, and we report the formation of a Hoxb9.Btg2 complex on a Hoxb9-responsive target, and the fact that this interaction facilitates the binding of Hoxb9 to DNA. The transcriptional activity of the Hoxb9.Btg complex is essentially dependent on the activation domain of Hoxb9, located in the N-terminal portion of the protein. Our data indicate that Btg1 and Btg2 act as transcriptional cofactors of the Hoxb9 protein, and suggest that this interaction may mediate their antiproliferative function.

PC3 overexpression affects the pattern of cell division of rat cortical precursors

The PC3 gene is transiently expressed during neurogenesis in precursor cells of the telencephalic ventricular/subventricular zone, and is rapidly downregulated before cell migration and differentiation. It is thought to have a role in controlling cell proliferation, but its precise function is not known. Here we present evidence that PC3, when overexpressed in vitro by retroviral-mediated gene transfer, acts by interfering with the normal pattern of cell division. Firstly, we report evidence that PC3 overexpression reduces the rate of cell proliferation in both NIH 3T3 cells and embryonic precursor cells from the rat cerebral cortex. Secondly, when studying the pattern of BrdU dilution in clones of cortical precursors, we observe that clones transduced with PC3 show an asymmetric pattern of BrdU dilution more frequently than clones transduced with a control vector. We discuss the hypothesis that the higher number of PC3 transduced clones showing an asymmetric pattern of BrdU dilution may be due to an increase in asymmetric cell divisions.

Tob2, a novel anti-proliferative Tob/BTG1 family member, associates with a component of the CCR4 transcriptional regulatory complex capable of binding cyclin-dependent kinases

Human cDNAs encoding a novel member of Tob/BTG1 anti-proliferative family proteins were cloned. The putative protein product termed Tob2 consisted of 344 amino acids with high similarity to the Tob protein. The tob2 mRNA was 4.1 kb long and was ubiquitously expressed in human adult tissues, as was revealed by Northern blot hybridization. However, further in situ hybridization analysis showed a characteristic expression of the tob2 mRNA in oocytes, suggesting a unique role of Tob2 in oogenesis. Like the Tob protein, Tob2 inhibited cell cycle progression from the G0/G1 to S phases. Intriguingly, the amino-terminal half of Tob2 as well as that of Tob was associated with a human homologue of yeast Caf1, a component of the CCR4 transcription factor complex. Moreover, Caf1 was associated with cyclin dependent kinases. These data suggested that both Tob and Tob2 were involved in cell cycle regulation through their interaction with Caf1. Finally, the tob2 gene was mapped to human chromosome 22q13.1-q13.31.

Expression of rat BTG(3) gene, Rbtg3, is regulated by redox changes

The Rbtg3 gene was isolated by PCR (polymerase chain reaction) cloning from the cDNA library of Rat1 fibroblasts that were stimulated with TPA (12-O-tetradecanoylphorbol-13-acetate) or various growth factors for 3h and was found to be a rat homologue of mouse BTG3 and human ANA genes. The Rbtg3 gene had unique DNA sequences in the 5'-UTR and 3'-UTR that contained four ATTTA and one TTATTTA(T/A)(T/A) nonamer motif, and also a polyA addition site. Nucleotide homology of Rbtg3 with BTG3 and ANA was 88.5 and 76.6%, respectively. Expression of Rbtg3 was investigated in SD rats as well as cell lines derived from mouse--SW3T3, NIH3T3 fibroblasts--and rat--Rat1, 3Y1 fibroblasts and PC12--cells. Rbtg3 was highly expressed in brain but barely in lung, kidney, thymus and spleen. The constitutive expression level was high in SW3T3, Rat1 and 3Y1 fibroblasts, but very low in NIH3T3 fibroblast and PC12 cells. However, in all cells tested, Rbtg3 was proved to be one of the primary response genes superinduced by TPA (50ng/ml)+cycloheximide (CHX, 10 microgram/ml). Expression of Rbtg3 was induced by H(2)O(2) (500mM) up to fourfold in PC12 cells and was blocked by pretreatment of NAC (N-acetyl-L-cysteine, 10mM). The induction was ninefold in 3Y1 fibroblasts by menadione (25mM) treatment for 1h, whereas it was reduced to a third of the control level in SW3T3 fibroblast by the same treatment. Rbtg3 was not expressed in NIH3T3 cells but minimally regulated by redox changes as compared with rapid and strong induction of TIS21/BTG2 mRNAs after TPA or H(2)O(2) stimulation. The above results indicate that Rbtg3 is one of many redox-regulated genes as well as a primary response gene.

Galpha(13) stimulates Rho-dependent activation of the cyclooxygenase-2 promoter

Cyclooxygenase-2 (COX-2) gene expression is rapidly increased by cytokines, tumor promoters, and growth factors and is markedly enhanced in various cancer cells. Here, we examine the regulation of COX-2 promoter activity by alpha subunits of heterotrimeric G proteins in NIH 3T3 cells. Using a transient transfection assay with a reporter vector in which the murine COX-2 promoter drives the production of luciferase and expression vectors encoding for alpha subunits of G-proteins, we show that overexpression of wild type and constitutively active Galpha(13) and Galpha(q) induced transcription from the COX-2 promoter. The highest level of induced luciferase activity (5.8-fold) occurred in cells expressing the constitutively active Galpha(13)(Q226L). We also show that expression of a constitutively active mutant of Rho (RhoQ63L) also induced transcription from the COX-2 promoter. Co-expression of Clostridium botulinum C3 toxin specifically blocked induction of the COX-2 promoter by either Galpha(13)Q226L or RhoQ63L but did not prevent the activation of this promoter by Ras, Rac, v-src, or forskolin. We conclude that Galpha(13) signals through a Rho-dependent pathway leading to activation of the COX-2 promoter. This pathway is not inhibited by either cytochalasin D, which disrupts actin filament organization, or genistein, a broad spectrum tyrosine kinase inhibitor, indicating a bifurcation of the signaling pathway used by Galpha(13)/Rho to induce COX-2 expression from that used to induce stress fiber formation and tyrosine phosphorylation of focal adhesion proteins.

BTG1: a triiodothyronine target involved in the myogenic influence of the hormone

The product of the B-cell translocation gene 1 (BTG1), a member of an antiproliferative protein family including Tis-21/PC3 and Tob, is thought to play an important role in the regulation of cell cycle progression. We have shown in a previous work that triiodothyronine (T3) stimulates quail myoblast differentiation, partly through a cAMP-dependent mechanism involved in the stimulation of cell cycle withdrawal. Furthermore, we found that T3 or 8-Br-cAMP increases BTG1 nuclear accumulation in confluent myoblast cultures. In this study, we report that BTG1 is essentially expressed at cell confluence and in differentiated myotubes. Whereas neither T3 nor cAMP exerted a direct transcriptional control upon BTG1 expression, we found that AP-1 activity, a crucial target involved in the triiodothyronine myogenic influence, repressed BTG1 expression, thus probably explaining the low BTG1 expression level in proliferating myoblasts. In transient transfection studies, we demonstrated that an AP-1-like sequence located in the BTG1 promoter was involved in this negative regulation. Our present data also bring evidence that the stimulation of BTG1 nuclear accumulation by T3 or 8-Br-cAMP probably results from an increased nuclear import or retention in the nucleus. Lastly, BTG1 overexpression in quail myoblasts mimicked the T3 or 8-Br-cAMP myogenic influence: (i) inhibition of myoblast proliferation due to an increased rate of myoblast withdrawal from the cell cycle; and (ii) stimulation of terminal differentiation. These data suggest that BTG1 is probably involved in T3 and cAMP myogenic influences. In conclusion, BTG1 is a T3 target involved in the regulation of myoblast differentiation.

Expression of the antiproliferative gene TIS21 at the onset of neurogenesis identifies single neuroepithelial cells that switch from proliferative to neuron-generating division

At the onset of mammalian neurogenesis, neuroepithelial (NE) cells switch from proliferative to neuron-generating divisions. Understanding the molecular basis of this switch requires the ability to distinguish between these two types of division. Here we show that in the mouse ventricular zone, expression of the mRNA of the antiproliferative gene TIS21 (PC3, BTG2) (i) starts at the onset of neurogenesis, (ii) is confined to a subpopulation of NE cells that increases in correlation with the progression of neurogenesis, and (iii) is not detected in newborn neurons. Expression of the TIS21 mRNA in the NE cells occurs transiently during the cell cycle, i.e., in the G1 phase. In contrast to the TIS21 mRNA, the TIS21 protein persists through the division of NE cells and is inherited by the neurons, where it remains detectable during neuronal migration and the initial phase of differentiation. Our observations indicate that the TIS21 gene is specifically expressed in those NE cells that, at their next division, will generate postmitotic neurons, but not in proliferating NE cells. Using TIS21 as a marker, we find that the switch from proliferative to neuron-generating divisions is initiated in single NE cells rather than in synchronized neighboring cells.

RNA and protein interactions modulated by protein arginine methylation

This review summarizes the current status of protein arginine N-methylation reactions. These covalent modifications of proteins are now recognized in a number of eukaryotic proteins and their functional significance is beginning to be understood. Genes that encode those methyltransferases specific for catalyzing the formation of asymmetric dimethylarginine have been identified. The enzyme modifies a number of generally nuclear or nucleolar proteins that interact with nucleic acids, particularly RNA. Postulated roles for these reactions include signal transduction, nuclear transport, or a direct modulation of nucleic acid interactions. A second methyltransferase activity that symmetrically dimethylates an arginine residue in myelin basic protein, a major component of the axon sheath, has also been characterized. However, a gene encoding this activity has not been identified to date and the cellular function for this methylation reaction has not been clearly established. From the analysis of the sequences surrounding known arginine methylation sites, we have determined consensus methyl-accepting sequences that may be useful in identifying novel substrates for these enzymes and may shed further light on their physiological role.

Interaction of BTG1 and p53-regulated BTG2 gene products with mCaf1, the murine homolog of a component of the yeast CCR4 transcriptional regulatory complex

Both BTG1 and BTG2 are involved in cell-growth control. BTG2 expression is regulated by p53, and its inactivation in embryonic stem cells leads to the disruption of DNA damage-induced G2/M cell-cycle arrest. In order to investigate the mechanism underlying Btg-mediated functions, we looked for possible functional partners of Btg1 and Btg2. Using yeast two-hybrid screening, protein-binding assays, and transient transfection assays in HeLa cells, we demonstrated the physical in vitro and in vivo interaction of both Btg1 and Btg2 with the mouse protein mCaf1 (i.e. mouse CCR4-associated factor 1). mCaf1 was identified through its interaction with the CCR4 protein, a component of a general transcription multisubunit complex, which, in yeast, regulates the expression of different genes involved in cell-cycle regulation and progression. These data suggest that Btg proteins, through their association with mCaf1, may participate, either directly or indirectly, in the transcriptional regulation of the genes involved in the control of the cell cycle. Finally, we found that box B, one of two conserved domains which define the Btg family, plays a functional role, namely that it is essential to the Btg-mCaf1 interaction.

Overexpression of the PC3/TIS21/BTG2 mRNA is part of the stress response induced by acute pancreatitis in rats

We have previously shown that the acute phase reaction of the pancreas is a powerful emergency mechanism which protects the organism against further pancreatic aggression. In an attempt to understand the mechanisms involved in this protective effect we tried to characterize at the molecular level the phenotypic changes of the pancreatic cell during acute stress. Using a systematic approach, we identified the PC3/TIS21/BTG2 mRNA as strongly overexpressed in pancreas during the acute phase of pancreatitis. PC3/TIS21/BTG2 mRNA is also overexpressed in liver and kidney during acute pancreatitis but not in the other tissues analyzed. In addition, PC3/TIS21/BTG2 mRNA is overexpressed in kidney after a 30-min ischemia. Since acute pancreatitis and kidney ischemia-reperfusion-induced injury were associated with apoptosis, and PC3/TIS21/BTG2 has an antiapoptotic activity, we speculate that this protein may play a role in the control of apoptosis progression in these tissues.

PRMT 3, a type I protein arginine N-methyltransferase that differs from PRMT1 in its oligomerization, subcellular localization, substrate specificity, and regulation

Methylation is one of the many post-translational modifications that modulate protein function. Although asymmetric NG,NG-dimethylation of arginine residues in glycine-arginine-rich domains of eucaryotic proteins, catalyzed by type I protein arginine N-methyltransferases (PRMT), has been known for some time, members of this enzyme class have only recently been cloned. The first example of this type of enzyme, designated PRMT1, cloned because of its ability to interact with the mammalian TIS21 immediate-early protein, was then shown to have protein arginine methyltransferase activity. We have now isolated rat and human cDNA orthologues that encode proteins with substantial sequence similarity to PRMT1. A recombinant glutathione S-transferase (GST) fusion product of this new rat protein, named PRMT3, asymmetrically dimethylates arginine residues present both in the designed substrate GST-GAR and in substrate proteins present in hypomethylated extracts of a yeast rmt1 mutant that lacks type I arginine methyltransferase activity; PRMT3 is thus a functional type I protein arginine N-methyltransferase. However, rat PRMT1 and PRMT3 glutathione S-transferase fusion proteins have distinct enzyme specificities for substrates present in both hypomethylated rmt1 yeast extract and hypomethylated RAT1 embryo cell extract. TIS21 protein modulates the enzymatic activity of recombinant GST-PRMT1 fusion protein but not the activity of GST-PRMT3. Western blot analysis of gel filtration fractions suggests that PRMT3 is present as a monomer in RAT1 cell extracts. In contrast, PRMT1 is present in an oligomeric complex. Immunofluorescence analysis localized PRMT1 predominantly to the nucleus of RAT1 cells. In contrast, PRMT3 is predominantly cytoplasmic.

Sequence and developmental expression of AmphiTob, an amphioxus homolog of vertebrate Tob in the PC3/BTG1/Tob family of tumor suppressor genes

Tob is a member of the PC3/ BTG1/Tob family of vertebrate tumor suppressor genes; its expression is known to inhibit proliferation of cells in vitro, but its possible roles during normal development have not been investigated previously. The present study concerns the structure and developmental expression of AmphiTob in an invertebrate chordate, amphioxus. This is the first investigation of any Tob gene during embryological development. The 311 amino acid AmphiTob protein is similar to vertebrate Tob but lacks the C-terminal PQ-rich domain of the latter. In early embryos of amphioxus, in situ hybridization first reveals AmphiTob expression in the hypoblast at the gastrula stage on the likely dorsal side of the embryo. During subsequent development, expression is seen in several tissues of the ectoderm, mesoderm, and endoderm. The most striking expression domains are in the developing somitic musculature and dorsal nerve cord. In the medial wall of each somite, AmphiTob is expressed strongly by cells destined to differentiate into the axial trunk muscles; this pattern persists until late in the larval stage, evidently because undifferentiated cells are continually becoming myogenic as the muscles grow. Nerve cord cells conspicuously transcribe AmphiTob from the late neurula until the early larval stage: Expression occurs in a few cells scattered along the nerve cord and in a group of cells located in the cerebral vesicle (in a region presumably homologous to the vertebrate diencephalic forebrain). During development, an intense and transitory transcription of AmphiTob may be an early event in cells exiting the cell cycle in preparation for differentiation.

Genes induced in programmed cell death of neuronal PC12 cells and developing sympathetic neurons in vivo

To identify primary response genes induced during early stages of neuronal programmed cell death (PCD), we screened by differential hybridization a subtracted cDNA library prepared from neuronal PC12 cells deprived of NGF for 6 hr in the presence of cycloheximide. Eight induced cDNA sequences were identified and designated message up-regulated during death (mud)-1-8. To determine which cloned sequences might be involved in neuronal PCD in vivo, expression of mud genes was analyzed in developing rat superior cervical ganglia (SCG) undergoing programmed cell death, using a combination of reverse Southern, reverse transcription polymerase chain reaction (RT-PCR), and in situ hybridization. Five sequences (mud-1, -3, -5/8, -6, and -7) are induced in SCG undergoing cell death in vivo, and induction of at least three of these (mud-3, -6, and -7) occurs in neurons. Partial sequence analysis reveals that mud-1 corresponds to annexin VI; mud-3 corresponds to rat PC3, mouse TIS21; mud-4 appears to be the rat homolog of human TAFII70; mud-5 and -8 are >85% identical members of the rodent gene family of B2-transcribed repeats; and mud-6 appears to be the rat homolog of human Ring 3 and Drosophila female sterile homeotic (fsh). Mud-2 and mud-7 encode novel sequences. These new candidate genes provide markers for early stages of neuronal PCD, are potentially involved in the cell death process, and serve to expand our view of cell death control in the developing nervous system.

Cloning and characterization of the mouse tob gene

The human Tob protein was identified as a molecule that interacted with the ErbB-2 protein, a receptor-type protein tyrosine kinase (RPTK). The interaction suggests that Tob is involved in RPTK-mediated signaling. In the present paper, we report molecular cloning and characterization of the mouse tob gene. The mouse tob gene contains an open reading frame of 1089 bp with 87% identity to its human counterpart in the nucleotide sequence. The coding region of mouse tob as well as human tob is not interrupted by introns. The mouse tob transcript is 2.3 kb long, the size being similar to that of the human tob transcript, and is detected ubiquitously in various tissues. Like human Tob, mouse Tob is characterized by the presence of a sequence rich in proline and glutamine which is often present in the sequence of transcription factors. In addition, the ATTTA motif characteristic of the immediate early gene is present in the 3'-untranslated region of the mouse tob gene. This, together with the conserved sequence and expression pattern of tob between mouse and human, suggests that Tob plays an important role in the response to extracellular signals.

Identification of BTG2, an antiproliferative p53-dependent component of the DNA damage cellular response pathway

Cell cycle regulation is critical for maintenance of genome integrity. A prominent factor that guarantees genomic stability of cells is p53 (ref. 1). The P53 gene encodes a transcription factor that has a role as a tumour suppressor. Identification of p53-target genes should provide greater insight into the molecular mechanisms that mediate the tumour suppressor activities of p53. The rodent Pc3/Tis21 gene was initially described as an immediate early gene induced by tumour promoters and growth factors in PC12 and Swiss 3T3 cells. It is expressed in a variety of cell and tissue types and encodes a remarkably labile protein. Pc3/Tis21 has a strong sequence similarity to the human antiproliferative BTG1 gene cloned from a chromosomal translocation of a B-cell chronic lymphocytic leukaemia. This similarity led us to speculate that BTG1 and the putative human homologue of Pc3/Tis21 (named BTG2) were members of a new family of genes involved in growth control and/or differentiation. This hypothesis was recently strengthened by the identification of a new antiproliferative protein, named TOB, which shares sequence similarity with BTG1 and PC3/TIS21 (ref. 7). Here, we cloned and localized the human BTG2 gene. We show that BTG2 expression is induced through a p53-dependent mechanism and that BTG2 function may be relevant to cell cycle control and cellular response to DNA damage.

The mammalian immediate-early TIS21 protein and the leukemia-associated BTG1 protein interact with a protein-arginine N-methyltransferase

The TIS21 immediate-early gene and leukemia-associated BTG1 gene encode proteins with similar sequences. Two-hybrid analysis identified a protein that interacts with TIS21 and BTG1. Sequence motifs associated with S-adenosyl-L-methionine binding suggested this protein might have methyltransferase activity. A glutathione S-transferase (GST) fusion of the putative methyltransferase modifies arginine residues, in appropriate protein substrates, to form NG-monomethyl and NG,NG-dimethylarginine (asymmetric). We term the protein- arginine N-methyltransferase (EC 2.1.1.23) gene "PRMT1, " for protein-arginine methyltransferase 1. GST-TIS21 and GST-BTG1 fusion proteins qualitatively and quantitatively modulate endogenous PRMT1 activity, using control and hypomethylated RAT1 cell extracts as methyl-accepting substrates. PRMT1 message appears ubiquitous, and is constitutive in mitogen-stimulated cells. Modulation of PRMT1 activity by transiently expressed regulatory subunits may be an additional mode of signal transduction following ligand stimulation.

The predominant protein-arginine methyltransferase from Saccharomyces cerevisiae

We have identified the major enzymatic activity responsible for the S-adenosyl-L-methionine-dependent methylation of arginine residues (EC 2.1.1.23) in proteins of the yeast Saccharomyces cerevisiae. The RMT1 (protein-arginine methyltransferase), formerly ODP1, gene product encodes a 348-residue polypeptide of 39.8 kDa that catalyzes both the NG-mono- and NG, NG-asymmetric dimethylation of arginine residues in a variety of endogenous yeast polypeptides. A yeast strain in which the chromosomal RMT1 gene was disrupted is viable, but the level of NG,NG-[3H]dimethylarginine residues detected in intact cells incubated with S-adenosyl-L-[methyl-3H]methionine is reduced to less than 15% of the levels found in the parent strain, while the NG-[3H]monomethylarginine content is reduced to less than 30%. We show that soluble extract from parent cell, but not from mutant rmt1 cells, catalyzes the in vitro methylation of endogenous polypeptides of 55, 41, 38, 34, and 30 kDa. The hypomethylated form of these five polypeptides, as well as that of several others, can be mono- and asymmetrically dimethylated by incubating the mutant rmt1 extract with a purified, bacterially produced, glutathione S-transferase-RMT1 fusion protein and S-adenosyl-L-[methyl-3H]methionine. This glutathione S-transferase-RMT1 fusion protein is also able to methylate a number of mammalian polypeptides including histones, recombinant heterogeneous ribonucleoprotein A1, cytochrome c, and myoglobin, but cannot methylate myelin basic protein. RMT1 appears to be a yeast homolog of a recently characterized mammalian protein-arginine methyltransferase whose activity may be modulated by mitotic stimulation of cells.

Follistatin has characteristics of a primary response gene in porcine granulosa cells

To explore the regulation of follistatin gene expression, porcine granulosa cells were incubated with the translational inhibitor, cycloheximide (CHX), for periods from 6-24 h. This resulted in a 3 to 10-fold increase in follistatin mRNA accumulation compared to vehicle treated control cultures. At 20 h, CHX augmented the follicle stimulating hormone (FSH) induced stimulation of follistatin mRNA accumulation by a mean of more than sixfold. Over 6 h, CHX elevated follistatin mRNA abundance twofold, while epidermal growth factor (EGF) increased the message threefold. CHX in the presence of EGF produced an effect additive to the EGF response. Results in the longer term differed, as pretreatment of granulosa cells with CHX for 20 h suppressed the induction of follistatin gene expression by both EGF and phorbol 12-myristate-13-acetate. By blockade of transcription with Actinomyocin D, an estimate of the half-life of follistatin mRNA between 4 and 8 h was made. Half-life did not appear to be affected by the CHX suppression of protein translation. From the observations of the occurrence of follistatin gene expression independent of protein synthesis, superinduction in the presence of CHX and FSH, and the interactions between CHX and EGF, it is concluded that follistatin is a primary response gene in porcine granulosa cells.

Differential expression of TIS21 and TIS1 genes in the various organs of Balb/c mice, thymic carcinoma tissues and human cancer cell lines

As a part of a series of investigations on the functions of TIS21 and TIS1 genes, we measured in vivo 12-O-tetradecanoylphorbol-13-acetate (TPA) inducibility of primary response genes (TIS21, TIS8 and TIS1) in the Balb/c mice and the changes of TIS gene expression in thymic carcinoma tissues and A549 and NCIH69 human lung cancer cell lines. In vivo induction of the TIS genes (TIS21, -8 and -1) by intraperitoneal injection of TPA was dramatic only at the needle contact site, i.e. in the abdominal muscle, not in the thigh muscle. Expression of TIS21 and TIS1 in the Balb/c mice thymus, lung, stomach and spleen was very strong (Lim IK et al. 1994a), regardless of TPA injection. Thymic carcinoma tissues developed in SV40-T-antigen-containing transgenic mice did not express TIS21 and TIS1, and expressed TIS8 weakly. Interestingly, induction of TIS21 expression was obliterated in the human lung cancer cells; A549 cells completely lost the ability to express TIS21 after a combined treatment of TPA and cycloheximide. We also measured the induction of TIS genes by TPA and/or cycloheximide in Raw264.7 mouse macrophage cells and U937 human histiocytic lymphoma cells. However, the induction profile was quite different; repressed and deregulated expression in the U937 cells as compared to rapid and transient induction of TIS genes in the Raw264.7 cells. These data may suggest a repressed expression of TIS21 and TIS1 in the cancer tissues and cells derived from the organs that constitutively express TIS21 in mice and in human cancer cells.

The transforming receptor tyrosine kinase, Axl, is post-translationally regulated by proteolytic cleavage

Several receptor tyrosine kinases generate soluble ligand binding domains either by differential splicing resulting in a truncated RNA transcript, or by proteolytic cleavage. Although the exact role in vivo of these soluble extracellular domains is unclear, proteolysis may function to down-regulate the receptor, and soluble extracellular domains (ECD) may compete with the intact receptor binding to ligand. Axl is a member of a new class of receptor tyrosine kinases characterized by an ECD resembling cell adhesion molecules and unique sequences in the kinase domain. In addition, Axl is transforming in both fibroblast and hematopoietic cells, and appears to be involved in mesenchymal development. We now find that Axl is post-translationally processed by cleavage in a 14 amino acid region immediately NH2-terminal to the transmembrane domain resulting in a soluble ECD and a membrane bound kinase domain. The sequence of this putative cleavage site shares no homology with recognition sites of known proteases. Characterization of this proteolytic processing shows that it does not require protein synthesis or transport but is augmented by phorbol ester treatment. Since the cleavage of Axl enhances turnover of the kinase on the cell surface, we suggest that proteolytic processing down-regulates Axl kinase activity.

Preferential primary-response gene expression in promotion-resistant versus promotion-sensitive JB6 cells

The 12-O-tetradecanoylphorbol-13-acetate (TPA)-inducible sequence (TIS) genes are a set of primary response genes induced in Swiss 3T3 cells by TPA. They include three transcription factors, a prostaglandin synthase, and three proteins of unknown function. To ascertain which, if any TIS genes might be involved in tumor promotion, we examined the expression of these genes in response to tumor promoters in transformation promotion-sensitive (P+) and -resistant (P-) JB6 murine epidermal cells, a model used to identify events relevant to promotion. A subset of TIS genes (TIS1, TIS10, and TIS21) was preferentially induced by TPA in P-cells. In addition, TIS1 and TIS21 mRNAs were preferentially induced in P-cells by epidermal growth factor, another transformation promoter that distinguishes P+ from P-cells. TIS1 and TIS21 protein levels were also greater in TPA-treated P-cells than P+ cells. Forskolin, a cAMP-elevating anti-promoter, increased TPA-induced levels of TIS1, TIS10, and TIS21 mRNAs in P+ cells, ruling in potential roles for these genes in modulating tumor promotion. The anti-promoters fluocinolone acetonide, retinoic acid, and superoxide dismutase did not enhance TPA-induced levels of TIS1 and TIS21 mRNAs in P+ cells, suggesting that these inhibitors may act on other promotion-relevant genes. TIS1 encodes a member of the steroid receptor superfamily. TIS1 encodes a protein of unknown function with strong sequence similarity to BTG1, a proposed "anti-proliferative gene" (Rouault JP, Rimokh R, Tessa C, et al., EMBO J 11:1663-1670, 1992). Preferential induction by multiple promoters of these TIS genes in P-cells and enhancement of their induction in P+ cells by the anti-promoter forskolin make TIS1 and TIS21 candidates for promotion suppressor genes.

Gem: an induced, immediate early protein belonging to the Ras family

A gene encoding a 35-kilodalton guanosine triphosphate (GTP)-binding protein, Gem, was cloned from mitogen-induced human peripheral blood T cells. Gem and Rad, the product of a gene overexpressed in skeletal muscle in individuals with Type II diabetes, constitute a new family of Ras-related GTP-binding proteins. The distinct structural features of this family include the G3 GTP-binding motif, extensive amino- and carboxyl-terminal extensions beyond the Ras-related domain, and a motif that determines membrane association. Gem was transiently expressed in human peripheral blood T cells in response to mitogenic stimulation; the protein was phosphorylated on tyrosine residues and localized to the cytosolic face of the plasma membrane. Deregulated Gem expression prevented proliferation of normal and transformed 3T3 cells. These results suggest that Gem is a regulatory protein, possibly participating in receptor-mediated signal transduction at the plasma membrane.

Temporal and spatial regulation of the expression of BAD2, a MAP kinase phosphatase, during seizure, kindling, and long-term potentiation

Recent studies indicate that stimulation of NMDA receptors in cultured hippocampal cells activates MAP kinase. Although the pathway whereby MAP kinase is activated has been been characterized, little is known about the mechanisms that shut off MAP kinase. In the course of analyzing several immediate-early genes identified previously by differential screen as inducible by seizure activity, we found that one of them, BAD2, encodes dual purpose, threonine/tyrosine phosphates with specific activity directed against MAP kinase (MKP-1). In situ hybridization of BAD2 demonstrates that stimuli that produce seizure, kindling, and long-term potentiation cause a rapid increase in BAD2 mRNA (within 0.5-1 hr after stimulation) that has, in each case, a distinctive pattern of expression in the brain. In these regions, the induction of a MAP kinase-specific phosphatase may provide a negative feedback control associated with long-term synaptic changes.

Synthesis, degradation, and subcellular localization of proteins encoded by the primary response genes TIS7/PC4 and TIS21/PC3

Murine TIS7 and TIS21 cDNAs were cloned from phorbol ester-induced Swiss 3T3 cells. The cognate rat cDNAs, PC4 and PC3, were cloned from nerve growth factor (NGF)-treated PC12 pheochromocytoma cells. The TIS7/PC4 and TIS21/PC3 primary response genes are rapidly and transiently induced in response to serum, phorbol esters, and polypeptide growth factors in quiescent Swiss 3T3 cells and by NGF and other ligands in PC12 cells. In both 3T3 and PC12 cells the appearance of the TIS21/PC3 message precedes that of TIS7/PC4 message following ligand stimulation, suggesting that the TIS21/PC3 protein is likely to be synthesized more rapidly than the TIS7/PC4 protein. Using antisera prepared against recombinant TIS21 and TIS7 proteins, we find that the TIS21/PC3 protein is, indeed, synthesized more rapidly than the TIS7/PC4 protein following stimulation in both 3T3 and PC12 cells. In addition, "pulse-chase" experiments demonstrate that the TIS21/PC3 protein is degraded much more rapidly than the TIS7/PC4 protein. The sequences of the predicted PC3 and PC4 proteins have lead to the speculation that these two proteins may both be secreted from cells following stimulation. The PC4 protein is reported to have some sequence similarity to interferons. The TIS21/PC3 protein contains a presumptive leader sequence. Using our antisera to the recombinant proteins, however, we cannot detect secretion of radiolabelled TIS7/PC4 or TIS21/PC3 protein. Immunohistochemical and subcellular fractionation experiments suggest that the TIS7 protein is a membrane associated, non-nuclear intracellular protein. The TIS21 protein, in contrast, is a non-nuclear, soluble intracellular protein.

Early responses of PC-12 cells to NGF and EGF: effect of K252a and 5'-methylthioadenosine on gene expression and membrane protein methylation

Although epidermal growth factor (EGF) and nerve growth factor (NGF) have markedly different biological effects on PC-12 cells, many of the signaling events following ligand binding are similar. Both EGF and NGF result in the induction of the primary response gene egr-1/TIS8 and increased methylation of a variety of membrane-associated proteins as early as 5 min after EGF or NGF treatment using a methylation assay that detects methyl esters as well as methylated arginine residues. At 20 min after stimulation with these factors, the stimulation of methylation by NGF is greater than that of EGF, especially in the polypeptides of 36-42 and 20-22 kDa. To help dissect the pathways involved in these cellular responses, the protein kinase inhibitor K252a and the methyltransferase inhibitor 5'-methylthioadenosine (MTA) were used. Both K252a and MTA inhibit NGF-, but not EGF-mediated, primary response gene expression. In contrast, MTA, but not K252a, can block NGF-induced membrane associated protein methylation. These data suggest a role for differential protein methylation reactions in EGF and NGF signal transduction.

Sequence analysis reveals that the BTG1 anti-proliferative gene is conserved throughout evolution in its coding and 3' non-coding regions

The human BTG1 gene (expressing an anti-proliferative function) is an evolutionarily conserved gene homologous to the murine PC3/TIS21 genes. Here, we report the cloning and sequencing of the murine BTG1 coding region and chicken BTG1 cDNA. The putative human and mouse BTG1 proteins are 100% identical; the chicken BTG1 cDNA contains an open reading frame of 170 amino acids with a 91% identity to its human and murine counterparts. The 3'-untranslated region of BTG1 is also highly conserved (82% homology between human and chicken), suggesting that it plays a key role in the regulation of BTG1 expression. These data confirm that BTG1 is phylogenetically highly conserved and that BTG1 and PC3/TIS21 may constitute the first members of a new family of functionally related genes.

Tissue-plasminogen activator is induced as an immediate-early gene during seizure, kindling and long-term potentiation

The requirement of protein and messenger RNA synthesis for long-term memory suggests that neural activity induced by learning initiates a cascade of gene expression. Here we use differential screening to identify five immediate-early genes induced by neuronal activity. One of these is tissue-plasminogen activator (tPA), an extracellular serine protease, which is induced with different spatial patterns in the brain by three activity-dependent events: (1) convulsive seizure increases expression of tPA in the whole brain; (2) stimulation of the perforant path produces an epileptiform after-discharge that ultimately leads to kindling increases the levels of tPA throughout the hippocampus bilaterally; and (3) brief high-frequency stimulation of the perforant path that produces long-term potentiation (LTP) causes an NMDA (N-methyl-D-aspartate) receptor-mediated increase in the levels of tPA mRNA which is restricted to the granule cells of the ipsilateral dentate gyrus. As release of tPA is correlated with morphological differentiation, the increased expression of tPA may play a role in the structural changes that accompany activity-dependent plasticity.

Characterization of peptides bound to the class I MHC molecule HLA-A2.1 by mass spectrometry

Antigens recognized by T cells are expressed as peptides bound to major histocompatibility complex (MHC) molecules. Microcapillary high-performance liquid chromatography-electrospray ionization-tandem mass spectrometry was used to fractionate and sequence subpicomolar amounts of peptides isolated from the MHC molecule HLA-A2.1. Of 200 different species quantitated, eight were sequenced and four were found in cellular proteins. All were nine residues long and shared a distinct structural motif. The sensitivity and speed of this approach should enhance the analysis of peptides from small quantities of virally infected and transformed cells as well as those associated with autoimmune disease states.