The DNA-binding homeo domain of the Oct-2 protein

Biochemical characterization and functional analysis of the POU transcription factor POU-M2 of Bombyx mori

POU-M2 is a homeodomain transcription factor which plays important roles in the development and silk synthesis of Bombyx mori. In this study, we expressed, purified and characterized POU-M2 and studied its transcription regulation on fibroin heavy chain gene of Bombyx mori. Gel filtration showed POU-M2 existed as a dimer in solution. Far-UV circular dichroism spectra indicated POU-M2 had a well-defined α-helix structure and the α-helix content was about 26.4%. The thermal unfolding transition of POU-M2 was a cooperative process. Tm, ΔH and ΔS were 45.15 ± 0.2 °C, 138.4 ± 0.5 KJ/mol and 0.4349 ± 0.04 KJ/(mol·K), respectively. Western blotting analysis indicated the expression level of POU-M2 increased slightly from day 3 to day 7 of the fifth instar larvae in the posterior silk gland. POU-M2 was positioned in the nucleus of cells. The luciferase reporter assay demonstrated POU-M2 could stimulate the promoter activity of fibroin heavy chain gene, and the activation effect was dependent on the amount of POU-M2. Our study suggested POU-M2 may be involved in the transcriptional regulation of fibroin heavy chain gene. These findings expand toward a better understanding of the structure of POU-M2 and its function in silk synthesis of Bombyx mori.

Control of DNA replication: a new facet of Hox proteins?

Hox proteins are well-known as developmental transcription factors controlling cell and tissue identity, but recent findings suggest that they are also part of the cell replication machinery. Hox-mediated control of transcription and replication may ensure coordinated control of cell growth and differentiation, two processes that need to be tightly and precisely coordinated to allow proper organ formation and patterning. In this review we summarize the available data linking Hox proteins to the replication machinery and discuss the developmental and pathological implications of this new facet of Hox protein function.

POU-specific domain of Oct-2 factor confers ‘octamer’ motif DNA binding specificity on heterologous Antennapedia homeodomain

The bipartite DNA binding domain of the POU family of transcription factors contains a 'POU-specific' domain unique to this class of factors and a 'POU homeodomain' homologous to other homeodomains. We compared DNA binding of the Oct-2 factor POU domain and the Antennapedia (Antp) homeodomain with a chimeric Oct-2/Antp protein in which the distantly related Antp homeodomain was substituted for the Oct-2 POU homeodomain. The Oct-2/Antp chimeric protein bound both the octamer and the Antp sites efficiently, indicating that DNA binding specificity is contributed by both components of the POU domain.

Regulation of PAX-6 gene transcription: alternate promoter usage in human brain

We have isolated and characterized the 5'-flanking regulatory region of the human PAX-6 gene. Mapping of transcription initiation sites revealed the existence of an additional non-coding 5' exon, exon 1A. Functional analyses indicated that PAX-6 transcription is regulated by two distinct promoters, A and B, resulting in alternative transcription of exon 1A or 1B and joint transcription of exons 2 to 13. While a single initiation site was identified for exon 1A, transcription of exon 1B appears to be initiated from more than one site downstream of the promoter B-associated TATA motif. Multiple potential binding sites for transcription factors were found in the regions of promoter A and B. Although a 1.1-kb fragment of promoter A and a 1.5 kb fragment of promoter B, which had been fused to a reporter gene and transiently expressed in cell lines, displayed constitutive promoter activity, transcription of PAX-6 driven by promoter B was considerably higher than by promoter A in various regions of human postmortem brain. Transcript PAX-6B was primarily expressed in cerebellar cortex, whereas relatively low concentrations were detected in other brain areas. Functional dissection by serial deletions revealed several clusters of both activating elements and cell-selective silencers within the regulatory regions upstream of exon 1A and 1B. Coexpression of the promoter B constructs with a vector expressing PAX-6 modulated promoter B activity, thus indicating autoregulation by PAX-6 transcription. In conclusion, our findings suggest that PAX-6 transcription is regulated by alternate usage of promoter A and B, and that in adult human brain expression of PAX-6 is primarily controlled by promoter B. Alternate promoter usage and differential PAX-6 transcription are likely to play a critical role in brain development and neuroplasticity.

The gut-enriched Krüppel-like factor suppresses the activity of the CYP1A1 promoter in an Sp1-dependent fashion

The gut-enriched Krüppel-like factor (GKLF) is a newly identified zinc finger-containing transcription factor. Recent studies indicate that GKLF binds to a core DNA sequence of 5'-(G/A)(G/A)GG(C/T)G(C/T)-3', which is found in an endogenous cis element, the basic transcription element (BTE) of the cytochrome P-450IA1 (CYP1A1) promoter. The present study characterizes the ability of GKLF to regulate CYP1A1 expression. By electrophoretic mobility gel shift assay (EMSA) and methylation interference assay, GKLF was found to bind BTE in a manner similar to several other transcription factors known to interact with BTE including Sp1 and BTEB. Cotransfection studies in Chinese hamster ovary cells showed that GKLF inhibited the CYP1A1 promoter in a dose- and BTE-dependent manner. The same experiments also revealed that BTE was responsible for a significant portion of the CYP1A1 promoter activity. EMSA of nuclear extracts from Chinese hamster ovary cells showed that Sp1 and Sp3 were two major proteins that interacted with BTE. Additional cotransfection studies showed that GKLF inhibited Sp1-mediated activation of the CYP1A1 promoter. In contrast, GKLF enhanced Sp3-dependent suppression of the same promoter. Moreover, the ability of GKLF to inhibit Sp1-dependent transactivation was in part due to physical interaction of the two proteins. These findings indicate that GKLF is a negative regulator of the CYP1A1 promoter in a BTE-dependent fashion and that this inhibitory effect is in part mediated by physical interaction with Sp1.

Analysis of cis-regulatory elements involved in the activation of a member of chalcone synthase gene family (PsChs1) in pea

Cis-regulatory elements involved in the activation of the plant defense-related gene encoding chalcone synthase 1 (PsChs1) in pea (Pisum sativum L.) were examined by transient transfection, gel mobility shift assay and in vitro DNase I-footprinting analysis. Transient transfection assay revealed that a 61 bp DNA fragment spanning from -242 to -182 of PsChs1 was required for the maximal promoter activity and possibly involved in the enhancement of elicitor-mediated activation. Nuclear isolate from elicitor-treated pea epicotyl tissues contained some factor(s) that specifically bound to this DNA fragment to form a complex with low mobility (LMC, low mobility complex) in gel mobility shift assay. DNase I-footprinting analysis of LMC revealed that among three protected regions detected in a 61 bp DNA fragment, two regions contained identical AT-rich sequence, TAAAATACT. Site directed mutation in either or both identical sequences, TAAAATACT to TGGAATACT, resulted in the reduction or loss in the ability to form LMC. Detailed analysis of 61 bp DNA fragment demonstrated that the region from -242 to -226 containing promoter-distal TAAAATACT motif was imperative for the maximal elicitor-mediated activation of PsChs1.

Solution structure of the octamer motif in immunoglobulin genes via restrained molecular dynamics calculations

The solution structure of the DNA decamer d(CATTTGCATC)-d(GATGCAAATG), comprising the octamer motif of immunoglobulin genes, is determined by restrained molecular dynamics (rMD) simulations. The restraint data set includes interproton distances and torsion angles for the deoxyribose sugar ring which were previously obtained by a complete relaxation matrix analysis of the two-dimensional nuclear Overhauser enhancement (2D NOE) intensities and by the quantitative simulation of cross-peaks in double-quantum-filtered correlated (2QF-COSY) spectra. The influence of torsion angles and the number of experimental distance restraints on the structural refinement has been systematically examined. Omitting part of the experimental NOE-derived distances results in reduced restraint violations and lower R factors but impairs structural convergence in the rMD refinement. Eight separate restrained molecular dynamics simulations were carried out for 20 ps each, starting from either energy-minimized A- or B-DNA. Mutual atomic root-mean-square (rms) differences among the refined structures are well below 1 A and comparable to the rms fluctuations of the atoms about their average position, indicating convergence to essentially identical structures. The average refined structure was subjected to an additional 100 ps of rMD simulations and analyzed in terms of average torsion angles and helical parameters. The B-type duplex exhibits clear sequence-dependent variations in its geometry with a narrow minor groove at the T3.A3 tract and a large positive roll at the subsequent TG.CA step. This is accompanied by a noticeable bend of the global helix axis into the major groove. There is also evidence of significant flexibility of the sugar-phosphate backbone with rapid interconversion among different conformers.

NonO, a non-POU-domain-containing, octamer-binding protein, is the mammalian homolog of Drosophila nonAdiss

We have cloned the ubiquitous form of an octamer-binding, 60-kDa protein (NonO) that appears to be the mammalian equivalent of the Drosophila visual and courtship song behavior protein, no-on-transient A/dissonance (nonAdiss). A region unprecedently rich in aromatic amino acids containing two ribonuclear protein binding motifs is highly conserved between the two proteins. A ubiquitous form of NonO is present in all adult tissues, whereas lymphocytes and retina express unique forms of NonO mRNA. The ubiquitous form contains a potential helix-turn-helix motif followed by a highly charged region but differs from prototypic octamer-binding factors by lacking the POU DNA-binding domain. In addition to its conventional octamer duplex-binding, NonO binds single-stranded DNA and RNA at a site independent of the duplex site.

NonO, a non-POU-domain-containing, octamer-binding protein, is the mammalian homolog of Drosophila nonAdiss

We have cloned the ubiquitous form of an octamer-binding, 60-kDa protein (NonO) that appears to be the mammalian equivalent of the Drosophila visual and courtship song behavior protein, no-on-transient A/dissonance (nonAdiss). A region unprecedently rich in aromatic amino acids containing two ribonuclear protein binding motifs is highly conserved between the two proteins. A ubiquitous form of NonO is present in all adult tissues, whereas lymphocytes and retina express unique forms of NonO mRNA. The ubiquitous form contains a potential helix-turn-helix motif followed by a highly charged region but differs from prototypic octamer-binding factors by lacking the POU DNA-binding domain. In addition to its conventional octamer duplex-binding, NonO binds single-stranded DNA and RNA at a site independent of the duplex site.

Repression of the myelin P0 gene by the POU transcription factor SCIP

SCIP is a POU domain transcription factor expressed by Schwann cells, the myelin-forming glial cells of the peripheral nervous system. In this study, we investigate SCIP regulation of the gene encoding P0, the major structural protein of peripheral myelin. We find that SCIP represses transcription of this gene through the joint action of the SCIP POU domain and an amino terminal domain that acts cell specifically. Maximal repression is DNA-binding-dependent, and analysis of the P0 promoter reveals the presence of multiple SCIP binding sites. Surprisingly, none of these sites in their native positions dramatically affect P0 promoter activity or its repression by SCIP, although they mediate repression when moved closer to the P0 transcription start site. We propose that repression occurs through a quenching mechanism mediated by the SCIP POU and amino terminal domains acting in concert with other nuclear proteins, including a Schwann cell-specific adapter.

Cloning, chromosomal localization and expression pattern of the POU domain gene Oct-11

POU domain genes encode a family of highly conserved transacting factors that influence the transcriptional activity of several cell type-specific and ubiquitous genes. We have cloned and sequenced cDNAs encoding a novel mouse POU domain protein, Oct-11, that is closely related within the POU domain to the POU class II proteins, Oct-1 and Oct-2. Recombinant Oct-11 protein binds specifically to an octamer sequence in vitro. The Oct-11 gene is expressed during mouse embryogenesis and in the adult thymus and testis. In addition, it is abundant in the myeloma cell line P3/NS-1/1-Ag4.1. We describe the structure of Oct-11 and its chromosomal localization, and discuss the evidence that the POU class II gene family has evolved by duplication and divergence of a common ancestral gene.

An NGF-inducible octamer binding protein activity in a C1300 neuroblastoma cell line

Nerve growth factor (NGF) induces a protein in the C1300 mouse neuroblastoma cell line which recognises the octamer DNA consensus sequence 'ATGCAAAT'. This protein is absent, or only minimally present, in C1300 cells prior to induction with NGF. This induced octamer binding protein is detectable by gel retardation analysis within 3 h of NGF treatment and increases progressively with 24 h and 72 h of exposure to NGF.

AT-rich promoter elements of soybean heat shock gene Gmhsp17.5E bind two distinct sets of nuclear proteins in vitro

A 33 bp double-stranded oligonucleotide homologous to two AT-rich sequences located upstream (-907 to -889 and -843 to -826) to the start of transcription of heat shock gene Gmhsp17.5E of soybean stimulated transcription when placed 5' to a truncated (-140) maize Adh1 promoter. The chimeric promoter was assayed in vivo utilizing anaerobically stressed sunflower tumors transformed by a pTi-based vector of Agrobacterium tumefaciens. Nuclear proteins extracted from soybean plumules were shown to bind double-stranded oligonucleotides homologous to AT-rich sequences in the 5' flanking regions of soybean beta-conglycinin, lectin, leghemoglobin and heat shock genes. These proteins were also shown to bind AT-rich probes homologous to homeobox protein binding sites from the Antennapedia and engrailed/fushi tarazu genes of Drosophila. Binding activity specific for AT-rich sequences showed a wide distribution among various plant organs and species. Preliminary characterization indicated that two sets of nuclear proteins from soybean bind AT-rich DNA sequences: a diverse high-molecular-weight (ca. 46-69 kDa) group, and a low-molecular-weight (23 and 32 kDa) group of proteins. The latter meets the operational criteria for high-mobility group proteins (HMGs).

An ATF/CREB binding site is required for virus induction of the human interferon beta gene [corrected]

We report the characterization of a distinct regulatory element of the human interferon beta (HuIFN-beta) gene promoter, which we designate PRDIV (positive regulatory domain IV). In previous studies, sequences between -104 and -91 base pairs upstream from the start site of transcription were shown to be required for maximal levels of virus induction in mouse L929 cells. We have localized the essential sequence in this region extending from -99 to at least -91, and we show that this sequence is a binding site for a protein of the activating transcription factor/cAMP response element binding protein (ATF/CREB) family of transcription factors. Mutations in PRDIV that decrease the affinity of one member of this family (ATF-2/CRE-BP1) decrease the level of virus induction in vivo. Moreover, multiple copies of PRDIV can confer both virus and cAMP inducibility upon a minimal promoter in L929 cells, while it is constitutively active in HeLa cells. We conclude that PRDIV is a distinct regulatory element of the HuIFN-beta promoter and that the signal transduction pathways involved in virus and cAMP induction may partially overlap.

Segments of the POU domain influence one another's DNA-binding specificity

The ubiquitously expressed mammalian POU-domain protein Oct-1 specifically recognizes two classes of cis-acting regulatory elements that bear little sequence similarity, the octamer motif ATGCAAAT and the TAATGARAT motif. The related pituitary-specific POU protein Pit-1 also recognizes these two motifs but, unlike Oct-1, binds preferentially to the TAATGARAT motif. Yet in our assay, Pit-1 still binds octamer elements better than does the octamer motif-binding protein Oct-3. The POU domain is responsible for recognizing these diverse regulatory sequences through multiple DNA contacts that include the two POU subdomains, the POU-specific region, and the POU homeodomain. The DNA-binding properties of 10 chimeric POU domains, in which different POU-domain segments are derived from either Oct-1 or Pit-1, reveal a high degree of structural plasticity; these hybrid proteins all bind DNA well and frequently bind particular sites better than does either of the parental POU domains. In these chimeric POU domains, the POU-specific A and B boxes and the hypervariable POU linker can influence DNA-binding specificity. The surprising result is that the influence a particular segment has on DNA-binding specificity can be greatly affected by the origin of other segments of the POU domain and the sequence of the binding site. Thus, the broad but selective DNA-binding specificity of Oct-1 is conferred both by multiple DNA contacts and by dynamic interactions within the DNA-bound POU domain.

Segments of the POU domain influence one another's DNA-binding specificity

The ubiquitously expressed mammalian POU-domain protein Oct-1 specifically recognizes two classes of cis-acting regulatory elements that bear little sequence similarity, the octamer motif ATGCAAAT and the TAATGARAT motif. The related pituitary-specific POU protein Pit-1 also recognizes these two motifs but, unlike Oct-1, binds preferentially to the TAATGARAT motif. Yet in our assay, Pit-1 still binds octamer elements better than does the octamer motif-binding protein Oct-3. The POU domain is responsible for recognizing these diverse regulatory sequences through multiple DNA contacts that include the two POU subdomains, the POU-specific region, and the POU homeodomain. The DNA-binding properties of 10 chimeric POU domains, in which different POU-domain segments are derived from either Oct-1 or Pit-1, reveal a high degree of structural plasticity; these hybrid proteins all bind DNA well and frequently bind particular sites better than does either of the parental POU domains. In these chimeric POU domains, the POU-specific A and B boxes and the hypervariable POU linker can influence DNA-binding specificity. The surprising result is that the influence a particular segment has on DNA-binding specificity can be greatly affected by the origin of other segments of the POU domain and the sequence of the binding site. Thus, the broad but selective DNA-binding specificity of Oct-1 is conferred both by multiple DNA contacts and by dynamic interactions within the DNA-bound POU domain.

A pre-B- and B cell-specific DNA-binding protein, EBB-1, which binds to the promoter of the VpreB1 gene

The VpreB1 protein is thought to be expressed on the surface of pre-B cells in association with lambda 5 and mu heavy chain, and to play an important role on B cell differentiation. The expression of VpreB1 and lambda 5 is pre-B cell specific, and regulated at the initiation of transcription. We have identified at least two sequence-specific DNA-binding proteins which bind to the region -191 to -74 of the promoter of the mouse VpreB1 gene. These DNA-binding proteins also bind to the promoter of the mouse lambda 5 gene. One of the two DNA-binding proteins, called EBB-1, is restricted to pre-B and B cells, but not detected in plasma cells, T cells and cells of other lineages. Transient transfection analysis of reporter constructs revealed that the binding sites of these proteins play a significant role in the activity of the promoter, especially the binding site of EBB-1. Taken together these results suggest that EBB-1 might be one of the crucial factors which regulates a series of intracellular events in B cell differentiation.

Characterization of two Drosophila POU domain genes, related to oct-1 and oct-2, and the regulation of their expression patterns

We have characterized two genes from Drosophila melanogaster that encode proteins with POU domains showing a high degree of identity with the human Oct-1 and Oct-2 transcription factors. These POU domain genes, pdm-1 and pdm-2, are expressed at high levels during early embryogenesis and at lower levels throughout the rest of development. Both genes are expressed as two stripes in the presumptive abdominal region during the blastoderm stage, followed by thirteen stripes in the germ band extended stage. This pattern of expression is altered in mutants for a gap gene (hunchback) and a pair-rule gene (fushi tarazu). In later stage embryos, both pdm-1 and pdm-2 are expressed in selected neuroblasts in the ventral nervous system, with higher levels in the three thoracic segments and lower levels in the abdominal segments. The low level of expression in the abdominal segments is maintained by the genes within the bithorax complex (BX-C). We have also identified the cells in the dorsal and lateral clusters of the peripheral nervous system that express pdm-1 and pdm-2, and show that some of these cells derive from lineages that require BX-C functions. Together, these results suggest that previously characterized members of the embryonic regulatory hierarchy specify the patterns of the POU domain gene expression, which, in turn, function during neurogenesis and perhaps in earlier stages.

Restriction of neuroblastoma to the prostate gland in transgenic mice

Male transgenic mice that carry a construct containing 5'-flanking sequences of the gp91-phox gene linked to the early region of the simian virus 40 (SV40) genome reproducibly develop tumors arising from the prostate gland. As gp91-phox is expressed exclusively in terminally differentiating hematopoietic cells of the myelomonocytic lineage, the induction of tumors arising from the prostate gland was unexpected. These lesions appear to be due to a novel transcription signal that was generated during the construction of the transgene. Surprisingly, the histopathological and biochemical properties of the tumor are diagnostic of neuroblastoma rather than of adenocarcinoma of the prostate gland. Tumors produce SV40 T antigen and isoforms of neural cell adhesion molecule characteristic of neuronal cells, and they occur in a testosterone-independent manner. Microscopic examination of prostate glands from young transgenic mice reveals the presence of small lesions arising outside of the prostate gland epithelium, which is consistent with the diagnosis of neuroblastoma and further distinguishes this tumor from prostatic adenocarcinoma. Prostate gland tumors occur in all male animals of susceptible lines carrying the gp91-phox promoter/SV40 early-region transgene. However, variability in the time at which gross tumors appear and the presence of cells expressing T antigen prior to tumorigenesis suggest that somatic events in addition to T-antigen production are required for the development of a malignancy. The extraordinary restriction of the site of tumorigenesis in these animals indicates the presence in the prostate gland of a novel, tissue-specific neuroectodermal cell of origin. These transgenic animals provide a model system for the study of neuroectodermal malignancies.

Restriction of neuroblastoma to the prostate gland in transgenic mice

Male transgenic mice that carry a construct containing 5'-flanking sequences of the gp91-phox gene linked to the early region of the simian virus 40 (SV40) genome reproducibly develop tumors arising from the prostate gland. As gp91-phox is expressed exclusively in terminally differentiating hematopoietic cells of the myelomonocytic lineage, the induction of tumors arising from the prostate gland was unexpected. These lesions appear to be due to a novel transcription signal that was generated during the construction of the transgene. Surprisingly, the histopathological and biochemical properties of the tumor are diagnostic of neuroblastoma rather than of adenocarcinoma of the prostate gland. Tumors produce SV40 T antigen and isoforms of neural cell adhesion molecule characteristic of neuronal cells, and they occur in a testosterone-independent manner. Microscopic examination of prostate glands from young transgenic mice reveals the presence of small lesions arising outside of the prostate gland epithelium, which is consistent with the diagnosis of neuroblastoma and further distinguishes this tumor from prostatic adenocarcinoma. Prostate gland tumors occur in all male animals of susceptible lines carrying the gp91-phox promoter/SV40 early-region transgene. However, variability in the time at which gross tumors appear and the presence of cells expressing T antigen prior to tumorigenesis suggest that somatic events in addition to T-antigen production are required for the development of a malignancy. The extraordinary restriction of the site of tumorigenesis in these animals indicates the presence in the prostate gland of a novel, tissue-specific neuroectodermal cell of origin. These transgenic animals provide a model system for the study of neuroectodermal malignancies.

Planarian homeobox genes: cloning, sequence analysis, and expression

Freshwater planarians (Platyhelminthes, Turbellaria, and Tricladida) are acoelomate, triploblastic, unsegmented, and bilaterally symmetrical organisms that are mainly known for their ample power to regenerate a complete organism from a small piece of their body. To identify potential pattern-control genes in planarian regeneration, we have isolated two homeobox-containing genes, Dth-1 and Dth-2 [Dugesia (Girardia) tigrina homeobox], by using degenerate oligonucleotides corresponding to the most conserved amino acid sequence from helix-3 of the homeodomain. Dth-1 and Dth-2 homeodomains are closely related (68% at the nucleotide level and 78% at the protein level) and show the conserved residues characteristic of the homeodomains identified to data. Similarity with most homeobox sequences is low (30-50%), except with Drosophila NK homeodomains (80-82% with NK-2) and the rodent TTF-1 homeodomain (77-87%). Some unusual amino acid residues specific to NK-2, TTF-1, Dth-1, and Dth-2 can be observed in the recognition helix (helix-3) and may define a family of homeodomains. The deduced amino acid sequences from the cDNAs contain, in addition to the homeodomain, other domains also present in various homeobox-containing genes. The expression of both genes, detected by Northern blot analysis, appear slightly higher in cephalic regions than in the rest of the intact organism, while a slight increase is detected in the central period (5 days) or regeneration.

Several regions of Antennapedia and thyroid transcription factor 1 homeodomains contribute to DNA binding specificity

The DNA binding specificities of the homeodomains contained in thyroid transcription factor 1 and Antennapedia have been compared. The two homeodomains recognize different DNA sequences, despite the similar amino acid sequences of their recognition helix. Mutations that make the recognition helix of thyroid transcription factor 1 identical to the one contained in Antennapedia have no effects on the binding specificity of thyroid transcription factor 1. The exchange of other segments between these two homeodomains allows the identification of the regions responsible for the observed DNA binding specificities. These results indicate that amino acid residues outside of the recognition helix play an important role in the determination of the DNA binding specificities of these two homeodomains.

Xenopus laevis Oct-1 does not bind to certain histone H2B gene promoter octamer motifs for which a novel octamer-binding factor has high affinity

Oct-1 and a second, previously unidentified octamer-binding protein (Oct-R) have been identified in extracts of Xenopus laevis oocytes and embryos. Oct-1 does not bind to the octamer motif associated with certain Xenopus laevis histone H2B gene promoters, whereas Oct-R binds well to this motif, but only in the sequence context of the H2B gene promoter.

Multiple protein factors bind to a rice glutelin promoter region

Our goal is to identify cis-acting elements in the regulatory region of the major seed storage protein gene in rice. A glutelin gene (pGL5-1) has been cloned by screening a rice genomic DNA library with synthetic oligonucleotides and with an amplified DNA fragment. A transient expression assay using immature rice seeds shows that its 5' flanking sequence can direct the synthesis of beta-glucuronidase (GUS) when fused upstream of the GUS coding region. Gel-retardation assays were performed to study protein-DNA interactions between putative regulatory sequences of pGL5-1 and nuclear proteins from immature rice seeds. We demonstrate that at least six protein-DNA complexes are formed between the 5' flanking sequence of pGL5-1 (-677 to -45) and nuclear protein factors. By subsequent DNase I-footprinting analyses we defined several protein-binding regions. Two of the protein-binding sequences contain the TGAGTCA motif, which is also present in the -300 element found in the 5' flanking sequences of several storage protein genes of other crop plants, and to which the transcription factors jun and GCN4 bind.

The oct-1 homeo domain contacts only part of the octamer sequence and full oct-1 DNA-binding activity requires the POU-specific domain

The ubiquitous octamer-binding protein oct-1 contains a POU domain required for DNA binding, which can be subdivided into a POU-specific domain and a POU homeo domain. We have overproduced the POU domain and the POU homeo domain in a vaccinia expression system, purified both polypeptides to near homogeneity, and compared their DNA-binding properties. In contrast to the POU domain, the homeo domain protects only part of the octamer sequence in the Ad2 origin against breakdown by DNase I or hydroxyl radicals. Analysis of purine contacts by DMS and DEPC interference assays shows that the Ad2 octamer can be divided into two regions: one that is recognized both by the POU domain and the homeo domain in an identical fashion, and one that is only recognized by the POU domain. This suggests that the POU-specific domain is responsible for the additional contacts located at one side of the octamer. In agreement with this, mutating the first 3 nucleotides (ATG) of the octamer affected binding by the POU domain but not by the homeo domain. The apparent binding affinities to different octamer sites were compared. The homeo domain binds 600-fold less efficiently to the canonical octamer sequence (ATGCAAAT) than the POU domain. The difference is only sevenfold for the Ad2 octamer, whereas both Kd values are almost identical for the HSV ICP4 TAATGARAT motif. Both the POU and homeo domains recognize target sequences for mammalian homeo box proteins. We conclude that the octamer can act as a bipartite recognition sequence for oct-1 and that the POU-specific domain contributes to the binding affinity, as well as to the specificity, by providing additional contacts.

Oct-6: a POU transcription factor expressed in embryonal stem cells and in the developing brain

A family of octamer binding proteins is expressed during mouse development. Oct-4 and Oct-6 have been identified as two octamer binding proteins present in embryonal stem cells. Here we report the complementary DNA cloning and characterization of the mouse Oct-6 gene. The protein of 448 amino acids contains a glycine/alanine-rich amino terminal region, a histidine-rich sequence with homology to a region of kininogen associated with clotting, a POU domain and a short proline/histidine-rich carboxy terminal region. Expression of Oct-6 in HeLa cells is sufficient for transcriptional activation from the octamer motif, identifying Oct-6 as a transcription factor. The Oct-6 expression is downregulated upon embryonic stem cell differentiation increasing again during brain development. Expression in brain is present in certain areas of telencephalon, mesencephalon and brain stem with abundant expression in the cortex anlagen and in the developing colliculi. Thus Oct-6 is a new octamer binding transcription factor specifically regulated during mouse development.

Astrocytes and glioblastoma cells express novel octamer-DNA binding proteins distinct from the ubiquitous Oct-1 and B cell type Oct-2 proteins

The 'octamer' sequence, ATGCAAAT or its complement ATTTGCAT, is a key element for the transcriptional regulation of immunoglobulin genes in B-lymphocytes as well as a number of housekeeping genes in all cell types. In lymphocytes, the octamer-binding protein Oct-2A and variants thereof are thought to contribute to the B-cell specific gene expression, while the ubiquitous protein Oct-1 seems to control general octamer site-dependent transcription. Various other genes, for example interleukin-1 and MHC class II genes, contain an octamer sequence in the promoter and are expressed in cells of both the immune and nervous systems. This prompted us to analyze the octamer-binding proteins in the latter cells. Using the electrophoretic mobility shift assay, at least six novel octamer binding proteins were detected in nuclear extracts of cultured mouse astrocytes. These proteins are differentially expressed in human glioblastoma and neuroblastoma cell lines. The nervous system-derived (N-Oct) proteins bound to the octamer DNA sequence in a manner which is indistinguishable from the Oct-1 and Oct-2A proteins. The relationship of the N-Oct proteins to Oct-1 and Oct-2A was analyzed by proteolytic clipping bandshift assays and by their reactivity towards antisera raised against recombinant Oct-1 and Oct-2A proteins. On the basis of these assays, all N-Oct-factors were found to be distinct from the ubiquitous Oct-1 and the lymphoid-specific Oct-2A proteins. In melanoma cells that contain the N-Oct-3 factor, a transfected lymphocyte-specific promoter was neither activated nor was it repressed upon contransfection with an Oct-2A expression vector. We therefore speculate that N-Oct-3 and other N-Oct factors have a specific role in gene expression in cells of the nervous system.

Molecular organization of the human Raf-1 promoter region

A genomic DNA fragment containing the Raf-1 promoter region was isolated by using a cDNA extension clone. Nucleotide sequencing of genomic DNA clones, primer extension, and S1 nuclease assays have been used to identify the 5' ends of Raf-1 RNAs. Consistent with its ubiquitous expression, the Raf-1 promoter region had features of a housekeeping gene in that it was GC-rich (HTF-like), lacked TATA and CAAT boxes, and contained heterogeneous RNA start sites and four potential binding sites for the transcription factor SP1. In addition, an octamer motif (ATTTCAT), a potential binding site for the octamer family of transcription factors, was located at -734 base pairs. The Raf-1 promoter region drove reporter gene expression 30-fold over the promoterless reporter in Cos 7 cells.

Molecular organization of the human Raf-1 promoter region

A genomic DNA fragment containing the Raf-1 promoter region was isolated by using a cDNA extension clone. Nucleotide sequencing of genomic DNA clones, primer extension, and S1 nuclease assays have been used to identify the 5' ends of Raf-1 RNAs. Consistent with its ubiquitous expression, the Raf-1 promoter region had features of a housekeeping gene in that it was GC-rich (HTF-like), lacked TATA and CAAT boxes, and contained heterogeneous RNA start sites and four potential binding sites for the transcription factor SP1. In addition, an octamer motif (ATTTCAT), a potential binding site for the octamer family of transcription factors, was located at -734 base pairs. The Raf-1 promoter region drove reporter gene expression 30-fold over the promoterless reporter in Cos 7 cells.

The POU-specific domain of Pit-1 is essential for sequence-specific, high affinity DNA binding and DNA-dependent Pit-1-Pit-1 interactions

Pit-1 is a member of a family of transcription factors sharing two regions of homology: a highly conserved POU-specific (POUS) domain and a more divergent homeodomain (POUHD). Analysis of mutant Pit-1 proteins suggests that, while the POUHD is required and sufficient for low affinity DNA binding, the POUS domain is necessary for high affinity binding and accurate recognition of natural Pit-1 response elements. Pit-1 is monomeric in solution but associates as a dimer on its DNA response element, exhibiting DNA-dependent protein-protein interactions requiring the POUS domain. Analysis of alpha-helical domains and conserved structures in Pit-1 suggests that POU domain proteins interact with their DNA recognition sites differently than classic homeodomain proteins, with both the POUHD and the POUS domain contacting DNA. Transcriptional activity of Pit-1 on enhancer elements is conferred primarily by a Ser- and Thr-rich N-terminal region unrelated to other known transcription-activating motifs.

The macrophage and B cell-specific transcription factor PU.1 is related to the ets oncogene

We have isolated a cDNA clone, PU.1, that codes for a new tissue-specific DNA binding protein. Analysis of the binding site by methylation interference and DNAase 1 protection revealed that the PU.1 protein recognized a purine-rich sequence, 5'-GAGGAA-3' (PU box). The PU.1 protein was shown to be a transcriptional activator that is expressed in macrophages and B cells. cDNA constructions used to generate proteins lacking portions of either the amino- or carboxy-terminal ends of the PU.1 protein placed the DNA binding domain in the highly basic carboxy-terminal domain of the protein. The amino acid sequence in the binding domain of PU.1 has considerable identity with proteins belonging to the ets oncogene family.

Interaction of the Escherichia coli Gal repressor protein with its DNA operators in vitro

The binding of Escherichia coli Gal repressor to linear DNA fragments containing two binding sites (OE and OI) within the gal operon was analyzed in vitro with quantitative footprint and mobility-shift techniques. In vivo analysis of the regulation of the gal operon [Haber, R., & Adhya, S. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 9683-9687] has suggested the role of a regulatory "looped complex" mediated by the association of Gal repressor dimers bound at OE and OI. The binding of Gal repressor to a single site can be described by a model in which monomer and dimer are in equilibrium and only the dimer binds to DNA. At pH 7.0, 25 mM KCl, and 20 degrees C, the binding and dimerization free energies are comparable, suggesting that the equilibrium governing the formation of dimers may be important to regulation. The two intrinsic binding constants, delta GI and delta GE, and a constant describing cooperativity, delta GIE, were determined by footprint titration analysis as a function of pH, [KCl], and temperature. Only at 4 and 0 degrees C was delta GIE negative, signifying cooperative binding. These results are thought to be due to a weak dimer to tetramer association interface. delta GE and delta GI had maximal values between pH 6 and pH 7. The dependence of these constants on [KCl] corresponded to the displacement of approximately 2 ion equiv. The temperature dependence could be described by a change in the heat capacity, delta Cp, of -2.3 kcal mol-1 deg-1. Mobility-shift titration experiments conducted at 20 and 0 degrees C yielded values for delta GIE that were consistent with those resolved from the footprint analysis. Unique values of delta GIE were determined by analysis of mobility-shift titrations of Gal repressor with wild-type operator subject to the constraint that delta GE = delta GI: a procedure that eliminates the need to simultaneously analyze wild-type titrations with titrations of OE- and OI- operators.

New type of POU domain in germ line-specific protein Oct-4

Members of a family of murine octamer-binding proteins interact specifically with the octamer motif, a transcription regulatory element found in the promoter and enhancer regions of many genes. Oct-4 is a maternally expressed protein that is also present in the pre-implantation mouse embryo. Although many regulatory proteins are expressed in post-implantation embryos, transcription factors regulating pre-implantation processes have remained elusive. The Oct-4 gene is therefore a prime candidate for an early developmental control gene. Here we report the complementary DNA cloning of the mouse Oct-4 gene, and the characterization of the encoded protein(s) by sequential in vitro transcription, translation, DNA-binding and protease-clipping analysis. Deletion analysis shows that the DNA-binding activity is mediated by a POU domain encoded in an open reading frame corresponding to a 324-amino-acid protein. Sequence comparison with known POU domains reveals that Oct-4 is a novel member of the POU-family.

A developmentally regulated trans-acting factor recognizes dissimilar G/C-rich elements controlling a class of cAMP-inducible Dictyostelium genes

Transcriptional response elements involved in the cAMP-inducible and developmentally regulated expression of the Dictyostelium aggregate-stage gene pst-cath/CP2 have been shown to include a G/C-rich sequence element [G-box regulatory element (GBRE)]. We have recently identified a trans-acting factor, GBF (GBRE binding factor), that specifically interacts with this sequence and have shown that the binding activity of GBF to GBRE is developmentally regulated and inducible by cAMP. Here, we examine further the possible role of GBF in the regulation of pst-cath/CP2 and three other coordinately regulated, cAMP-inducible aggregate-stage genes. We show that GBF itself (or other closely related factors) recognizes dissimilar G/C-rich elements present in the 5'-flanking regions of these genes and that the ability of the individual, distinct G/C-rich elements to confer regulated expression on a promoter deletion mutant of the pst-cath/CP2 gene is correlated with the relative affinity for GBF. G/C-rich elements carrying point mutations that prevent in vitro binding of GBF to two of the G/C-rich elements fail to activate expression in vivo. An analysis of major points of contact between the GBF protein and two distinctly different binding sites suggests that binding of GBF to these sequence elements involves a considerable degree of flexibility in DNA-protein interactions. These results suggest that the regulated expression of a class of aggregate-stage cAMP-inducible genes involves the interaction of GBF or homologous factors with dissimilar G/C-rich sequence elements and that induction of GBF activity or that of homologous factors by cAMP may thus be a limiting step in the induction of this temporally coordinate set of genes during Dictyostelium development.

Regulation of cell-type-specific transcription and differentiation of the pituitary

The transcription of rat prolactin and growth hormone genes in vitro requires a pituitary transcription factor, specific to certain cell types in the pituitary, which currently appears to be the PUF-I/Pit-1/GHF-1 protein. This factor binds to cis-regulatory elements in the 5' region of both genes and exerts a positive influence on transcription initiation presumably by interacting with general transcription factors. The PUF-I/Pit-1/GHF-1 transcriptional regulatory protein probably has an important role in not only the differentiation of the pituitary lactotroph/somatotroph cell lineage; it is also expressed in the early development of the nervous system but its function there is less well documented. It appears to be one member of a family of trans-activator proteins involved in differential gene expression in several cell types.

Characterization of chicken octamer-binding proteins demonstrates that POU domain-containing homeobox transcription factors have been highly conserved during vertebrate evolution

The DNA sequence motif ATTTGCAT (octamer) or its inverse complement has been identified as an evolutionarily conserved element in the promoter region of immunoglobulin genes. Two major DNA-binding proteins that bind in a sequence-specific manner to the octamer DNA sequence have been identified in mammalian species--a ubiquitously expressed protein (Oct-1) and a lymphoid-specific protein (Oct-2). During characterization of the promoter region of the chicken immunoglobulin light chain gene, we identified two homologous octamer-binding proteins in chicken B cells. When the cloning of the human gene for Oct-2 revealed it to be a member of a distinct family of homeobox genes, we sought to determine if the human Oct-2 cDNA could be used to identify homologous chicken homeobox genes. Using a human Oct-2 homeobox-specific DNA probe, we were able to identify 6-10 homeobox-containing genes in the chicken genome, demonstrating that the Oct-2-related subfamily of homeobox genes exists in avian species. Low-stringency screening of a chicken embryonic cDNA library allowed us to clone one of these genes. DNA sequence analysis revealed it to be the chicken homologue of the human Oct-1 gene. The predicted protein sequence of the chicken Oct-1 gene demonstrated that the gene for Oct-1 has been highly conserved during vertebrate evolution with an overall 96% amino acid sequence identity between the chicken and human proteins. The previously described POU domain (termed POU for its presence in the Pit-1, Oct-1/Oct-2, and Unc-86 genes) and homeobox domain are 100% conserved between the two protein products. Together, our data show that the POU-containing subfamily of homeobox genes have been highly conserved during vertebrate evolution, apparently as a result of selection for their DNA-binding and transcriptional regulatory properties.

Characterization and expression of two sea urchin homeobox gene sequences

We describe two homeobox sequences, TgHbox5 and TgHbox6, isolated from the Hawaiian sea urchin Tripneustes gratilla using a Drosophila Sex combs reduced probe. Sequence analysis shows that the encoded TgHbox5 homeodomain shares only 30-52% amino acid identity with homeodomains encoded by previously characterized genes, establishing that it is a divergent homeobox that is not in any known class of homeoboxes. TgHbox5 is expressed in the embryo as two major developmentally regulated transcripts. one at 5.0 kilobase (kb) appearing by blastula stage and the other at 2.7 kb appearing at pluteus stage. Multiple transcripts from TgHbox5 are present at a much lower level in adult tissues and are predominantly expressed in small and large intestines. The TgHbox6 homeobox is an Antenna-pedia-class homeobox, which appears not to be expressed during embryogenesis but produces abundant 3.6 and 3.2 kb transcripts in the six adult tissues examined.

A two-base change in a POU factor-binding site switches pituitary-specific to lymphoid-specific gene expression

The structurally related POU homeo domain proteins Pit-1 and Oct-2 activate pituitary- and lymphoid-specific transcription, respectively, by binding to similar AT-rich motifs in their target genes. In this study we identify bases critical for recognition and activation by Pit-1 and examine how small differences in Pit-1 and Oct-2-binding sites can impart differential transcriptional responses in pituitary and B-lymphoid cells. Scanning mutagenesis of Pit-1 response elements in both the rat prolactin and growth hormone genes reveals a critical binding motif recognized in an identical manner by the native Pit-1 protein and cloned Pit-1 gene product. This motif, ATTATTCCAT, differs by only two bases from the octamer element, ATTTGCAT, required for Oct-2-dependent activation of immunoglobulin genes. Cross recognition of Pit-1 and Oct-2 sites by both factors can be demonstrated in competitive binding assays, in which an oligometric Pit-1 site from the prolactin gene is converted to an Oct-2 site by a double point mutation. In contrast to the binding data, no cross activation of transcription is detectable in cultured cell lines. When inserted immediately 5' to a prolactin TATA box, the wild-type prolactin element enhances transcription strongly in pituitary cells but is inactive in B cells, whereas the octamer variant of the prolactin site activates expression in B cells but is silent in pituitary lines. Both elements are nonfunctional in heterologous cell lines that lack Pit-1 and Oct-2.(ABSTRACT TRUNCATED AT 250 WORDS)

Interleukin 6 induces a liver-specific nuclear protein that binds to the promoter of acute-phase genes

Interleukin 6 (IL-6) is responsible for a variety of biological effects related to the activation of defenses against infection or inflammation, including the immune response and the acute-phase reaction. Its mechanism of action is unknown. It has recently been shown to induce transcription of several genes encoding acute-phase proteins. Here we describe the identification of an IL-6 responsive element (IL-6RE) present in the promoter of the human hemopexin gene. This element is necessary and sufficient for the IL-6-dependent activation of transcription. The IL-6 effect does not require de novo protein synthesis. A liver-specific nuclear protein (IL-6DBP) binds to the hemopexin IL-6RE as well as to similar sequences on the promoter of other acute-phase genes. IL-6DBP DNA binding activity is induced by IL-6 via a posttranslational mechanism.

The Oct-1 homoeodomain directs formation of a multiprotein-DNA complex with the HSV transactivator VP16

The herpes simplex virus transactivator VP16 participates in the formation of a multiprotein-DNA complex with the ubiquitous octamer-motif-binding factor Oct-1. Complex formation is dependent on specific amino acids in the Oct-1 homoeodomain which are in positions analogous to positive control mutations in helix 2 of the lambda phage repressor helix-turn-helix motif, indicating that this structure is an ancient target for protein-protein interactions mediating transcriptional control.

The Oct-2 protein binds cooperatively to adjacent octamer sites

Recombinant proteins derived from the cloned human oct-2 gene were used to investigate cooperative binding by Oct-2 to adjacent DNA-binding sites. Oct-2, a B-cell-specific transcription factor, binds tightly to the octamer sequence in immunoglobulin promoters. A second apparently unrelated consensus sequence in heavy chain promoters, the heptamer site, also is recognized by the Oct-2 protein but with 1000-fold lower affinity. Simultaneous occupancy of both the octamer and heptamer sites is favored by cooperative interactions. The heptamer site is probably recognized by the same binding surface in the Oct-2 protein as the octamer site and thus is conserved as a lower-affinity binding site. This permits the immunoglobulin promoter to respond to a much broader range of levels of Oct-2 protein. Substitution of prototype octamer sequences for heptamer sequences yields a probe with two octamer sites spaced by 2 nucleotides, which also binds Oct-2 protein cooperatively. Only the POU domain in the Oct-2 protein is required for this cooperative interaction. Similar protein-protein interactions between bound Oct-2 proteins may promote promoter-enhancer synergism in the heavy chain gene.

Fine-tuning of MHC class II gene expression in defined microenvironments

Strict control of major histocompatibility complex class II gene expression is essential for proper functioning of the immune system. Recent transgenic mouse studies have revealed an intricate fine-tuning of class II gene transcription in microenvironments such as the germinal centers and thymic cortex and medulla.