JunD mutants with spontaneously acquired transforming potential have enhanced transactivating activity in combination with Fra-2

Yukmijihwang-tang inhibits receptor activator for nuclear Factor-κB ligand-induced osteoclast differentiation

Yukmijihwang-tang (YMT) is a traditional herbal medicine known to enhance memory in brain injury models. The aims of this study were to evaluate the inhibitory effect of YMT on osteoclast differentiation and to determine its molecular mechanism of action. YMT dose-dependently inhibited receptor activator for nuclear factor-κB (NF-κB) ligand (RANKL)-induced tartrate-resistant acid phosphatase (TRAP) activity and the formation of multinucleated osteoclasts in RAW264.7 cells. In addition, quantitative reverse transcription-polymerase chain reaction showed that YMT significantly decreased RANKL-induced expression of osteoclast differentiation-specific genes (TRAP, matrix metalloproteinase-9, cathepsin K, and the d2 isoform of vacuolar ATPase V(0) domain). Furthermore, YMT inhibited RANKL-induced phosphorylation of mitogen-activated protein kinases (extracellular signal-regulated kinase, c-Jun N-terminal kinase, and p38), phosphorylation of I-κBα, phosphorylation of NF-κB p65, and the expression of transcription factors Fra-2 and nuclear factor of activated T-cells, cytoplasmic 1. Furthermore, YMT inhibited the bone-resorptive activity of differentiated osteoclasts, suggesting that YMT inhibits osteoclast differentiation by suppressing RANKL-induced signaling molecules and transcription factors that affect the regulation of genes for osteoclast differentiation. As such, YMT may have therapeutic potential in bone diseases.

CD11c gene expression in hairy cell leukemia is dependent upon activation of the proto-oncogenes ras and junD

Hairy cell leukemia (HCL) is a chronic lymphoproliferative disease, the cause of which is unknown. Diagnostic of HCL is abnormal expression of the gene that encodes the beta2 integrin CD11c. In order to determine the cause of CD11c gene expression in HCL the CD11c gene promoter was characterized. Transfection of the CD11c promoter linked to a luciferase reporter gene indicated that it is sufficient to direct expression in hairy cells. Mutation analysis demonstrated that of predominant importance to the activity of the CD11c promoter is its interaction with the activator protein-1 (AP-1) family of transcription factors. Comparison of nuclear extracts prepared from hairy cells with those prepared from other cell types indicated that hairy cells exhibit abnormal constitutive expression of an AP-1 complex containing JunD. Functional inhibition of AP-1 expressed by hairy cells reduced CD11c promoter activity by 80%. Inhibition of Ras, which represents an upstream activator of AP-1, also significantly inhibited the CD11c promoter. Furthermore, in the hairy cell line EH, inhibition of Ras signaling through mitogen-activated protein kinase/extracellular signal-regulated kinase kinases 1 and 2 (MEK1/2) reduced not only CD11c promoter activity but also reduced both CD11c surface expression and proliferation. Expression in nonhairy cells of a dominant-positive Ras mutant activated the CD11c promoter to levels equivalent to those in hairy cells. Together, these data indicate that the abnormal expression of the CD11c gene characteristic of HCL is dependent upon activation of the proto-oncogenes ras and junD.

Two UVC-induced stress response pathways in HeLa cells identified by cDNA microarray

Environmental toxins induce multiple effects in vivo, involving various molecular pathways. The ultraviolet C (UVC, 254 nm) component of sunlight can cause strong cytotoxic and genotoxic effects. In this study, UVC-induced stress response factors were analyzed by cDNA microarray, using the Millennium(R) Nylon membrane chip system. HeLa cells were irradiated with 30 Joule/m(2)/sec UVC, incubated for 30 or 60 minutes and then subjected to the analysis. Multiple chips were used for each experimental condition so that the data could be analyzed statistically. Principal component analysis (PCA) was used to identify groups of genes whose expression changed in a similar manner with time post-UVC irradiation. Three major factors were identified, depending on the directionality of expression changes in each gene. The factor loadings in all three identified gene groups were high, indicating that genes within each group were highly correlated. Two factors exhibited significantly changed expression patterns after 30 minutes of incubation but in the opposite direction. This indicates that the "immediate early" UVC-induced stress response was elicited by two major pathways. Interestingly, expression of the genomic damage-inducible GADD genes, as well as p53, was initially decreased, unlike the "immediate early" genes Fos/Jun and Egr-1, which were strongly increased after 30 minutes of incubation. The results indicate that PCA used in the analysis of pre-hypothesized, functionally related genes can identify the potential subpathways in a group. This method provides a novel approach for identifying functionally-related genes in microarray studies.

Carbonic anhydrase II is an AP-1 target gene in osteoclasts

c-Fos, a member of the AP-1 family of transcription factors, is necessary for osteoclast differentiation but to date, none of the osteoclast-phenotypic markers have been identified as AP-1 target genes. Here, we demonstrate that carbonic anhydrase II (CA II), an enzyme necessary for osteoclast activity, is transcriptionally upregulated by c-Fos/AP-1. A functional AP-1 binding site is present in the CA II promoter and is necessary for this regulation. Furthermore, we show that AP-1 binding activity, mainly composed of Fra-2 and JunD, is induced by treatment of bone marrow cultures with the osteoclastogenic hormone 1,25 dihydroxyvitamin D(3). Fra-2 and JunD are found in mature osteoclasts as well. Thus, our data demonstrate that cFos/AP-1 can directly regulate the expression of this osteoclast marker and that AP-1 activity is upregulated in osteoclast progenitors in response to osteoclastogenic signals.

Jun, the oncoprotein

Cellular Jun (c-Jun) and viral Jun (v-Jun) can induce oncogenic transformation. For this activity, c-Jun requires an upstream signal, delivered by the Jun N-terminal kinase (JNK). v-Jun does not interact with JNK; it is autonomous and constitutively active. v-Jun and c-Jun address overlapping but not identical sets of genes. Whether all genes essential for transformation reside within the overlap of the v-Jun and c-Jun target spectra remains to be determined. The search for transformation-relevant targets of Jun is moving into a new stage with the application of DNA microarrays technology. Genetic screens and functional tests remain a necessity for the identification of genes that control the oncogenic phenotype.

AP-1 in mouse development and tumorigenesis

Genetically modified mice have provided important insights into the biological functions of the dimeric transcription factor complex AP-1. Extensive analyses of mice and cells with genetically modified Fos or Jun proteins provide novel insights into the physiological functions of AP-1 proteins. Using knock-out strategies it was found that some components, such as c-Fos, FosB and JunD are dispensable, whereas others, like c-Jun, JunB and Fra-1 are essential in embryonic development and/or in the adult organism. Besides the specific roles of AP-1 proteins in developmental processes, we are beginning to obtain a better molecular understanding of the cell-context dependent function of AP-1 in cell proliferation and apoptosis, in bone biology as well as in multistep tumorigenesis.

Endogenous AP-1 levels necessary for oncogenic activity are higher than those sufficient to support normal growth

We investigated the role of endogenous AP-1 in human tumor cell lines by introducing SupJunD-1, a dominant-negative mutant of AP-1, using vesicular stomatitis virus G protein (VSV-G)-pseudotyped retrovirus vectors. Single inoculation of six human tumor cell lines, originating from osteosarcomas, non-small cell lung carcinomas or cervical carcinomas, with recombinant SupJunD-1 virus at a high multiplicity of infection readily inhibited colony formation in soft agar. We detected no significant changes in expression levels of AP-1 components c-Jun or Fra-1, adhesion molecules CD44 or E-cadherin, or cell cycle regulator p53, which are encoded by genes previously reported to be under the control of AP-1 in some mouse or human cell lines. By varying the dosage of VSV-G-pseudotyped retrovirus, we were able to change the proviral copy number of supjunD-1 from 1 to approximately 10 and monitor suppression of endogenous AP-1 function as assessed by growth characteristics of the tumor cell lines, we found a SupJunD-1 dosage which significantly suppressed anchorage-independent growth without affecting the cellular growth in monolayer cultures at all. We conclude that endogenous AP-1 levels necessary for oncogenic activity are much higher than those sufficient to support normal growth.

Constitutive and Interleukin-7/Interleukin-15 Stimulated DNA Binding of Myc, Jun, and Novel Myc-Like Proteins in Cutaneous T-Cell Lymphoma Cells

Members of the Myc and Jun/Fos gene families have been found to be expressed in late stages of cutaneous T-cell lymphoma (CTCL) and may be responsible for the transition from low-grade to high-grade tumors. The composition of these complexes is an important parameter, as the different homo- and heterodimeric jun and myc complexes can have gene transcription activating or suppressing activities. We determined the composition of the jun and myc DNA-binding complexes in three CTCL cell lines and malignant cells of seven Sézary patients by electrophoretic mobility shift assays (EMSAs) and “supershift” assays in which specific antibodies against the different members of the tested gene families were included in the binding reactions. Complexes containing JunD were found in three cell lines and two patients. The three cell lines and one patient contained also c-Myc/Max heterodimers. Because c-Myc/Max heterodimers are strong gene transcription activators and are necessary for cell-cycle progression, they may play a role in the progression of CTCL. JunD may also promote cell-cycle progression and influence the expression of cell death survival genes. Interleukin-7 (IL-7) and IL-15, which have been identified as growth factors for CTCL cells, stimulated the DNA binding of JunD and two novel c-Myc recognition site (E-box) binding proteins, but not the DNA binding of c-Myc/Max heterodimers.

Constitutive and Interleukin-7/Interleukin-15 Stimulated DNA Binding of Myc, Jun, and Novel Myc-Like Proteins in Cutaneous T-Cell Lymphoma Cells

Members of the Myc and Jun/Fos gene families have been found to be expressed in late stages of cutaneous T-cell lymphoma (CTCL) and may be responsible for the transition from low-grade to high-grade tumors. The composition of these complexes is an important parameter, as the different homo- and heterodimeric jun and myc complexes can have gene transcription activating or suppressing activities. We determined the composition of the jun and myc DNA-binding complexes in three CTCL cell lines and malignant cells of seven Sézary patients by electrophoretic mobility shift assays (EMSAs) and “supershift” assays in which specific antibodies against the different members of the tested gene families were included in the binding reactions. Complexes containing JunD were found in three cell lines and two patients. The three cell lines and one patient contained also c-Myc/Max heterodimers. Because c-Myc/Max heterodimers are strong gene transcription activators and are necessary for cell-cycle progression, they may play a role in the progression of CTCL. JunD may also promote cell-cycle progression and influence the expression of cell death survival genes. Interleukin-7 (IL-7) and IL-15, which have been identified as growth factors for CTCL cells, stimulated the DNA binding of JunD and two novel c-Myc recognition site (E-box) binding proteins, but not the DNA binding of c-Myc/Max heterodimers.

Two proteins translated by alternative usage of initiation codons in mRNA encoding a JunD transcriptional regulator

The junD gene encodes one component of the transcription factor, AP-1. Since two forms of JunD protein have been reported, we analyzed here the molecular mechanisms involved in the isoform production. Immunochemical analysis indicated that the longer and shorter forms of mouse JunD (JunD-L and JunD-S, with apparent molecular weights of 44 and 39 kDa, respectively) differ in their content of an N-terminal peptide. Mutational analysis further indicated that JunD-S is the translational product initiated at the third AUG located 144 bp from the first AUG, at which JunD-L translation starts. Such production of two junD isoforms from a single mRNA using the same reading frame seems to be conserved in human, rat, and chicken. To examine the functional differences between the isoforms, each type of JunD was exclusively expressed by the use of retrovirus vectors harboring the mutated junD gene. The exogenous expression of either one of these forms did not cause cellular transformation of NIH3T3, but suppressed the anchorage-independent growth of NIH3T3 transfor-bold by the activated K-ras or v-src gene. These two isoforms were expressed in all the mouse tissues examined and in various cell lines established from human tumors, though the expression ratio between JunD-L and JunD-S varied, suggesting that some factor(s) modulate the alternative usage of the initiation codon of the junD gene.

Recombination creates novel L1 (LINE-1) elements in Rattus norvegicus

Mammalian L1 (long interspersed repeated DNA. LINE-1) retrotransposons consist of a 5' untranslated region (UTR) with regulatory properties, two protein encoding regions (ORF I, ORF II, which encodes a reverse transcriptase) and a 3' UTR. L1 elements have been evolving in mammals for > 100 million years and this process continues to generate novel L1 subfamilies in modern species. Here we characterized the youngest known subfamily in Rattus norvegicus, L1mlvi2, and unexpectedly found that this element has a dual ancestry. While its 3' UTR shares the same lineage as its nearest chronologically antecedent subfamilies, L13 and L14, its ORF I sequence does not. The L1mlvi2 ORF I was derived from an ancestral ORF I sequence that was the evolutionary precursor of the L13 and L14 ORF I. We suggest that an ancestral ORF I sequence was recruited into the modern L1mlvi2 subfamily by recombination that possibly could have resulted from template strand switching by the reverse transcriptase during L1 replication. This mechanism could also account for some of the structural features of rodent L1 5' UTR and ORF I sequences including one of the more dramatic features of L1 evolution in mammals, namely the repeated acquisition of novel 5' UTRs.

Chondrocytes as a specific target of ectopic Fos expression in early development

The Finkel-Biskis-Jinkins murine sarcoma virus, which carries v-fos, induces osteosarcomas, whereas high-level expression of exogenous c-fos in transgenic and chimeric mice leads to postnatal development of osteogenic and chondrogenic tumors, respectively. To test whether such target cell specificity of an oncogene can be detected even in early development, we induced ectopic expression of fos in chicken limb buds by microinjecting replication-competent retrovirus into the presumptive leg field of stage 10 embryos. This caused cartilage truncation of all the long bones of the injected leg, which was mainly attributable to chondrodysplasia due to severe retardation of differentiation of the proliferating chondrocytes into mature or hypertrophic chondrocytes, as well as a slight delay in precartilagenous condensation. Expression of genes for all the other known members of chicken AP-1, which include such transforming genes as c-jun and fra-2, however, caused no macroscopic abnormalities in limb formation, indicating a specific function of Fos proteins in embryonic endochondral bone differentiation. The extent of truncation was stronger with v-Fos than with c-Fos, and comparative analysis of these proteins, as well as v-Fos mutants, revealed that strong transforming activity of Fos protein is necessary to cause dysplasia, suggesting that common molecular mechanisms are involved in both embryonic chondrodysplasia and bone tumor formation in postnatal mice.

Stepwise transformation of rat embryo fibroblasts: c-Jun, JunB, or JunD can cooperate with Ras for focus formation, but a c-Jun-containing heterodimer is required for immortalization

Among the Jun family of transcription factors, only c-Jun displays full transforming potential in cooperation with activated c-Ha-Ras in primary rat embryo fibroblasts. c-Jun in combination with Ras can both induce foci of transformed cells from rat embryo fibroblast monolayers and promote the establishment of these foci as tumoral cell lines. JunB can also cooperate with Ras to induce foci but is unable to promote immortalization. We report here that JunD, in cooperation with Ras, induces foci with an efficiency similar to that of JunB. Artificial Jun/eb1 derivatives from each of the three Jun proteins were also analyzed. These constructs carry a heterologous homodimerization domain from the viral EB1 transcription factor and are thought to form only homodimers in the cell. We show here that these Jun/eb1 chimeras are potent transactivators of AP1 sites and that they can cooperate with c-Ha-Ras to induce foci. However, among all the Ras-Jun and Ras-Jun/eb1 combinations tested, only foci from Ras-c-Jun can be efficiently expanded and maintained as long-term growing cultures. Therefore, we suggest that a heterodimer containing c-Jun might be required for in vitro establishment of these primary mammalian cells.

Transcription factor AP-1, and the role of Fra-2

Transcription factors function to regulate gene transcription. They may be constitutively expressed or may only be activated during specific situations. Activator protein-1 (AP-1) is an inducible transcription factor, and is comprised of multiple protein complexes that include the gene products of the fos and jun gene families. Numerous cellular and viral genes contain AP-1 binding sites within their promoters and, accordingly, AP-1 has been shown to play a role in the regulation of both basal and inducible transcription of these genes. fos-related antigen-2 (fra-2) has been found to have both similar and unique properties to that of other fos gene members in terms of its regulation and expression. The analysis and determination of the function of Fra-2 will provide further information on the role of AP-1.

Circadian expression of transcription factor Fra-2 in the rat pineal gland

Physiological changes in Fos-like immunoreactivity in the rat pineal gland are shown here to be due primarily to changes in a 42/46-kDa Fos-related antigen (Fra). Studies are presented that indicate this 42/46-kDa Fra is Fra-2, a poorly understood member of the Fos family of transcription factors. Both Fra-2 mRNA and protein are absent during the day and increase robustly at night on a circadian basis; organ culture studies indicate that regulation is mediated by an adrenergic-->cyclic AMP mechanism. AP-1 binding activity changes in parallel to changes in the level of Fra-2 protein.

Analysis of AP-1 function in cellular transformation pathways

To understand the role of endogenous AP-1 activity in cellular transformation induced by oncogenes, we have made use of a fos mutant (supfos-1) and a jun mutant (supjun-1), either of which can function as a transdominant inhibitor of AP-1-mediated transcriptional regulation. Chicken embryo fibroblasts (CEF) infected with a series of transforming retroviruses were doubly infected with retrovirus carrying supfos-1 or supjun-1, and suppression of cellular transformation was monitored in terms of reversion to normal cellular morphology or acquisition of anchorage-dependent growth. Cellular transformation induced by several exogenously expressed transforming genes of the fos or jun family was efficiently suppressed, as expected. CEF transformed by v-src, v-yes, v-fps, c-Ha-ras, and N-terminally truncated c-raf were also induced to revert to the normal phenotype by these transdominant mutants, suggesting that functional transcription factor AP-1 activity is essential for the cellular transformation induced by these oncogenes. The suppression is not attributable to nonspecific inhibition of cellular proliferation, because CEF transformed by v-ros or v-myc were not induced to revert to the normal phenotype. We next analyzed changes in all known components of chicken AP-1 induced by v-src, c-Ha-ras, or activated c-raf transformation. The levels of both Fra-2 and c-Jun expression were elevated two- to fourfold, and hyperphosphorylation of Fra-2 was also observed. We further showed that Fra-2-c-Jun heterodimer is mainly responsible for the elevated AP-1 DNA-binding activity in these transformed cells, and we propose that this heterodimer play a crucial role in the transformation induced by these oncogenes.