Growth-related changes in specific mRNAs of cultured mouse cells

Role of the composite glucocorticoid response element in proliferin gene expression

A binding site for the glucocorticoid receptor in the serum-inducible proliferin gene promoter has been reported to function as a composite glucocorticoid response element when fused to a minimal promoter. We now show that this element can also act as a glucocorticoid-independent negative regulator of transcription, both as an isolated element fused to a minimal promoter and within the context of the proliferin gene promoter. Furthermore, this element is recognized by a factor in mouse fibroblast cell extracts that is distinct from the glucocorticoid receptor and from AP-1, both of which have previously been shown to be able to bind to this site. The ability of this element to repress serum-inducible proliferin promoter activity is dependent on the position of this element with respect to the adjacent serum response region, and on the activity of a positive regulatory element located further upstream in the proliferin promoter.

Cellular Levels of Signaling Factors Are Sensed by β-actin Alleles to Modulate Transcriptional Pulse Intensity

The transcriptional response of β-actin to extra-cellular stimuli is a paradigm for transcription factor complex assembly and regulation. Serum induction leads to a precisely timed pulse of β-actin transcription in the cell population. Actin protein is proposed to be involved in this response, but it is not known whether cellular actin levels affect nuclear β-actin transcription. We perturbed the levels of key signaling factors and examined the effect on the induced transcriptional pulse by following endogenous β-actin alleles in single living cells. Lowering serum response factor (SRF) protein levels leads to loss of pulse integrity, whereas reducing actin protein levels reveals positive feedback regulation, resulting in elevated gene activation and a prolonged transcriptional response. Thus, transcriptional pulse fidelity requires regulated amounts of signaling proteins, and perturbations in factor levels eliminate the physiological response, resulting in either tuning down or exaggeration of the transcriptional pulse.

Dual views of SRF: a genomic exposure

Esnault and colleagues (pp. 943-958) take a genomics approach to investigate the role of SRF (serum response factor) in the serum response of fibroblasts. The well-established dual role of SRF with alternative cofactors and responsiveness to two signaling pathways is illustrated at the genome-wide level, yet new insight comes from this global picture.

Solving the mystery of memory

The word "memory" is derived from the ancient Greek myth of Mnemosyne, the mother of the Muses, who was "said to know everything, past, present, and future." Memory is essential to our existence, and one of neuroscience's primary missions is to understand how the brain processes memory and to improve treatments for Alzheimer's disease, traumatic brain injury, drug addiction, and the many other afflictions associated with disrupted memory. Our article traces scientists' progress in understanding memory over the last 15 years.

S100A4 in esophageal cancer: Is this the one to blame?

Metastasis is the main reason for cancer-related death. S100A4 is one of the key molecules involved in this event. Several studies have shown that overexpression of S100A4 in non-metastatic cancer cells can make them become metastatic, and knockdown of S100A4 in metastatic cancer cells can curtail their invasive nature. A study by Chen et al^[2] published in the World J Gastroenterol 18(9): 915-922, 2012 is a typical example. This study showed in vitro and in vivo evidence that S100A4 expression level determines the invasiveness of esophageal squamous carcinoma. Considering the fact that more than half of the cancer-related deaths are caused by malignancies derived from the digestive system and esophageal cancer is the 4th top contributor to this fraction, this study warrants more attention.

PDGF: the nuts and bolts of signalling toolbox

PDGF is a growth factor and is extensively involved in multi-dimensional cellular dynamics. It switches on a plethora of molecules other than its classical pathway. It is engaged in various transitions of development; however, if the unleashed potentials lead astray, it brings forth tumourigenesis. Conventionally, it has been assumed that the components of this signalling pathway show fidelity and act with a high degree of autonomy. However, as illustrated by the PDGF signal transduction, reinterpretation of recent data suggests that machinery is often shared between multiple pathways, and other components crosstalk to each other through multiple mechanisms. It is important to note that metastatic cascade is an intricate process that we have only begun to understand in recent years. Many of the early steps of this PDGF cascade are not readily targetable in the clinic. In this review, we will unravel the paradoxes with reference to mitrons and cellular plasticity and discuss how disruption of signalling cascade triggers cellular proliferation phase transition and metastasis. We will also focus on the therapeutic interventions to counteract resultant molecular disorders.

Microarray profiling of gene expression patterns in adult male rat brain following acute progesterone treatment

Progesterone can influence various behaviors in adult male rats, however, little is known about which particular genes are regulated by progesterone in the male rat brain. Using focused microarray technology, we where able to define a subset of genes that are responsive to progesterone. Nylon membrane-based cDNA microarrays were used to profile gene expression patterns in the preoptic area/mediobasal hypothalamus (POA/MBH) of male rat brain 7 h following a single injection of progesterone. RNA was isolated from the brains of 6 male rats injected with progesterone and 6 male rats injected with sesame oil. Next, we hybridized the RNA from each animal to individual cDNA microarrays that contained more than 100 target genes, all of which are involved in cAMP and or calcium signaling pathways. Direct side-by-side comparison of all 12 arrays revealed differences in the expression patterns of 12 different genes. We confirmed the data gathered from the arrays on 4 different genes using Real-Time PCR. These data begin to outline the important role played by progesterone in mediating changes in gene expression within the male brain.

Molecular cloning and characterization of rKAB1, which interacts with KARP-1, localizes in the nucleus and protects cells against oxidative death

The Ku autoantigen/KARP-1 (Ku86 autoantigen related protein-1) plays an important role in the double-strand break repair of mammalian DNA as a DNA-binding component of DNA-dependent protein kinase (DNA-PK) complex. KARP-1 is differently transcribed from the human Ku86 autoantigen gene locus and it is implicated in the control of DNA-dependent protein kinase activity. We cloned rKAB1, a rat homolog of KAB1 (KARP-1 binding protein 1 of human) from a rat hippocampal cDNA library. rKAB1 mRNA was specifically expressed in the brain and the thymus. EGFP-tagged rKAB1 protein localized in cell nucleus and in the condensed chromosome during the mitotic cell division. We found that rKAB1 works as a protective protein against cell damage by oxidative stress.

Role of immediate early gene expression in cortical morphogenesis and plasticity

During the development of the central nervous system, there is a fundamental requirement for synaptic activity in transforming immature neuronal connections into organized functional circuits (Katz 1996). The molecular mechanisms underlying activity-dependent adaptive changes in neurons are believed to involve regulated cascades of gene expression. Immediate early genes (IEGs) comprise the initial cascade of gene expression responsible for initiating the process of stimulus-induced adaptive change, and were identified initially as transcription factors that were regulated in brain by excitatory synaptic activity. More recently, a class of neuronal immediate early genes has been identified that encodes growth factors, signaling molecules, extracellular matrix and adhesion proteins, and cytoskeletal proteins that are rapidly and transiently expressed in response to glutamatergic neurotransmission. This review focuses on the neuronal immediate early gene (nIEG) response, in particular, the class of "effector" immediate early gene proteins that may directly modify neuronal and synaptic function.

Overexpression of S100A4 in pancreatic ductal adenocarcinomas is associated with poor differentiation and DNA hypomethylation

Using the National Center for Biotechnology Information Serial Analysis of Gene Expression database, we found that S100A4, a calcium-binding protein previously implicated in metastasis, was expressed in five of seven pancreatic carcinoma libraries but not in the two normal pancreatic duct libraries. We confirmed the overexpression of S100A4 using reverse transcriptase-polymerase chain reaction, which demonstrated that 18 of 19 (95%) pancreatic carcinoma cell lines expressed S100A4. Using immunohistochemistry, we found that 57 of 61 invasive pancreatic carcinomas (93%), 3 of 18 high-grade pancreatic intraepithelial neoplasia lesions (17%), and 0 of the 69 low-grade pancreatic intraepithelial neoplasia lesions expressed S100A4 protein, whereas normal pancreatic tissue and tissue affected by chronic pancreatitis did not label. Expression of S100A4 was associated with poor differentiation of the pancreatic adenocarcinomas (P = 0.001). We found that three CpG sites in the first intron of the S100A4 gene were approximately 90% methylated in microdissected normal pancreatic duct cells using bisulfite-modified sequencing and in two cell lines and three primary pancreatic carcinomas with a reduced or absent expression of S100A4. In contrast, these CpGs were 100% hypomethylated in 11 of 12 pancreatic cancer cell lines by methylation-specific polymerase chain reaction. The association between the expression of S100A4 and hypomethylation of the first intron of S100A4 was statistically significant (P = 0.002). These data suggest that the majority of pancreatic carcinomas undergo selection for hypomethylation and overexpression of S100A4. Because most pancreatic carcinomas express S100A4, it may be a useful target for early detection strategies.

Coexpression of microsomal-type prostaglandin E synthase with cyclooxygenase-2 in brain endothelial cells of rats during endotoxin-induced fever

Fever is triggered by an elevation of prostaglandin E(2) (PGE(2)) in the brain. However, the mechanism of its elevation remains unanswered. We herein cloned the rat glutathione-dependent microsomal prostaglandin E synthase (mPGES), the terminal enzyme for PGE(2) biosynthesis, and examined its induction in the rat brain after intraperitoneal injection of pyrogen lipopolysaccharide (LPS). In Northern blot analysis, mPGES mRNA was weakly expressed in the brain under the normal conditions but was markedly induced between 2 and 4 hr after the LPS injection. In situ hybridization study revealed that LPS-induced mPGES mRNA signals were mainly associated with brain blood vessels, especially vein or venular-type ones, in the whole brain area. Immunohistochemical study demonstrated that mPGES-like immunoreactivity was expressed in the perinuclear region of brain endothelial cells, which were identified as von Willebrand factor-positive cells. Furthermore, in the perinuclear region of the endothelial cells, mPGES was colocalized with cyclooxygenase-2 (COX-2), which is the enzyme essential for the production of the mPGES substrate PGH(2). Inhibition of cyclooxygenase-2 activity resulted in suppression of both PGE(2) level in the CSF and fever (Cao et al., 1997), suggesting that the two enzymes were functionally linked and that this link is essential for fever. These results demonstrate that brain endothelial cells play an essential role in the PGE(2) production during fever by expressing COX-2 and mPGES.

Coexpression of microsomal-type prostaglandin E synthase with cyclooxygenase-2 in brain endothelial cells of rats during endotoxin-induced fever

Fever is triggered by an elevation of prostaglandin E(2) (PGE(2)) in the brain. However, the mechanism of its elevation remains unanswered. We herein cloned the rat glutathione-dependent microsomal prostaglandin E synthase (mPGES), the terminal enzyme for PGE(2) biosynthesis, and examined its induction in the rat brain after intraperitoneal injection of pyrogen lipopolysaccharide (LPS). In Northern blot analysis, mPGES mRNA was weakly expressed in the brain under the normal conditions but was markedly induced between 2 and 4 hr after the LPS injection. In situ hybridization study revealed that LPS-induced mPGES mRNA signals were mainly associated with brain blood vessels, especially vein or venular-type ones, in the whole brain area. Immunohistochemical study demonstrated that mPGES-like immunoreactivity was expressed in the perinuclear region of brain endothelial cells, which were identified as von Willebrand factor-positive cells. Furthermore, in the perinuclear region of the endothelial cells, mPGES was colocalized with cyclooxygenase-2 (COX-2), which is the enzyme essential for the production of the mPGES substrate PGH(2). Inhibition of cyclooxygenase-2 activity resulted in suppression of both PGE(2) level in the CSF and fever (Cao et al., 1997), suggesting that the two enzymes were functionally linked and that this link is essential for fever. These results demonstrate that brain endothelial cells play an essential role in the PGE(2) production during fever by expressing COX-2 and mPGES.

Regulation of SSAT expression by synaptic activity

Neuronal activity is a requirement for the plasticity and normal development of the central nervous system. We have used differential cloning techniques to identify an immediate-early gene (IEG) that is rapidly induced in neurons by activity in both adult and developmental models of plasticity. Here we describe the key regulatory enzyme of polyamine catabolism, spermidine/spermine N1-acetyltransferase (SSAT), as a neuronal IEG. In the rat brain, kainate-induced seizures result in a 5.5-fold increase in the amount of SSAT mRNA above basal levels and the enzymatic activity is increased twofold. Expression of SSAT mRNA is rapidly and transiently upregulated in the cerebral cortex and hippocampus by seizure-induced neuronal activation. In hippocampal neurons, SSAT expression is dynamically responsive to synaptic activity in the long-term potentiation (LTP) paradigm. In developing brain, region-specific expression of SSAT mRNA is first detected at postnatal day 9 (P9) and subsequently increases through days P15, P20, before reaching maximal level in adult animals. This dynamic transcriptional and translational control suggests that SSAT may play a role in activity-dependent neuronal plasticity and development.

Overexpression of protein kinase C delta represses expression of proliferin in NIH3T3 cells that regulates cell proliferation

Protein kinase C (PKC) delta is known to inhibit proliferation of many cell types. In this study we found that overexpression of PKCdelta reduced proliferation of NIH3T3 cells. To identify specific genes regulated by PKCdelta in regulation of cell proliferation, we used differential display-polymerase chain reaction in PKCdelta-overexpressing NIH3T3 cells and found that the expression of proliferin, a secreted protein known to stimulate cell proliferation, was significantly repressed. Transient transfection study indicated that the repression of proliferin expression was inversely proportional to the expression levels of PKCdelta. Addition of an anti-proliferin antibody to culture medium to neutralize the secreted proliferin decreased cell proliferation in a dose-dependent manner. Our results, therefore, suggest that overexpression of PKCdelta induces transcriptional repression of proliferin, thereby resulting in inhibition of cell proliferation.

Is epilepsy a progressive disease? The neurobiological consequences of epilepsy

While primary, or idiopathic, epilepsies may exist, in the vast majority of cases epilepsy is a symptom of an underlying brain disease or injury. In these cases, it is difficult if not impossible to dissociate the consequences of epilepsy from the consequences of the underlying disease, the treatment of either the disease or the epilepsy, or the actual seizures themselves. Several cases of apparent complications of epilepsy are presented to illustrate the range of consequences encountered in clinical practice and the difficulty in assigning blame for progressive symptomatology in individual cases. Because of the difficulty in interpreting clinical material, many investigators have turned to epilepsy models in order to address the potential progressive consequences of recurrent seizures. The authors review experimental data, mainly from animal models, that illustrate short-, medium-, and long-term morphological and biochemical changes in the brain occurring after seizures, and attempt to relate these observations to the human condition.

Inhibition of activity-dependent arc protein expression in the rat hippocampus impairs the maintenance of long-term potentiation and the consolidation of long-term memory

It is widely believed that the brain processes information and stores memories by modifying and stabilizing synaptic connections between neurons. In experimental models of synaptic plasticity, such as long-term potentiation (LTP), the stabilization of changes in synaptic strength requires rapid de novo RNA and protein synthesis. Candidate genes, which could underlie activity-dependent plasticity, have been identified on the basis of their rapid induction in brain neurons. Immediate-early genes (IEGs) are induced in hippocampal neurons by high-frequency electrical stimulation that induces LTP and by behavioral training that results in long-term memory (LTM) formation. Here, we investigated the role of the IEG Arc (also termed Arg3.1) in hippocampal plasticity. Arc protein is known to be enriched in dendrites of hippocampal neurons where it associates with cytoskeletal proteins (Lyford et al., 1995). Arc is also notable in that its mRNA and protein accumulate in dendrites at sites of recent synaptic activity (Steward et al., 1998). We used intrahippocampal infusions of antisense oligodeoxynucleotides to inhibit Arc protein expression and examined the effect of this treatment on both LTP and spatial learning. Our studies show that disruption of Arc protein expression impairs the maintenance phase of LTP without affecting its induction and impairs consolidation of LTM for spatial water task training without affecting task acquisition or short-term memory. Thus, Arc appears to play a fundamental role in the stabilization of activity-dependent hippocampal plasticity.

Inhibition of activity-dependent arc protein expression in the rat hippocampus impairs the maintenance of long-term potentiation and the consolidation of long-term memory

It is widely believed that the brain processes information and stores memories by modifying and stabilizing synaptic connections between neurons. In experimental models of synaptic plasticity, such as long-term potentiation (LTP), the stabilization of changes in synaptic strength requires rapid de novo RNA and protein synthesis. Candidate genes, which could underlie activity-dependent plasticity, have been identified on the basis of their rapid induction in brain neurons. Immediate-early genes (IEGs) are induced in hippocampal neurons by high-frequency electrical stimulation that induces LTP and by behavioral training that results in long-term memory (LTM) formation. Here, we investigated the role of the IEG Arc (also termed Arg3.1) in hippocampal plasticity. Arc protein is known to be enriched in dendrites of hippocampal neurons where it associates with cytoskeletal proteins (Lyford et al., 1995). Arc is also notable in that its mRNA and protein accumulate in dendrites at sites of recent synaptic activity (Steward et al., 1998). We used intrahippocampal infusions of antisense oligodeoxynucleotides to inhibit Arc protein expression and examined the effect of this treatment on both LTP and spatial learning. Our studies show that disruption of Arc protein expression impairs the maintenance phase of LTP without affecting its induction and impairs consolidation of LTM for spatial water task training without affecting task acquisition or short-term memory. Thus, Arc appears to play a fundamental role in the stabilization of activity-dependent hippocampal plasticity.

Absence of S100A4 (mts1) gene mutations in various canine and feline tumours. Detection of a polymorphism in feline S100A4 (mts1)

Ninety canine and 101 feline tumours of various types were investigated for gene mutations in the coding regions of the metastasis-associated gene S100A4 (mts1). No gene mutations were present in the analysed genomic area. A widespread histidine/tyrosine polymorphism was detected in codon 17 of S100A4.

Induction of S100A4 gene expression inhibits in vitro invasiveness of human squamous cell carcinoma, KOSC-3 cells

S100A4 is considered functionally involved in metastasis and invasiveness of rodent and human mammary tumors. We screened the expression of S100A4 in human squamous cell carcinoma cell lines, and found 2 cell lines which were highly invasive, but did not express any noticeable extent of S100A4. To examine whether the expression of S100A4 regulated invasiveness of squamous cell carcinoma, we transfected S100A4 cDNA into KOCS-3 and HSC-4 squamous cell carcinoma cells. The transfectants from KOSC-3 cells expressing sense S100A4 decreased invasiveness by 80% compared with cells of the wild type or those with the vector only.

Molecular cloning and characterization of Amida, a novel protein which interacts with a neuron-specific immediate early gene product arc, contains novel nuclear localization signals, and causes cell death in cultured cells

Amida was isolated by the yeast two-hybrid system as a novel protein which associated with Arc, a non-transcriptional immediate early gene specific to the brain. Amida was confirmed to be associated with Arc in vitro and in vivo. Amida shows no homology to known proteins. Amida is ubiquitously expressed, although it is abundant in the brain. A transfection study revealed that Amida was localized in the nucleus and after 72 h the transfected cells underwent apoptosis. Furthermore, we found two nuclear localization signals and a domain needed for interacting with Arc was encompassed by two nuclear localization signals. Co-transfection experiment with Amida and Arc suggested that Amida transported Arc into the nucleus and negatively regulated Amida-induced cell death. These results indicate that Arc together with Amida may modulate cell death in the brain.

A unique bFGF-responsive transcriptional element

The mitogen-regulated protein/proliferin (mrp/plf) genes encode closely related proteins that stimulate cell proliferation and angiogenesis. Basic fibroblast growth factor (bFGF) increases mrp/plf mRNA and protein production by 3T3 cells. Although the three cloned mrp/plf gene promoters are over 97% identical, only mrp3 is transcriptionally activated by bFGF. A series of truncated mrp3 promoter sequences were tested to determine the minimal promoter sequence necessary for bFGF-responsive transcription. Within the minimal bFGF-responsive mrp3 promoter fragment, a putative FGF-regulatory element (FRE) was identified. Nuclear factors that bind the FRE are present in 3T3 cells. When present upstream of a thymidine kinase basal promoter, the FRE exhibits high transcriptional activity and responds to bFGF. Thus, the FRE is a strong transcriptional element that is regulated by bFGF and that may participate in regulating the mrp3 gene and perhaps other FGF-regulated genes.

Arcadlin is a neural activity-regulated cadherin involved in long term potentiation

Neural activity results in long term changes that underlie synaptic plasticity. To examine the molecular basis of activity-dependent plasticity, we have used differential cloning techniques to identify genes that are rapidly induced in brain neurons by synaptic activity. Here, we identify a novel cadherin molecule Arcadlin (activity-regulated cadherin-like protein). arcadlin mRNA is rapidly and transiently induced in hippocampal granule cells by seizures and by N-methyl-D-aspartate-dependent synaptic activity in long term potentiation. The extracellular domain of Arcadlin is most homologous to protocadherin-8; however, the cytoplasmic region is distinct from that of any cadherin family member. Arcadlin protein is expressed at the synapses and shows a homophilic binding activity in a Ca2+-dependent manner. Furthermore, application of Arcadlin antibody reduces excitatory postsynaptic potential amplitude and blocks long term potentiation in hippocampal slices. Its close homology with cadherins, its rapid inducibility by neural activity, and its involvement in synaptic transmission suggest that Arcadlin may play an important role in activity-induced synaptic reorganization underlying long term memory.

Identification and characterization of mRNAs differentially expressed in thyroid cells stimulated by a mitogenic treatment

The aim of our work is to identify new genes and proteins involved in the control of the proliferation of thyroid cells as putative protooncogenes and antioncogenes. Several strategies are discussed. A first study has allowed to identify three new genes. Further search will use the differential display and gene arrays methodology. The role of the identified proteins coded by the genes is studied in vitro by the search of partner proteins by the double hybrid method and in vivo by mice gene knockout technology.

Calcium-binding protein S100A4 in health and disease

The S100 proteins contain two EF-hand motifs and are of generally unknown function. One of these proteins, S100A4, is an intracellular calcium-binding protein that is present in normal rodent and human cells. In cultured rodent mammary cells, S100A4 is expressed at a higher level in some metastatic epithelial cells than in non-metastatic counterparts. Similarly, in human breast cell lines, S100A4 is present at a higher level in cultured cells from the more malignant, than in those from the more benign tumours. Gene transfer experiments have shown that rodent or human S100A4 is able to induce metastatic capability in otherwise non-metastatic breast tumour cells. Furthermore, expression of rodent S100A4 transgenes can induce metastasis of benign tumours arising in transgenic model systems. Possible mechanisms for the metastasis-inducing effect of S100A4 and the relevance of these observations to human cancer are discussed.

Coordinated induction of inducible nitric oxide synthase and GTP-cyclohydrolase I is dependent on inflammatory cytokines and interferon-gamma in HaCaT keratinocytes: implications for the model of cutaneous wound repair

Recently we demonstrated a strong expression of inducible nitric oxide synthase (iNOS) and GTP-cyclohydrolase I (GTP-CH I) in the basal keratinocytes of the epidermis adjacent to the wound and of the hyperproliferative epithelium during wound healing. To identify possible mediators of iNOS and GTP-CH I expression during this process, we analyzed the regulation of iNOS and GTP-CH I expression in cultured human keratinocytes. We found a large and long lasting coinduction of iNOS and GTP-CH I expression upon simultaneous treatment of quiescent cells with inflammatory cytokines interleukin-1beta, tumor necrosis factor-alpha, and interferon-gamma, but not with serum growth factors. The stimulatory effect of interleukin-1beta, tumor necrosis factor-alpha, and interferon-gamma is strongly synergistic on iNOS and GTP-CH I expression, because these factors alone stimulated GTP-CH I expression, although to a much lesser extent. Furthermore, iNOS mRNA levels are not influenced at all by stimulation with IL-1beta and revealed only a weak induction after treatment with tumor necrosis factor-alpha and interferon-gamma. Induction of iNOS and GTP-CH I gene expression upon cytokine and interferon-gamma exposure is independent of de novo protein synthesis. Because these cytokines are present at the wound site, they might be responsible for iNOS and GTP-CH I induction during cutaneous repair. Serum, which is released upon hemorrhage, is likely to play no stimulatory role in iNOS and GTP-CH I induction during wound healing.

Dynamic regulation of RGS2 suggests a novel mechanism in G-protein signaling and neuronal plasticity

Long-term neuronal plasticity is known to be dependent on rapid de novo synthesis of mRNA and protein, and recent studies provide insight into the molecules involved in this response. Here, we demonstrate that mRNA encoding a member of the regulator of G-protein signaling (RGS) family, RGS2, is rapidly induced in neurons of the hippocampus, cortex, and striatum in response to stimuli that evoke plasticity. Although several members of the RGS family are expressed in brain with discrete neuronal localizations, RGS2 appears unique in that its expression is dynamically responsive to neuronal activity. In biochemical assays, RGS2 stimulates the GTPase activity of the alpha subunit of Gq and Gi1. The effect on Gi1 was observed only after reconstitution of the protein in phospholipid vesicles containing M2 muscarinic acetylcholine receptors. RGS2 also inhibits both Gq- and Gi-dependent responses in transfected cells. These studies suggest a novel mechanism linking neuronal activity and signal transduction.

Dynamic regulation of RGS2 suggests a novel mechanism in G-protein signaling and neuronal plasticity

Long-term neuronal plasticity is known to be dependent on rapid de novo synthesis of mRNA and protein, and recent studies provide insight into the molecules involved in this response. Here, we demonstrate that mRNA encoding a member of the regulator of G-protein signaling (RGS) family, RGS2, is rapidly induced in neurons of the hippocampus, cortex, and striatum in response to stimuli that evoke plasticity. Although several members of the RGS family are expressed in brain with discrete neuronal localizations, RGS2 appears unique in that its expression is dynamically responsive to neuronal activity. In biochemical assays, RGS2 stimulates the GTPase activity of the alpha subunit of Gq and Gi1. The effect on Gi1 was observed only after reconstitution of the protein in phospholipid vesicles containing M2 muscarinic acetylcholine receptors. RGS2 also inhibits both Gq- and Gi-dependent responses in transfected cells. These studies suggest a novel mechanism linking neuronal activity and signal transduction.

Serum- and polypeptide growth factor-inducible gene expression in mouse fibroblasts

Complex cellular processes such as proliferation, differentiation, and apoptosis are regulated in part by extracellular signaling molecules: for example, polypeptide growth factors, cytokines, and peptide hormones. Many polypeptide growth factors exert their mitogenic effects by binding to specific cell surface receptor protein tyrosine kinases. This interaction triggers numerous biochemical responses, including changes in phospholipid metabolism, the activation of a protein phosphorylation cascade, and the enhanced expression of specific immediate-early, delayed-early, or late response genes. In this review, I summarize the major findings obtained from studies investigating the effects of serum or individual polypeptide growth factors on gene expression in murine fibroblasts. Several experimental approaches, including differential hybridization screening of cDNA libraries and differential display, have been employed to identify mRNA species that are expressed at elevated levels in serum- or polypeptide growth factor-stimulated cells. These studies have demonstrated that serum- and growth factor-inducible genes encode a diverse family of proteins, including DNA-binding transcription factors, cytoskeletal and extracellular matrix proteins, metabolic enzymes, secreted chemokines, and serine-threonine kinases. Some of these gene products act as effectors of specific cell cycle functions (e.g., enzymes involved in nucleotide and DNA synthesis), others are required to successfully convert a metabolically inactive cell to a metabolically active cell that will eventually increase in size and then divide (e.g., glucose-metabolizing enzymes), and some actually function as positive or negative regulators of cell cycle progression. In conclusion, research conducted during the past 15 years on serum- and growth factor-regulated gene expression in murine fibroblasts has provided significant insight into mitogenic signal transduction and cell growth control.

Proto-oncogene Sno expression, alternative isoforms and immediate early serum response

The mouse Sno gene, a Ski proto-oncogene homolog, expresses two isoforms, SnoN and SnoN2 (also called sno -dE3), which differ from each other in a location downstream from the site of alternative splicing previously described in the human SNO gene. SnoN2 is missing a 138 nt coding segment present in mouse SnoN and human SNON . We have cloned and sequenced the human ortholog of mouse SnoN2 , the existence of which was predicted from conservation of the alternative splice donor site that produces the SnoN2 isoform. Mouse SnoN2 and SnoN are expressed throughout embryonic development, in neonatal muscle and in many adult tissues. SnoN2 is the major species in most tissues, but SnoN and SnoN2 are expressed at approximately equal levels in brain. In human tissues, SNON2 is the less abundantly expressed isoform. Expression of mouse SnoN and SnoN2 mRNAs is induced with immediate early kinetics upon serum stimulation of quiescent fibroblasts, even in the presence of the protein synthesis inhibitor cycloheximide, while Ski is not. Interestingly, although both isoforms of Sno are induced, SnoN2 induction is much higher than SnoN . These data are consistent with a role for Sno in the response to proliferation stimuli.

Modulation of S-100 genes response to growth conditions in human epithelial tumor cells

Many new members of the S-100 genes are known to be associated with cell differentiation, malignant transformation, and cell cycle. Of the S-100 genes examined in the present study, calcyclin, calpactin I light chain and calvasculin were expressed in most human epithelial tumor cells, and their expression levels differed according to various growth conditions. Their transcribed levels differed depending on each cell line, but their expression patterns were similarly changed under growth-modulatory conditions. Their messenger RNA levels increased parallel to the S phase population of cells, and decreased at G1/G2 phases. In contrast, this expression diminished in tumor cells under growth-inhibitory conditions, such as treatment with topoisomerase II inhibitor VP-16 or phorbol 12-myristate 13-acetate.

Identification and characterization of novel genes modulated in the thyroid of dogs treated with methimazole and propylthiouracil

Induction of cell proliferation by mitogen or growth factor stimulation leads to the specific stimulation or repression of a large number of genes. To better understand differentiated epithelial cell growth regulation, we have initiated a study to identify genes which are regulated by the thyrotropin-dependent mitogenic pathway in dog thyroid cells. A thyroid cDNA library was prepared from a methimazole and propylthiouracil-treated dog and differentially screened with probes derived from control or stimulated thyroids. Among 19 clones isolated, 6 encode known proteins (inwardly rectifying potassium channel, nucleosome assembly protein, ribosomal protein L7, elongation factor 1alpha, non-muscle myosin light chain, and heat shock protein 90beta). The 13 others correspond to proteins whose function is unknown. Among them, 5 correspond to mRNAs whose expression was modulated by mitogenic stimulation of thyrocytes in primary culture. A preliminary characterization of two of these cDNAs is reported: clone 5, which might represent a novel, atypical protein kinase, and clone 3, which contains ankyrin-like repeats, suggesting that it might interact with other proteins.

Identification and characterization of a fibroblast marker: FSP1

We performed subtractive and differential hybridization for transcript comparison between murine fibroblasts and isogenic epithelium, and observed only a few novel intracellular genes which were relatively specific for fibroblasts. One such gene encodes a filament-associated, calcium-binding protein, fibroblast-specific protein 1 (FSP1). The promoter/enhancer region driving this gene is active in fibroblasts but not in epithelium, mesangial cells or embryonic endoderm. During development, FSP1 is first detected by in situ hybridization after day 8.5 as a postgastrulation event, and is associated with cells of mesenchymal origin or of fibroblastic phenotype. Polyclonal antiserum raised to recombinant FSP1 protein stained the cytoplasm of fibroblasts, but not epithelium. Only occasional cells stain with specific anti-FSP1 antibodies in normal parenchymal tissue. However, in kidneys fibrosing from persistent inflammation, many fibroblasts could be identified in interstitial sites of collagen deposition and also in tubular epithelium adjacent to the inflammatory process. This pattern of anti-FSP1 staining during tissue fibrosis suggests, as a hypothesis, that fibroblasts in some cases arise, as needed, from the local conversion of epithelium. Consistent with this notion that FSP1 may be involved in the transition from epithelium to fibroblasts are experiments in which the in vitro overexpression of FSP1 cDNA in tubular epithelium is accompanied by conversion to a mesenchymal phenotype, as characterized by a more stellate and elongated fibroblast-like appearance, a reduction in cytokeratin, and new expression of vimentin. Similarly, tubular epithelium submerged in type I collagen gels exhibited the conversion to a fibroblast phenotype which includes de novo expression of FSP1 and vimentin. Use of the FSP1 marker, therefore, should further facilitate both the in vivo studies of fibrogenesis and the mapping of cell fate among fibroblasts.

Growth and differentiation proceeds normally in cells deficient in the immediate early gene NGFI-A

NGFI-A (also known as EGR-1, zif/268, and Krox-24) is a zinc finger transcription factor induced in many cell types by a variety of growth and differentiation stimuli. To determine if NGFI-A plays a requisite role in these processes, we used homologous recombination to mutate both alleles of NGFI-A in embryonic stem (ES) cells and examined its effect on growth and differentiation. We find that ES cells lacking NGFI-A exhibit similar growth rates and serum-induced gene expression profiles compared to wild-type parental cells. They are capable of differentiating into neurons, cardiac myocytes, chondrocytes, and squamous epithelium. Chimeric mice were generated from targeted ES cells, and their progeny were crossed to produce homozygous mutant mice. Growth and histological analyses of mice lacking NGFI-A confirm the finding in ES cells that NGFI-A is not required for many of the processes associated with its expression and suggest that the function of NGFI-A is either more subtle in vivo or masked by redundant expression provided by other gene family members such as NGFI-C, Krox-20, or EGR3.

Characterization of a delayed early serum response region

The proliferin (PLF) gene promoter provides a relatively simple model system for the study of growth-regulated gene expression in mouse cells. The promoter elements required for this serum-induced regulation have been identified and include an AP-1 site as well as an adjacent element comprised of three imperfect repeats that are similar in sequence to the simian virus 40 (SV40) Sph motif. Distinct protein complexes bound independently to the AP-1 and Sph elements, and both of these juxtaposed sites could be occupied simultaneously. Furthermore, serum stimulation of mouse fibroblasts resulted in similar increases in protein binding to the AP-1 and Sph elements. Consistent with this increase in AP-1 and Sph binding activity, the PLF AP-1 and Sph elements were independently able to confer serum responsiveness to a minimal promoter, and together these two elements acted synergistically in response to serum. Although several members of the AP-1 family were able to activate the PLF gene promoter in transient cotransfection experiments, the predominant AP-1 components interacting with the PLF gene promoter in serum-stimulated cells were Fra-1, JunB, and JunD. Analysis of the Sph element revealed that mutation of Sph repeats I or III abolished serum responsiveness of the PLF gene promoter, and mutation of Sph repeat III decreased protein binding to this element. Although the Sph element is similar in sequence to the SV40 element, the PLF Sph-binding factor is distinct from TEF-1, the factor that binds to the SV40 Sph motif.

Characterization of a delayed early serum response region

The proliferin (PLF) gene promoter provides a relatively simple model system for the study of growth-regulated gene expression in mouse cells. The promoter elements required for this serum-induced regulation have been identified and include an AP-1 site as well as an adjacent element comprised of three imperfect repeats that are similar in sequence to the simian virus 40 (SV40) Sph motif. Distinct protein complexes bound independently to the AP-1 and Sph elements, and both of these juxtaposed sites could be occupied simultaneously. Furthermore, serum stimulation of mouse fibroblasts resulted in similar increases in protein binding to the AP-1 and Sph elements. Consistent with this increase in AP-1 and Sph binding activity, the PLF AP-1 and Sph elements were independently able to confer serum responsiveness to a minimal promoter, and together these two elements acted synergistically in response to serum. Although several members of the AP-1 family were able to activate the PLF gene promoter in transient cotransfection experiments, the predominant AP-1 components interacting with the PLF gene promoter in serum-stimulated cells were Fra-1, JunB, and JunD. Analysis of the Sph element revealed that mutation of Sph repeats I or III abolished serum responsiveness of the PLF gene promoter, and mutation of Sph repeat III decreased protein binding to this element. Although the Sph element is similar in sequence to the SV40 element, the PLF Sph-binding factor is distinct from TEF-1, the factor that binds to the SV40 Sph motif.

Egr3/Pilot, a zinc finger transcription factor, is rapidly regulated by activity in brain neurons and colocalizes with Egr1/zif268

Programs of gene activation may underlie long-term adaptive cellular responses to extracellular ligands. We have used a differential cDNA cloning strategy to identify genes that are strongly induced by excitatory stimuli in the adult rat hippocampus. Here, we report the rat cDNA sequence of a zinc-finger transcription factor, Egr3/Pilot, and characterize its regulated mRNA expression in brain. Egr3 mRNA is rapidly and transiently induced in neurons of the hippocampus and cortex by electroconvulsive seizure. mRNA levels peak 2 hr after the seizure and remain elevated for as long as 8 hr. Egr3 mRNA is also rapidly induced in granule cells of the dentate gyrus by synaptic NMDA receptor activation elicited by patterned stimulation of the perforant pathway and by drugs that alter dopamine neurotransmission in the striatum. Basal levels of Egr3 mRNA in the cortex appear to be driven by natural synaptic activity because monocular deprivation rapidly decreases Egr3 mRNA in the deafferented visual cortex. Aspects of the protein structure, sequence-specific DNA binding, transcriptional activity, and regulation of Egr3 are highly similar to another zinc-finger transcription factor, Egr1/zif268. Moreover, we demonstrate colocalization of Egr3 and zif268 mRNAs in neurons of normal and stimulated cortex. Our studies suggest that interactions between these coregulated transcription factors may be important in defining long-term, neuroplastic responses.

Modulation of mts1 expression in mouse and human normal and tumor cells

The mts1 gene, encoding small Ca(2+)-binding protein of the S100-family, is considered as a gene whose activity correlates with the manifestation of a metastatic phenotype of tumor cells. It was shown before that the mts1 is expressed not only in metastatic tumor cells but also in some normal tissues, namely in so-called "lymphoid" organs: spleen, thymus, bone marrow. In this work we analyzed in more detail the expression of mts1 in human and mouse hematopoietic cells and cell lines. A high level of mts1 RNA was observed in T-lymphocytes, neutrophils, monocytes/macrophages and in corresponding cell lines. Controversially, the mts1 gene was silent in B-lymphocytes as well as in myeloma and erythroleukemia cell lines. The possibility of modulating the mts1 gene expression by the action of different agents was demonstrated. Mitogens, such as lipopolysaccharides (LPS), interferon (IFN gamma), and concanavalin A (Con A), modulate the level of the mts1 gene expression in hematopoietic cells differently. Calcium ionophore, A23187, can also be regarded as a modulator of the mts1 gene expression, since its addition to the cells results in a substantial decrease of the mts1 RNA level. It was shown that the mts1 RNA's half-life is relatively long, more than 24 h. We therefore believe that calcium ionophore can activate some ribonucleases which degrade the mts1 RNA. Cycloheximide prevents the effect of A23187 and stabilizes the mts1 RNA, probably by blocking the synthesis of these nucleases. Thus, the obtained data indicate that the agents which are capable of changing the physiological status of the cells also modulate the mts1 gene expression.

SnoI, a novel alternatively spliced isoform of the ski protooncogene homolog, sno

We have cloned and sequenced a novel human isoform of sno, snoI for insertion. SnoI contains 1330 nucleotides inserted in place of 7 nucleotides of the snoN mRNA. Sno is a member of the ski protooncogene family, which has been implicated in muscle development. The two previously known sno alternatively spliced isoforms are snoN (684 amino acids), and snoA (415 amino acids); snoI encodes a truncated isoform of 399 amino acids (44,298 MW). Southern blot experiments show that snoI contains a third alternative exon from the sno gene; a single sno gene can express all three isoforms of sno by alternative splicing. All three isoforms contain the region that is most similar to the ski proto-oncogene. The relationship between snoI and snoN is analogous to that between delta fosB and fosB, where a truncated form of the fosB transcription factor is produced by alternative splicing. We find conservation of human snoI-specific sequences in several mammalian species, in monkey, dog, cow, rabbit and pig, but not in rodents, whereas the common portion of the sno gene is conserved in all vertebrate species tested. SnoN, snoA, and ski mRNAs accumulate in many human tissues including skeletal muscle; the snoI alternative mRNA accumulates more specifically in skeletal muscle. SnoI is also expressed in rhabdomyosarcoma tumor, a tumor that contains differentiated skeletal muscle. The tissue-specific alternative splicing of human snoI, an mRNA in the ski/sno gene family, and the presence of sno mRNAs in muscle are consistent with a proposed role for the sno oncogene in muscle gene regulation.

Transcriptional analysis of the mts1 gene with specific reference to 5' flanking sequences

The mts1 gene is specifically expressed in certain metastatic tumors but not in their nonmetastatic counterparts. It is also expressed in several normal cell and tissue types that exhibit the ability to be motile. The gene was cloned from both mouse and human sources and the 5' flanking regions were sequenced. The sequencing data revealed a 135-base-pair region of high homology between the mouse and human mts1 gene. This homology was observed in the vicinity of the TATA box. The 5' region of the mts1 gene was also observed to have a high degree of homology to some known promoter and enhancer sequences. To determine the role this region plays in regulating the transcription of mts1, promoter analysis was performed. Sixteen constructs were prepared in which the chloramphenicol acetyltransferase gene was fused to different regions of the mouse mts1 promoter. These constructs were analyzed in transient transfection assays in two related cell lines derived from mouse mammary adenosarcomas: CSML-0, a nonmetastatic cell line with low levels of mts1 expression, and CSML-100, a metastatic cell line with high levels of mts1 expression. Results of our transient transfection assays in conjunction with results obtained from in vitro and in vivo footprinting of the promoter region show no evidence of cis-acting control elements important for the transcriptional regulation of mts1 in these cell lines. A few nucleotides upstream of the TATA box are sufficient for maximal levels of mts1 transcription. Because no cis-acting control elements were found, restriction of mts1 transcription in CSML-0 cells must exist on some other level. mts1 was found to be hypermethylated in CSML-0 cells but not in CSML-100 cells. The possible role of methylation in progression of the nonmetastatic CSML-0 adenosarcoma cell line toward the metastatic CSML-100 adenosarcoma cell line is discussed.

Differential expression of cytochrome oxidase (COX) genes in different regions of monkey brain

A frontal pole cDNA library from monkey (Macaca mulatta) brain was screened to identify mRNAs that are expressed more in frontal pole as compared to primary visual cortex. Three cDNA clones, whose greater expression was confirmed by Northern blot analysis, were identified as cytochrome oxidase (COX) subunits I, II, and III (COX I, II, and III). Each clone showed higher levels of mRNA in the frontal pole, dorsal lateral prefrontal cortex, and hippocampus than in the primary visual or somatosensory cortices. COX histochemistry of prefrontal, visual, and somatosensory cortical regions demonstrated heterogeneous distributions, with highest activity in dendrite-rich neuropil of the cortex. A laminar distribution of COX mRNA expression also was demonstrated with in situ hybridization. mRNA was detected in cell bodies and in apical dendrites. These results indicate region specific differences in the distribution of COX activity and in the corresponding mRNA for three of its subunits within the monkey brain. Such differences may be related to differences in the distribution of neuropil as compared with cell bodies among the brain regions studied, and may be relevant to selective vulnerability in Alzheimer's disease.

Lithium stimulation of HPP-CFC and stromal growth factor production in murine Dexter culture

We have previously reported that the addition of lithium chloride (LiCl) to murine Dexter cultures results in increased numbers of progenitor and mature hematopoietic cells of the granulocyte, macrophage, and megakaryocyte lineages. We now report the effect of various levels of LiCl on the high proliferative potential colony-forming cell (HPP-CFC) in Dexter culture and on the induction of growth factors from Dexter stromal cells. LiCl (4 mEq/L) stimulated supernatant HPP-CFC for the first 4 weeks of culture (150-275%), and stimulated stromal HPP-CFC at week 3 (170-222%). Higher levels of lithium (8 and 12 mEq/L) selectively stimulated supernatant HPP-CFC, macrophage, and eosinophil production, whereas granulocytes and granulocyte-macrophage colony-forming cells (CFU-C) were inhibited. mRNA expression was evaluated from week 4 Dexter cultures that received a pulse or continuous exposure to lithium and had received either 0 or 1,100 cGy irradiation. Four mEq/L LiCl stimulated increased expression of G-CSF, GM-CSF, IL-6, and, in the nonirradiated stroma continuously exposed to lithium, CSF-1 mRNA. In general, the higher levels of lithium stimulated increased mRNA expression for these same growth factors. mRNA for the recently described Steel factor was decreased with increasing levels of lithium added to either normal or irradiated stroma. Bioassays of conditioned medium (cm) from irradiated cultures against the FDC-P1 and T1165 cell lines indicated cytokine activity, which was blocked by antibodies to GM-CSF and IL-6, respectively. Altogether these data show that lithium stimulates Dexter HPP-CFC, and this stimulation appears to be mediated by multiple growth factors that are induced from stromal cells.

D1Dopamine Receptor Activation of Multiple Transcription Factor Genes in Rat Striatum

Recent studies have shown that dopamine receptor agonists induce expression of Fos-like immunoreactivity in rat striatal neurons. The protooncogene c-fos belongs to a family of immediate early genes that are rapidly induced in fibroblasts by growth factors. In light of previous findings that several immediate early gene mRNAs that encode proven or putative transcription factors are differentially regulated by neuronal stimulation in vivo, we have examined the effect of dopaminergic agents on mRNA levels of several such genes using in situ hybridization and northern blot analysis. d-Amphetamine (2.5-10 mg/kg i.p.) causes a rapid but transient dose-dependent increase in zif268 and jun-B mRNA levels in striatum that was abolished by striatal 6-hydroxydopamine lesions or by pretreatment with the specific D1 receptor antagonist SCH-23390 but not by specific D2 receptor antagonists. Apomorphine, a dopamine agonist that acts at both D1 and D2 receptors, and SKF-38393, a specific D1 receptor agonist, produce similar mRNA changes in rats pretreated with either 6-hydroxydopamine or reserpine, whereas LY-171,555, a specific D2 receptor agonist, has no effect. Direct dopamine agonist effects on these immediate early gene mRNA levels are also blocked by D1 but not by D2 antagonists. We observed similar, although less robust, changes in c-fos and fos-B mRNA levels. These results demonstrate that striatal D1 dopamine receptors are coupled to activation of multiple transcription factor genes, including zif268 and jun-B as well as members of the fos family.

The serum response factor is extensively modified by phosphorylation following its synthesis in serum-stimulated fibroblasts

Growth factor regulation of c-fos proto-oncogene transcription is mediated by a 20-bp region of dyad symmetry, termed the serum response element. The inner core of this element binds a 67-kDa phosphoprotein, the serum response factor (SRF), that is thought to play a pivotal role in the c-fos transcriptional response. To investigate the mechanism by which SRF regulates c-fos expression, we generated polyclonal anti-SRF antibodies and used these antibodies to analyze the biochemical properties of SRF. These studies indicate that the synthesis of SRF is transient, occurring within 30 min to 4 h after serum stimulation of quiescent fibroblasts. Newly synthesized SRF is transported to the nucleus, where it is increasingly modified by phosphorylation during progression through the cell cycle. Within 2 h of serum stimulation, differentially modified forms of SRF can be distinguished on the basis of the ability to bind a synthetic serum response element. SRF protein exhibits a half-life of greater than 12 h and is predominantly nuclear, with no change occurring in its localization upon serum stimulation. We find that the induction of SRF synthesis is regulated at the transcriptional level and that cytoplasmic SRF mRNA is transiently expressed with somewhat delayed kinetics compared with c-fos mRNA expression. These features of SRF expression suggest a model whereby newly synthesized SRF functions in the shutoff of c-fos transcription.