The Rous sarcoma virus long terminal repeat promoter is regulated by TFII-I

A Novel Interaction between TFII-I and Mdm2 with a Negative Effect on TFII-I Transcriptional Activity

Williams-Beuren syndrome-associated transcription factor TFII-I plays a critical regulatory role in bone and neural tissue development and in immunity, in part by regulating cell proliferation in response to mitogens. Mdm2, a cellular oncogene responsible for the loss of p53 tumor suppressor activity in a significant proportion of human cancers, was identified in this study as a new binding partner for TFII-I and a negative regulator of TFII-I-mediated transcription. These findings suggest a new p53-independent mechanism by which increased Mdm2 levels found in human tumors could influence cancer cells. In addition to that, we present data indicating that TFII-I is an important cellular regulator of transcription from the immediate-early promoter of human cytomegalovirus, a promoter sequence frequently used in mammalian expression vectors, including vectors for gene therapy. Our observation that Mdm2 over-expression can decrease the ability of TFII-I to activate the CMV promoter might have implications for the efficiency of experimental gene therapy based on CMV promoter–derived vectors in cancers with Mdm2 gene amplification.

Evolution of general transcription factors

Three genes GTF2IRD1, GTF2I, and GTF2IRD2, which encode members of the GTF2I (or TFII-I) family of so-called general transcription factors, were discovered and studied during the last two decades. Chromosome location and similarity of exon-intron structures suggest that the family evolved by duplications. The initial duplication of ancestral proto-GTF2IRD1 gene likely occurred in early vertebrates prior to origin of cartilaginous fish and led to formation of GTF2I (>450 MYA), which was later lost in bony fish but successfully evolved in the land vertebrates. The second duplication event, which created GTF2IRD2, occurred prior to major radiation events of eutherian mammalian evolution (>100 MYA). During recent steps of primate evolution there was another duplication which led to formation of GTF2IRD2B (<4 MYA). Two latest duplications were coupled with inversions. Genes belonging to the family have several highly conservative repeats which are implicated in DNA binding. Phylogenetic analysis of the repeats revealed a pattern of intragenic duplications, deletions and substitutions which led to diversification of the genes and proteins. Distribution of statistically rare atypical substitutions (p ≤ 0.01) sheds some light on structural differentiation of repeats and hence evolution of the genes. The atypical substitutions are often located on secondary structures joining α-helices and affect 3D arrangement of the protein globule. Such substitutions are commonly traced at the early stages of evolution in Tetrapoda, Amniota, and Mammalia.

Development of gene expression system in a marine diatom using viral promoters of a wide variety of origin

Promoter sequences of the cytomegalovirus (PCMV), the rous sarcoma virus long terminal repeat (PRSV-LTR) and the cauliflower mosaic virus 35s (PCaMV35s) were ligated with the beta-glucuronidase (GUS) gene, uidA, and were introduced into cells of the marine diatom, Phaeodactylum tricornutum. Transformants were selected on a 100 mg l(-1) Zeocin plate, and Zeocin-resistant clones were further selected by the occurrence of GUS activity. Two to 10 GUS-positive clones were obtained, and GUS activities in these transformants did not change in response to changes in ambient CO(2) concentration except that the PRSV-LTR was weakly activated in air. These results indicate that a wide spectrum of viral promoters originating from mammalian, avian and plant hosts can operate as constitutive promoters in a marine diatom. The CO(2) responsive promoter sequence of the chloroplastic carbonic anhydrase gene in P. tricornutum (Pptca1) with a deleted initiator region was ligated with the minimal region of the PCMV followed by uidA and was introduced into P. tricornutum. GUS expression in the resulting transformants was clearly regulated by CO(2), that is, GUS expression was stimulated in air to about 10-fold than that in cells grown in 5% CO(2). However, the CO(2) response disappeared when the core regulatory region of Pptca1 (-76 to -11 bp) was removed. The regulative function of the endogenous diatom promoter was thus maintained after fusion with an extrinsic viral promoter. These results indicate that diatom cells accommodate a wide range of transcriptional system from beyond the plant kingdom and that an efficient transcriptional system could potentially be constructed in marine diatoms by selecting an appropriate set of viral promoter and functional cis elements.

Expression profiling of BEN regulated genes in mouse embryonic fibroblasts

BEN is a member of the TFII-I family of helix-loop-helix transcription factors. Both TFII-I and BEN are involved in gene regulation through interactions with tissue-specific transcription factors and chromatin remodeling complexes. Identification of the downstream target genes of TFII-I proteins is critical in delineating the regulatory effects of these proteins. In this study, we conducted a microarray analysis to determine gene expression alterations following the overexpression of BEN in primary mouse embryonic fibroblasts (MEFs). We found the BEN-dependent modulation in the expression of large groups of genes representing a wide variety of functional categories including genes important in the immune response, cell cycle, transcriptional regulation and cell signaling. A set of genes identified by the microarray analysis was validated by independent real-time PCR analysis. Among upregulated genes were Shrm, Tgfb2, Ube2l6, G1p2, Ccl7 while downregulated genes were Folr1, Tgfbr2, Csrp2, and Dlk1. These results support a versatile function of TFII-I proteins in vertebrate physiology and lead to an increased understanding of the BEN-dependent molecular events.

Studies on the activity of a bidirectional promoter of Mungbean yellow mosaic India virus by agroinfiltration

The AV promoter expressing AV1 and AV2 genes and AC1 promoter expressing AC1 gene are present in opposite orientation in the intergenic region of Mungbean yellow mosaic India virus (MYMIV). Transient Agrobacterium-mediated delivery of putative promoter constructs into Nicotiana benthamiana and different legumes, followed by reporter gene (beta-d-glucuronidase, GUS) assay, identified the promoter region of both AC1 and AV genes that is necessary for transcriptional initiation. Transcription activator protein-independent activity of AV promoter and differential regulation of AC1 promoter are unique to MYMIV. The AV promoter is a composite core promoter having both TATA box and Initiator elements (TATA(+)Inr(+)). Many transcription factor binding sites were identified in the upstream promoter sequences of both virion and complementary sense genes, which might be used in the transcription regulation studies of the host plant as well as the virus.

Vascular endothelial growth factor receptor-2: counter-regulation by the transcription factors, TFII-I and TFII-IRD1

The vascular endothelial growth factor receptor-2 (VEGFR-2/KDR/flk-1) functions as the primary mediator of vascular endothelial growth factor activation in endothelial cells. Regulation of VEGFR-2 expression appears critical in mitogenesis, differentiation, and angiogenesis. Transcriptional regulation of the VEGFR-2 is complex and may involve multiple putative upstream regulatory elements including E boxes. Transcript initiation is dependent on an initiator (Inr) element flanking the transcriptional start site. The transcription factor, TFII-I, enhances VEGFR-2 transcription in an Inr-dependent fashion. TFII-I is unusual both structurally and functionally. The TFII-I transcription factor family members contain multiple putative DNA binding domains. Functionally, TFII-I acts at both the basal, Inr element as well as at several distinct upstream regulatory sites. It has been postulated that the structure of TFII-I might allow simultaneous interaction with both basal and regulatory sites in a given promoter. As TFII-I is known to act at regulatory sites including E boxes as well as at the basal Inr element, we evaluated the possibility of Inr-independent TFII-I activation of the VEGFR-2 promoter. We found that an Inr-mutated VEGFR-2 reporter construct retains TFII-I-stimulated activity. We demonstrated that TFII-I binds to both the Inr and to three regulatory E boxes in the human VEGFR-2 promoter. In addition, reduction in TFII-I expression by siRNA results in decreased VEGFR-2 expression. We also describe counter-regulation of the VEGFR-2 promoter by TFII-IRD1. We found that TFII-I is capable of acting at both basal and regulatory sites in one promoter and that the human VEGFR-2 promoter is functionally counter-regulated by TFII-I and TFII-IRD1.

Biochemistry and biology of the inducible multifunctional transcription factor TFII-I

An animal cell has the capability to respond to a variety of external signals through cell surface receptors. The response is usually manifested in terms of altered gene expression in the nucleus. Thus, in modern molecular and cell biology, it has become important to understand how the communication between extracellular signals and nuclear gene transcription is achieved. Originally discovered as a basal factor required for initiator-dependent transcription in vitro, recent evidence suggests that TFII-I is also an inducible multifunctional transcription factor that is activated in response to a variety of extracellular signals and translocates to the nucleus to turn on signal-induced genes. Here I review the biochemical and biological properties of TFII-I and related proteins in nuclear gene transcription, signal transduction and genetic disorders.

Structure-function analysis of TFII-I. Roles of the N-terminal end, basic region, and I-repeats

The transcription factor TFII-I can bind specifically to several DNA sequence elements and is implicated in both basal and activated transcription. There are four alternatively spliced isoforms of TFII-I, all characterized by the presence of six I-repeats, R1-R6, each containing a potential helix-loop-helix motif implicated in protein-protein interactions. These isoforms exhibit both homomeric and heteromeric interactions that lead to nuclear localization. In this study we mapped two distinct regions in TFII-I that affect its DNA binding. Deletion of either of these regions led to abrogation of DNA binding and transcriptional activation from both the Vbeta and c-fos promoters. The I-repeats, as expected, were capable of mediating homomeric interactions either individually or in combination. Unexpectedly, an additional homomeric interaction domain was found within the N-terminal end of TFII-I that includes a putative leucine zipper motif. These data suggest a model in which TFII-I undergoes regulated homomeric interaction mediated by both the N-terminal end and the I-repeats.