Host defense mechanisms triggered by microbial lipoproteins through toll-like receptors.

The generation of cell-mediated immunity against many infectious pathogens involves the production of interleukin-12 (IL-12), a key signal of the innate immune system. Yet, for many pathogens, the molecules that induce IL-12 production by macrophages and the mechanisms by which they do so remain undefined. Here it is shown that microbial lipoproteins are potent stimulators of IL-12 production by human macrophages, and that induction is mediated by Toll-like receptors (TLRs). Several lipoproteins stimulated TLR-dependent transcription of inducible nitric oxide synthase and the production of nitric oxide, a powerful microbicidal pathway. Activation of TLRs by microbial lipoproteins may initiate innate defense mechanisms against infectious pathogens.

Transcription of herpes simplex virus tk sequences under the control of wild-type and mutant human RNA polymerase I promoters.

We studied RNA polymerase I transcription in cells transfected with a plasmid, prHuTK, containing the herpes simplex virus tk gene fused to a human rRNA promoter. Primer extension analysis of tk RNA isolated from COS cells transfected with prHuTK reveals that transcription from the RNA polymerase I promoter is highly efficient and initiates at the same position used for the synthesis of endogenous rRNA in HeLa cells. The RNA products derived from prHuTK are distinguishable from normal RNA polymerase II transcripts of tk in that they are not polyadenylated, are extremely unstable, and are found predominantly in the nucleus. Moreover, the transcription observed is resistant to 300 micrograms of alpha-amanitin per ml. These results strongly suggest that prHuTK transcription is under the control of the human rRNA promoter and RNA polymerase I. To further characterize the activity of the human rDNA promoter in vivo, a series of 5' and 3' deletion mutants was tested in this transfection assay. The deletion analysis indicates that a core region of ca. 40 base pairs overlapping the initiation site is critical for transcription. In addition, a region between nucleotides -234 and -131 upstream from the core sequence serves to modulate the efficiency of transcription. Insertion into prHuTK of additional ribosomal nontranscribed spacer DNA or the simian virus 40 enhancer element has no apparent effect on the promoter activity. Surprisingly, RNA polymerase II transcripts synthesized at low levels from two start sites within the core control element of the wild-type RNA polymerase I promoter are activated upon deletion of upstream RNA polymerase I promoter sequences. However, these RNA polymerase II transcripts are not expressed from the endogenous rRNA promoter.

T-antigen-DNA polymerase alpha complex implicated in simian virus 40 DNA replication.

We have combined in vitro DNA replication reactions and immunological techniques to analyze biochemical interactions between simian virus (SV40) large T antigen and components of the cellular replication apparatus. First, in vitro SV40 DNA replication was characterized with specific origin mutants. Next, monoclonal antibodies were used to demonstrate that a specific domain of T antigen formed a complex with cellular DNA polymerase alpha. Several antibodies were identified that coprecipitated T antigen and DNA polymerase alpha, while others were found to selectively prevent this interaction and concomitantly inhibit DNA replication. DNA polymerase alpha also bound efficiently to a T-antigen affinity column, confirming the immunoprecipitation results and providing a useful method for purification of the complete protein complex. Taken together, these results suggest that the T-antigen-polymerase association may be a key step in the initiation of SV40 DNA replication.

Both LyF-1 and an Ets protein interact with a critical promoter element in the murine terminal transferase gene.

Terminal deoxynucleotidyltransferase (TdT) is a template-independent DNA polymerase that is expressed transiently during the earliest stages of B- and T-cell ontogeny. Previously, we characterized the promoter for the murine TdT gene and identified a novel DNA-binding protein, called LyF-1, that interacts with a DNA sequence element found to be critical for transcriptional activity in lymphoid cell lines. Here, we present a more detailed analysis of this 30-bp control element, called the TdT D' element, which is centered approximately 60 bp upstream of the transcription start site. We found that both the murine and human D' elements are recognized by multiple proteins, including LyF-1 and at least two Ets family proteins, Ets-1 and Fli-1. Additional protein-DNA interactions were identified through studies using unfractionated nuclear extracts, in which the D' element was apparently incorporated into a multiprotein complex, possibly containing an Ets protein as a core component. By analyzing a series of substitution mutations, two adjacent binding sites for LyF-1 were identified in the murine D' element, with the Ets protein binding site closely coinciding with the proximal, lower-affinity LyF-1 site. Transient transfection analysis with these mutations revealed that only a 10-bp region, containing precisely the Ets and proximal LyF-1 binding sites, was needed for D' activity. These results suggest an important role for an Ets family protein in the expression of the TdT gene. The role of LyF-1 is less clear; it might act in conjunction with the Ets protein bound at the D' element or it might be unnecessary for D' activity.

Two distinct promoter elements in the human rRNA gene identified by linker scanning mutagenesis.

A cell-free RNA polymerase I transcription system was used to evaluate the transcription efficiency of 21 linker scanning mutations that span the human rRNA gene promoter. Our analysis revealed the presence of two major control elements, designated the core and upstream elements, that affect the level of transcription initiation. The core element extends from -45 to +18 relative to the RNA start site, and transcription is severely affected (up to 100-fold) by linker scanning mutations in this region. Linker scanning and deletion mutations in the upstream element, located between nucleotides -156 and -107, cause a three- to fivefold reduction in transcription. Under certain reaction conditions, such as the presence of a high ratio of protein to template or supplementation of the reaction with partially purified protein fractions, sequences upstream of the core element can have an even greater effect (20- to 50-fold) on RNA polymerase I transcription. Primer extension analysis showed that RNA synthesized from all of these mutant templates is initiated at the correct in vivo start site. To examine the functional relationship between the core and the upstream region, mutant promoters were constructed that alter the orientation, distance, or multiplicity of these control elements relative to each other. The upstream control element appears to function in only one orientation, and its position relative to the core is constrained within a fairly narrow region. Moreover, multiple core elements in close proximity to each other have an inhibitory effect on transcription.

LyF-1, a transcriptional regulator that interacts with a novel class of promoters for lymphocyte-specific genes.

We have studied transcriptional control of the murine terminal deoxynucleotidyltransferase (TdT) gene, which is activated specifically in immature B and T lymphocytes. This analysis has led to the identification and purification of a 50-kDa sequence-specific DNA-binding protein, LyF-1, that interacts with the approximate consensus sequence PyPyTGGGAGPu and is enriched in cells at most stages of B- and T-cell differentiation. LyF-1 binds tightly to an element in the TdT promoter that we show is required for transcription in lymphocytes. LyF-1 also interacts with an element in the immunoglobulin mu enhancer, called microB, that was recently shown to be important for lymphocyte-specific enhancer activity. Moreover, LyF-1 binds to the promoters for the lymphocyte-specific genes lambda 5, VpreB, and lck, all of which we speculate have additional features in common with the TdT promoter. Thus, LyF-1 may be a general transcriptional activator for genes whose expression is restricted to the B- and/or T-lymphocyte lineages.

Core promoter specificities of the Sp1 and VP16 transcriptional activation domains.

The core promoter compositions of mammalian protein-coding genes are highly variable; some contain TATA boxes, some contain initiator (Inr) elements, and others contain both or neither of these basal elements. The underlying reason for this heterogeneity remains a mystery, as recent studies have suggested that TATA-containing and Inr-containing core promoters direct transcription initiation by similar mechanisms and respond similarly to a wide variety of upstream activators. To analyze in greater detail the influence of core promoter structure on transcriptional activation, we compared activation by GAL4-VP16 and Sp1 through synthetic core promoters containing a TATA box, an Inr, or both TATA and Inr. Striking differences were found between the two activators, most notably in the relative strengths of the TATA/Inr and Inr core promoters: the TATA/Inr promoter was much stronger than the Inr promoter when transcription was activated by GAL4-VP16, but the strengths of the two promoters were more comparable when transcription was activated by Sp1. To define the domains of Sp1 responsible for efficient activation through an Inr, several Sp1 deletion mutants were tested as GAL4 fusion proteins. The results reveal that the glutamine-rich activation domains, which previously were found to interact with Drosophila TAF110, preferentially stimulate Inr-containing core promoters. In contrast, efficient activation through TATA appears to require additional domains of Sp1. These results demonstrate that activation domains differ in their abilities to function with specific core promoters, suggesting that the core promoter structure found in a given gene may reflect a preference of the regulators of that gene. Furthermore, the core promoter preference of an activation domain may be related to a specific mechanism of action, which may provide a functional criterion for grouping activation domains into distinct classes.

CIF150, a human cofactor for transcription factor IID-dependent initiator function.

The transcription factor IID (TFIID) complex is highly conserved between the Drosophila and mammalian systems. A mammalian homolog has been described for all the Drosophila TATA box-binding protein-associated factors (TAFs), with the exception of dTAF(II)150. We previously reported the identification of CIF, an essential cofactor for TFIID-dependent transcription from promoters containing initiator (Inr) elements. Here we describe the molecular cloning of CIF150, the human homolog of dTAF(II)150, and present biochemical evidence that this factor is involved in Inr activity. CIF150 is capable of mediating TFIID-dependent Inr activity in a complementation assay, and a protein fraction lacking Inr activity lacks detectable amounts of CIF150. Despite the striking similarity to dTAF(II)150, CIF150 does not appear to be associated with human TFIID. However, in vitro binding assays revealed a specific and direct interaction between CIF150 and hTAF(II)135. This interaction might be structurally important for the functional interaction between CIF150 and human TFIID, since CIF150 stabilizes TFIID binding to a core promoter.

DNA sequence requirements for transcriptional initiator activity in mammalian cells.

A transcriptional initiator (Inr) for mammalian RNA polymerase II can be defined as a DNA sequence element that overlaps a transcription start site and is sufficient for (i) determining the start site location in a promoter that lacks a TATA box and (ii) enhancing the strength of a promoter that contains a TATA box. We have prepared synthetic promoters containing random nucleotides downstream of Sp1 binding sites to determine the range of DNA sequences that convey Inr activity. Numerous sequences behaved as functional Inrs in an in vitro transcription assay, but the Inr activities varied dramatically. An examination of the functional elements revealed loose but consistent sequence requirements, with the approximate consensus sequence Py Py A+1 N T/A Py Py. Most importantly, almost every functional Inr that has been described fits into the consensus sequence that we have defined. Although several proteins have been reported to bind to specific Inrs, manipulation of those elements failed to correlate protein binding with Inr activity. The simplest model to explain these results is that all or most Inrs are recognized by a universal binding protein, similar to the functional recognition of all TATA sequences by the same TATA-binding protein. The previously reported proteins that bind near specific Inr elements may augment the strength of an Inr or may impart transcriptional regulation through an Inr.

Mechanism of initiator-mediated transcription: evidence for a functional interaction between the TATA-binding protein and DNA in the absence of a specific recognition sequence.

Promoters containing Sp1 binding sites and an initiator element but lacking a TATA box direct high levels of accurate transcription initiation by using a mechanism that requires the TATA-binding protein (TBP). We have begun to address the role of TBP during transcription from Sp1-initiator promoters by varying the nucleotide sequence between -14 and -33 relative to the start site. With each of several promoters containing different upstream sequences, we detected accurate transcription both in vitro and in vivo, but the promoter strengths varied widely, particularly with the in vitro assay. The variable promoter activities correlated with, but were not proportional to, the abilities of the upstream sequences to function as TATA boxes, as assessed by multiple criteria. These results confirm that accurate transcription can proceed in the presence of an initiator, regardless of the sequence present in the -30 region. However, the results reveal a role for this upstream region, most consistent with a model in which initiator-mediated transcription requires binding of TBP to the upstream DNA in the absence of a specific recognition sequence. Moreover, in vivo it appears that the promoter strength is modulated less severely by altering the -30 sequence, consistent with a previous suggestion that TBP is not rate limiting in vivo for TATA-less promoters. Taken together, these results suggest that variations in the structure of a core promoter might alter the rate-limiting step for transcription initiation and thereby alter the potential modes of transcriptional regulation, without severely changing the pathway used to assemble a functional preinitiation complex.

Multiple control elements mediate activation of the murine and human interleukin 12 p40 promoters: evidence of functional synergy between C/EBP and Rel proteins.

Interleukin 12 (IL-12) is a heterodimeric cytokine whose activity is critical for T-helper 1 responses. The gene for the IL-12 p40 subunit is expressed in macrophages following induction by bacterial products, and its expression is augmented by gamma interferon. In this study, we performed a functional analysis of the murine and human p40 promoters in the murine macrophage cell line RAW 264.7. Transcription from the murine p40 promoter was strongly induced by lipopolysaccharide and heat-killed Listeria monocytogenes (HKLM), but promoter activity was not enhanced by gamma interferon. Multiple cis-acting elements involved in activated transcription were identified through an extensive mutant analysis. The most critical element, whose activity is conserved in mice and humans, is located between positions -96 and -88 relative to the murine transcription start site. This element exhibits functional synergy with a previously described NF-kappaB half-site which interacts with Rel proteins. DNase I footprinting and electrophoretic mobility shift assays demonstrated that C/EBP proteins interact with the critical element, but in nuclear extracts, cooperative binding of C/EBP and Rel proteins to their respective sites was not observed. Interestingly, promoter activity was induced by HKLM in the presence of cycloheximide, consistent with induction by posttranslational mechanisms. The results suggest that C/EBP and Rel proteins play important roles in the activation of IL-12 p40 transcription by bacteria. However, many complex interactions will need to be clarified to fully understand p40 regulation.

A potential role for Elf-1 in terminal transferase gene regulation.

The terminal deoxynucleotidyltransferase (TdT) gene represents an attractive model for the analysis of gene regulation during an early phase of lymphocyte development. In previous studies, we identified a DNA element, termed D', which is essential for TdT promoter activity in immature lymphocytes, and two classes of D'-binding factors, Ikaros proteins and Ets proteins. Here, we report a detailed mutant analysis of the D' element which suggests that an Ets protein, rather than an Ikaros protein, activates TdT transcription. Since multiple Ets proteins are expressed in developing lymphocytes and are capable of binding to the D' element, DNA affinity chromatography was used to determine if one of the Ets proteins might bind to the D' element with a uniquely high affinity, thereby implicating that protein as a potential TdT activator. Indeed, one binding activity was greatly enriched in the high-salt eluates from a D' affinity column. Peptide microsequencing revealed that the enriched protein was Elf-1. Immunoblot analyses confirmed that in nuclear extracts, Elf-1 has a significantly higher affinity for the D' sequence than does another Ets protein, Ets-1. Transactivation and expression studies support the hypothesis that Elf-1 activates TdT transcription in immature T and B cells. Finally, a D' mutation which selectively reduces Elf-1 binding, but not the binding of other Ets proteins, was found to greatly reduce TdT promoter activity. Although Elf-1 previously had been implicated in the inducible activation of genes in mature T and B cells, our results suggest that it also plays an important role in regulating genes during an early phase of lymphocyte development.

Initiator recognition in a primitive eukaryote: IBP39, an initiator-binding protein from Trichomonas vaginalis.

While considerable progress has been made in understanding the mechanisms of transcription in higher eukaryotes, transcription in single-celled, primitive eukaryotes remains poorly understood. Promoters of protein-encoding genes in the parasitic protist Trichomonas vaginalis, which represents one of the deepest-branching eukaryotic lineages, have a bipartite structure with gene-specific regulatory elements and a conserved core promoter encompassing the transcription start site. Core promoters in T. vaginalis appear to consist solely of a highly conserved initiator (Inr) element that is both a structural and a functional homologue of its metazoan counterpart. Using DNA affinity chromatography, we have isolated an Inr-binding protein from T. vaginalis. Cloning of the gene encoding the Inr binding protein identified a novel 39-kDa protein (IBP39). We show that IBP39 binds to both double and single Inr motifs found in T. vaginalis genes and that binding requires the conserved nucleotides necessary for Inr function in vivo. Analyses of the cloned IBP39 gene revealed no homology at the protein sequence level with identified proteins in other organisms or the presence of known DNA-binding domains. The relationship between IBP39 and Inr-binding proteins in metazoa presents interesting evolutionary questions.

The lymphoid transcription factor LyF-1 is encoded by specific, alternatively spliced mRNAs derived from the Ikaros gene.

The lymphocyte-specific DNA-binding protein LyF-1 interacts with a critical control element in the terminal deoxynucleotidyltransferase (TdT) promoter as well as with the promoters for other genes expressed during early stages of B- and T-cell development. We have purified LyF-1 and have obtained a partial amino acid sequence from proteolytic peptides. The amino acid sequence suggests that LyF-1 is a zinc finger protein encoded by the Ikaros gene, which previously was implicated in T-cell development. Recombinant Ikaros expressed in Escherichia coli bound to the TdT promoter, and antisera directed against the recombinant protein specifically blocked the DNA-binding activity of LyF-1 in crude extracts. Further analysis revealed that at least six distinct mRNAs are derived from the Ikaros/LyF-1 gene by alternative splicing. Only two of the isoforms possess the N-terminal zinc finger domain that is necessary and sufficient for TdT promoter binding. Although both of these isoforms bound to similar sequences in the TdT, lambda 5, VpreB, and lck promoters, one isoform contains an additional zinc finger that resulted in altered recognition of some binding sites. At least four of the Ikaros/LyF-1 isoforms were detectable in extracts from B- and T-cell lines, with the relative amounts of the isoforms varying considerably. These data reveal that the LyF-1 protein is encoded by specific mRNAs derived from the alternatively-spliced Ikaros gene, suggesting that this gene may be important for the early stages of both B- and T-lymphocyte development.

Ikaros-family proteins: in search of molecular functions during lymphocyte development.

The regulatory steps that lead to the differentiation of hematopoietic cells from a multipotential stem cell remain largely unknown. A beginning to the understanding of these steps has come from the study of DNA-binding proteins that are thought to regulate the expression of genes required for specific developmental events. Ikaros is the founding member of a small family of DNA-binding proteins required for lymphocyte development, but the members of this family differ from other key regulators of lymphopoiesis in that direct target genes have not been conclusively identified, and reasonable support has been presented for only a few potential targets. Therefore, the molecular mechanisms that Ikaros uses for regulating lymphocyte development remain largely unknown. Current data suggest that, in some instances, Ikaros may function as a typical transcription factor. However, recent results suggest that it may function more broadly, perhaps in the formation of silent and active chromatin structures. In this review, our current knowledge of the molecular functions of Ikaros will be discussed.

Generality of a functional initiator consensus sequence.

Transcriptional initiator (Inr) elements, like TATA boxes, are found in the core promoters of many eukaryotic protein-coding genes. To facilitate the dissection of transcription initiation mechanisms, and to identify Inr elements within known and newly-discovered genes, the precise DNA sequence requirements for Inr activity must be defined. Previously, we reported a preliminary Inr consensus sequence based on an extensive mutant analysis carried out in HeLa cell extracts. This analysis was limited, however, because it was performed only with an in vitro transcription assay and with the mutants in only one promoter context. In this study, we have assessed the general validity of the functional Inr consensus sequence by analyzing a selected set of mutants in additional promoter contexts and with both in vivo and in vitro assays. In addition, we analyzed the evolutionary conservation of the Inr consensus sequence by determining the sequence requirements for Inr function in Drosophila embryo extracts. The results demonstrate the generality and strict conservation among vertebrates and invertebrates of the Inr consensus sequence, Py Py A+1 N T/A Py Py.

Pioneer factors, genetic competence, and inductive signaling: programming liver and pancreas progenitors from the endoderm.

The endoderm is a multipotent progenitor cell population in the embryo that gives rise to the liver, pancreas, and other cell types and provides paradigms for understanding cell-type specification. Studies of isolated embryo tissue cells and genetic approaches in vivo have defined fibroblast growth factor/mitogen-activated protein kinase (FGF/MAPK) and bone morphogenetic protein (BMP) signaling pathways that induce liver and pancreatic fates in the endoderm. In undifferentiated endoderm cells, the FoxA and GATA transcription factors are among the first to engage silent genes, helping to endow competence for cell-type specification. FoxA proteins can bind their target sites in highly compacted chromatin and open up the local region for other factors to bind; hence, they have been termed "pioneer factors." We recently found that FoxA proteins remain bound to chromatin in mitosis, as an epigenetic mark. In embryonic stem cells, which lack FoxA, FoxA target sites can be occupied by FoxD3, which in turn helps to maintain a local demethylation of chromatin. By these means, a cascade of Fox factors helps to endow progenitor cells with the competence to activate genes in response to tissue-inductive signals. Understanding such epigenetic mechanisms for transcriptional competence coupled with knowledge of the relevant signals for cell-type specification should greatly facilitate efforts to predictably differentiate stem cells to liver and pancreatic fates.

The "initiator" as a transcription control element.

Transcription of the lymphocyte-specific terminal deoxynucleotidyltransferase gene begins at a single nucleotide, but no TATA box is present. We have identified a 17 bp element that is sufficient for accurate basal transcription of this gene both in vitro and in vivo. This motif, the initiator (Inr), contains within itself the transcription start site. Homology to the Inr is found in many TATA-containing genes, and specific mutagenesis influences both the efficiency and accuracy of initiation. Moreover, in the presence of either a TATA box or the SV40 21 bp repeats, a greatly increased level of transcription initiates specifically at the Inr. Thus, the Inr constitutes the simplest functional promoter that has been identified and provides one explanation for how promoters that lack TATA elements direct transcription initiation.

Inhibition of simian virus 40 DNA replication by specific modification of T-antigen with oxidized ATP.

We covalently bound periodate-oxidized ATP (oATP) to purified simian virus 40 (SV40) large T-antigen and determined the effect of this modification on viral DNA replication and three other biochemical activities of T-antigen. The oATP bound specifically to T-antigen, inhibiting the ATPase activity and preventing T-antigen from activating SV40 DNA replication in vitro. In contrast, binding of oATP had no effect on the DNA-binding activity of T-antigen nor on its ability to form a complex with DNA polymerase alpha. These results provide direct biochemical evidence suggesting that the T-antigen ATPase activity is necessary for viral DNA replication.