Expanded polyglutamine stretches interact with TAFII130, interfering with CREB-dependent transcription.

At least eight inherited neurodegenerative diseases are caused by expanded CAG repeats encoding polyglutamine (polyQ) stretches. Although cytotoxicities of expanded polyQ stretches are implicated, the molecular mechanisms of neurodegeneration remain unclear. We found that expanded polyQ stretches preferentially bind to TAFII130, a coactivator involved in cAMP-responsive element binding protein (CREB)-dependent transcriptional activation, and strongly suppress CREB-dependent transcriptional activation. The suppression of CREB-dependent transcription and the cell death induced by polyQ stretches were restored by the co-expression of TAFII130. Our results indicate that interference of transcription by the binding of TAFII130 with expanded polyQ stretches is involved in the pathogenetic mechanisms underlying neurodegeneration.

Functional domains and upstream activation properties of cloned human TATA binding protein.

The TATA binding protein, TFIID, plays a central role in the initiation of eukaryotic mRNA synthesis. Here, we present a human cDNA clone for this factor. Comparison of its predicted protein sequence with those from Drosophila and yeast reveals a highly conserved carboxyl-terminal 180 amino acids. By contrast, the amino-terminal region of TFIID has diverged in both sequence and length. A striking feature of the human protein is a stretch of 38 glutamine residues in the NH2-terminal region. Expression of human TFIID in both Escherichia coli and HeLa cells produces a protein that binds specifically to a TATA box and promotes basal transcription; the conserved COOH-terminal portion of the protein is sufficient for both of these activities. Recombinant TFIID forms a stable complex on a TATA box either alone or in combination with either of the general transcription factors, TFIIA or TFIIB. Full-length recombinant TFIID is able to support Sp1 activated transcription in a TFIID-depleted nuclear extract, while a deletion of the NH2-terminal half of the protein is not. These results indicate the importance of the NH2-terminal region for upstream activation functions and suggest that additional factors (co-activators) are required for mediating interactions with specific regulators.

Distinct subdomains of human TAFII130 are required for interactions with glutamine-rich transcriptional activators.

TFIID is a multiprotein complex consisting of the TATA box binding protein and multiple tightly associated proteins (TAFIIs) that are required for transcription by selected activators. We previously reported cloning and partial characterization of human TAFII130 (hTAFII130). The central domain of hTAFII130 contains four glutamine-rich regions, designated Q1 to Q4, that are involved in interactions with the transcriptional activator Sp1. Mutational analysis has revealed specific regions within the glutamine-rich (Q1 to Q4) central region of hTAFII130 that are required for interaction with distinct activation domains. We tested amino- and carboxyl-terminal deletions of hTAFII130 for interaction with Sp1 activation domains A and B (Sp1A and Sp1B) and the N-terminal activation domain of CREB (CREB-N) by using the yeast two-hybrid system. Our results indicate that Sp1B interacts almost exclusively with the Q1 region of hTAFII130. In contrast, Sp1A makes multiple contacts with Q1 to Q4 of hTAFII130, while CREB-N interacts primarily with the Q1-Q2 hTAFII130 subdomain. Consistent with these interaction studies, overexpression of the Q1-to-Q4 region in HeLa cells inhibits Sp1- but not VP16-mediated transcriptional activation. These findings indicate that the Q1-to-Q4 region of hTAFII130 is required for Sp1-mediated transcriptional enhancement in mammalian cells and that different activation domains target distinct subdomains of hTAFII130.

Complementary DNA sequence of a human cytoplasmic actin. Interspecies divergence of 3' non-coding regions.

We have isolated and sequenced a cloned complementary DNA insert complementary to the messenger RNA of a cytoplasmic actin expressed in human epidermal cells. This provides the first cytoplasmic actin complementary DNA sequence for a vertebrate organism. The actin amino acid sequence predicted from this complementary DNA is identical to that of a bovine cytoplasmic actin and shows 98 and 85% homology with a Dictyostelium and a yeast actin, respectively. The complementary DNA sequence indicates that the 3' end of the mRNA contains an unusually long (greater than 400 nucleotides) 3' non-translated region. A comparison of this 3' non-coding region with those of recently determined actin complementary DNA sequences from other species reveals little or no homology among these sequences. Thus, these results indicate that although the actin amino acid sequences are extremely conserved, the non-coding regions of the mRNAs diverge rapidly.

Gene product of Moloney murine leukemia virus required for proviral integration is a DNA-binding protein.

The 3'-terminal portion of the retroviral pol gene encodes a function required for the formation of the integrated provirus soon after infection of sensitive cells. To permit the isolation of large quantities of the gene product, we expressed various portions of the pol gene of Moloney murine leukemia virus (M-MuLV) as trpE fusion proteins in Escherichia coli. The proteins were found to exhibit strong DNA-binding activity after extraction and renaturation by two different procedures. In the first method, proteins separated by polyacrylamide gel electrophoresis were blotted to nitrocellulose and assayed when bound to the support. The second procedure involved the isolation of proteins in an insoluble fraction, solubilization with guanidine, and renaturation. The characteristics of the binding activity are described and compared with those of authentic viral protein.

A novel gene, GliH1, with homology to the Gli zinc finger domain not required for mouse development.

The Sonic hedgehog (Shh)-Gli signaling pathway regulates development of many organs, including teeth. We cloned a novel gene encoding a transcription factor that contains a zinc finger domain with highest homology to the Gli family of proteins (61-64% amino acid sequence identity) from incisor pulp. Consistent with this sequence conservation, gel mobility shift assays demonstrated that this new Gli homologous protein, GliH1, could bind previously characterized Gli DNA binding sites. Furthermore, transfection assays in dental pulp cells showed that whereas Gli1 induces a nearly 50-fold increase in activity of a luciferase reporter containing Gli DNA binding sites, coexpression of Gli1 with Gli3 and/or GliH1 results in inhibition of the Gli1-stimulated luciferase activity. In situ hybridization analysis of mouse embryos demonstrated that GliH1 expression is initiated later than the three Gli genes and has a more restricted expression pattern. GliH1 is first detected diffusely in the limb buds at 10.0 days post coitus and later is expressed in the branchial arches, craniofacial interface, ventral part of the tail, whisker follicles and hair, intervertebral discs, teeth, eyes and kidney. LacZ was inserted into the GliH1 allele in embryonic stem cells to produce mice lacking GliH1 function. While this produced indicator mice for GliH1-expression, analysis of mutant mice revealed no discernible phenotype or required function for GliH1. A search of the Celera Genomics and associated databases identified possible gene sequences encoding a zinc finger domain with approximately 90% homology to that of GliH1, indicating there is a family of GliH genes and raising the possibility of overlapping functions during development.

Small-scale density gradient sedimentation to separate and analyze multiprotein complexes.

The transcription factor TFIID is a multisubunit complex that is required for promoter recognition and accurate initiation of transcription by RNA polymerase II. To dissect the molecular architecture and the biochemical properties of TFIID, a small-scale density gradient sedimentation method is employed to separate related complexes through differences in their sedimentation properties. A small amount of starting material is sufficient to obtain readily assayable amounts of separated proteins after centrifugation for 8 to 12 h in a benchtop ultracentrifuge. Gradient fractions are analyzed by immunoblotting for the presence of specific components of TFIID. Sucrose gradient sedimentation is performed to separate a mixture of multiprotein complexes from a crude nuclear extract immunoprecipitation of the proteins present in each fraction with an anti-TBP antibody reveals multiple TBP-containing complexes of different sizes. Density gradient sedimentation permits separation of specific components in a complex mixture and preserves activity, allowing functional assays.

Assembly of partial TFIID complexes in mammalian cells reveals distinct activities associated with individual TATA box-binding protein-associated factors.

The TATA box-binding protein (TBP) and TBP-associated factors (TAF(II)s) compose the general transcription factor TFIID. The TAF(II) subunits mediate activated transcription by RNA polymerase II by interacting directly with site-specific transcriptional regulators. TAF(II)s also participate in promoter recognition by contacting core promoter elements in the context of TFIID. To further dissect the contribution of individual TAF(II) subunits to mammalian TFIID function, we employed a vaccinia virus-based protein expression system to study protein-protein interactions and complex assembly. We identified the domains of human (h) TAF(II)130 required for TAF(II)-TAF(II) interactions and formation of a complex with hTBP, hTAF(II)100, and hTAF(II)250. Functional analysis of partial TFIID complexes formed in vivo indicated that hTAF(II)130 was required for transcriptional activation by Sp1 in vitro. DNase I footprinting experiments demonstrated that purified hTBP/hTAF(II)250 complex reconstituted with or without additional TAF(II)s was significantly reduced for TATA box binding (as much as 9-fold) compared with free hTBP. By contrast, hTAF(II)130 stabilized binding of hTBP to the TATA box, whereas hTAF(II)100 had little effect. Thus, our biochemical analysis supports the notion that TAF(II)s possess distinct functions to regulate the activity of TFIID.

Domain structure of the Moloney murine leukemia virus reverse transcriptase: mutational analysis and separate expression of the DNA polymerase and RNase H activities.

The reverse transcriptase of Moloney murine leukemia virus, like that of all retroviruses, exhibits a DNA polymerase activity capable of synthesis on RNA or DNA templates and an RNase H activity with specificity for RNA in the form of an RNA.DNA hybrid. We have generated a library of linker insertion mutants of the Moloney murine leukemia virus enzyme expressed in bacteria and assayed these mutants for both enzymatic activities. Those mutations affecting the DNA polymerase activity were clustered in the 5'-proximal two-thirds of the gene, and those affecting RNase H were in the remaining 3' one-third. Based on these maps, plasmids were made that expressed each one of the domains separately; assays of the proteins encoded by these plasmids showed that each domain exhibited only the expected activity.

The TATA-binding protein and associated factors are integral components of the RNA polymerase I transcription factor, SL1.

We have previously shown that the TATA-binding protein (TBP) and multiple TBP-associated factors (TAFs) are required for regulated transcriptional initiation by RNA polymerase II. Here we report the biochemical properties of the RNA polymerase I promoter selectivity factor, SL1, and its relationship to TBP. Column chromatography and glycerol gradient sedimentation indicate that a subpopulation of TBP copurifies with SL1 activity. Antibodies directed against TBP efficiently deplete SL1 transcriptional activity, which can be restored with the SL1 fraction but not purified TBP. Thus, TBP is necessary but not sufficient to complement SL1 activity. Analysis of purified SL1 reveals a complex containing TBP and three distinct TAFs. Purified TAFs reconstituted with recombinant TBP complement SL1 activity, and this demonstrates that TBP plus novel associated factors are integral components of SL1. These findings suggest that TBP may be a universal transcription factor and that the TBP-TAF arrangement provides a unifying mechanism for promoter recognition in animal cells.

Abortive reverse transcription by mutants of Moloney murine leukemia virus deficient in the reverse transcriptase-associated RNase H function.

The reverse transcriptase enzymes of retroviruses are multifunctional proteins containing both DNA polymerase activity and a nuclease activity, termed RNase H, specific for RNA in RNA-DNA hybrid form. To determine the role of RNase H activity in retroviral replication, we constructed a series of mutant genomes of Moloney murine leukemia virus that encoded reverse transcriptase enzymes that were specifically altered to retain polymerase function but lack RNase H activity. The mutant genomes were all replication defective. Analysis of in vitro reverse transcription reactions carried out by mutant virions showed that minus-strand strong-stop DNA was formed but did not efficiently translocate to the 3' end of the genome; rather, the DNA was stably retained in RNA-DNA hybrid form. Plus-strand strong-stop DNA was not detected. These results suggest that RNase H normally promotes strong-stop translocation, perhaps by exposing single-stranded DNA sequences for base pairing. Four new DNA species were also detected among the reaction products. Analysis of these DNAs suggested that they were minus-strand DNAs formed from VL30 RNAs encoded by the mouse genome. We suggest that reverse transcriptase can initiate DNA synthesis at any one of four alternate tRNA primer-binding sites near the 5' ends of VL30 RNAs.

Structural requirements for bacterial expression of stable, enzymatically active fusion proteins containing the human immunodeficiency virus reverse transcriptase.

A collection of variant plasmids that express the human immunodeficiency virus (HIV) reverse transcriptase as trpE fusion proteins were generated and scored for their ability to produce stable, active proteins. Trimming portions of the viral pol gene resulted in dramatic increases in yield over earlier constructs; the accumulation of high levels of enzymatically active protein in this system was increased by the retention of the trpE sequences at the amino terminus. A new in situ gel activity assay was used to demonstrate that the major induced protein, containing approximately 68 kD of viral sequences, was the active species.

Analysis of retroviral pol gene products with antisera raised against fusion proteins produced in Escherichia coli.

Portions of the pol gene of Moloney murine leukemia virus (MuLV) were expressed as fusion proteins in Escherichia coli, and the purified proteins were used to elicit antibodies in Escherichia coli, and the purified proteins were used to elicit antibodies in rabbits. The sera were used to examine the mature pol gene products contained in virion particles and identified the reverse transcriptase and a second protein, P46pol, encoded by the 3' portion of the gene. The P46 protein was not phosphorylated and was present at the same molar abundance as the reverse transcriptase. The sera were also used to detect the Pr200gag-pol intracellular precursor protein and to analyze its processing to the mature forms. The proteins formed by several Moloney MuLV mutants were analyzed. Further tests revealed cross-reactivity with Friend MuLV and feline leukemia virus proteins, but not with avian retrovirus proteins.

An insertion mutation in the pol gene of Moloney murine leukemia virus results in temperature-sensitive pol maturation and viral replication.

An insertion mutation in the pol gene of Moloney murine leukemia virus (M-MuLV) was found to render the virus temperature-sensitive for replication. A provirus containing a 12-bp insertion at the boundary between the reverse transcriptase (RT) and integrase (IN) domains induced the formation of mutant virions containing a partially processed RT-IN fusion protein. Some proteolytic processing to form mature RT and IN was observed at 32 degrees, but only aberrantly processed proteins were detected at 39 degrees. The uncleaved precursor was found to exhibit DNA polymerase activity, even though it could not support replication of the virus in vivo at 39 degrees.

Coactivators for a proline-rich activator purified from the multisubunit human TFIID complex.

The mechanisms of transcriptional activation directed by sequence-specific regulators is central to understanding gene regulation. Here, we report the isolation of coactivators responsible for mediating transcriptional activation by Gal4-Pro, a hybrid regulator containing the proline-rich activation domain of human CTF/NFI. Chromatographic studies indicate that endogenous human TFIID consists of a multisubunit complex containing the TATA-binding protein (TBP), coactivators, and other associated factors. A fraction containing the coactivator activity was separated from the endogenous TBP after disrupting the tightly associated complex with urea. The urea-purified TBP was active for basal level transcription but no longer could support activation by Gal4-Pro. However, when the two separated components were added together, activated levels of transcription were restored in the presence of Gal4-Pro. Immunoaffinity purification of the TFIID complex identifies several polypeptides specifically associated with the endogenous TBP, some or all of which function as coactivators when reconstituted with Gal4-Pro. The isolated coactivators also mediate activation by a chimeric glutamine-rich activator derived from Sp1 but not the Gal4-VP16 activator, suggesting distinct factor requirements for different types of transcriptional regulators.

Genetic dissection of hTAF(II)130 defines a hydrophobic surface required for interaction with glutamine-rich activators.

The general transcription factor TFIID is a multiprotein complex consisting of the TATA box-binding protein and multiple TATA box-binding protein-associated factors (TAF(II)s). The central domain of human TAF(II)130 contains four glutamine-rich regions Q1-Q4 that interact with transcriptional activators such as Sp1 and CREB and mediate activation. We screened in yeast random point mutations introduced into Q1-Q4 against the Sp1 activation domain and obtained a distinct set of hTAF(II)130s with alterations in TAF(II)-activator interaction. Here we characterize functionally an hTAF(II)130 mutant containing a phenylalanine to serine change at position 311 (F311S) that is compromised in its ability to associate with Sp1B and CREB-N activation domains. Substitution of phenylalanine with tyrosine but not with isoleucine or tryptophan also reduced hTAF(II)130 interaction, suggesting that the hydrophobic character rather than the specific amino acid at this position is a key determinant of interaction. Deletion of nine amino acids (Delta9) surrounding Phe(311) abolished the interaction of hTAF(II)130 with Sp1. Overexpression of hTAF(II)130Q1/Q2 and Q1-Q4 strongly inhibited Sp1-dependent transcriptional enhancement in transient transfection assays, whereas expression of either F311S or Delta9 only partially suppressed Sp1-mediated activation. Thus, a short hydrophobic sequence motif encompassing Phe(311) in hTAF(II)130 represents a critical surface with which Sp1B interacts to activate transcription.

Purification and characterization of murine retroviral reverse transcriptase expressed in Escherichia coli.

Expression of a region of the Moloney murine leukemia virus (M-MuLV) pol gene in Escherichia coli resulted in the synthesis of reverse transcriptase activity which could be detected in crude extracts. Construction of deletions at the 3' terminus of this gene resulted in a 4-fold increase in the level of the reverse transcriptase activity in the soluble fraction of crude lysates and yielded the high level production of a stable protein species of Mr = 71,000. Purification of this protein by column chromatography on DEAE-cellulose, phosphocellulose, polyribocytidylic acid-agarose, and hydroxylapatite indicated that it was a multifunctional enzyme containing RNase H and reverse transcriptase activity. The Mr = 71,000 species had a sedimentation coefficient of 4.65 S by glycerol gradient centrifugation, indicating that the enzyme was a monomer. Using poly(A)+ mRNAs primed with oligo(dT), the enzyme synthesized double-stranded DNA copies between 1.3 and 9.9 kilobases in length. Synthesis of long cDNA required 8 mM Mg2+, 4 mM Mn2+, 2 mM dNTPs, and saturating levels of enzyme. Actinomycin D efficiently limited the enzyme to the first strand synthesis. Additional characteristics of the fusion protein are described.

Expression of enzymatically active reverse transcriptase in Escherichia coli.

Reverse transcriptase of murine retroviruses is a monomeric protein of approximately 80,000 daltons, which is encoded by the central portion of the viral pol gene. To prepare large quantities of the enzyme, we have constructed gene fusions between the trpE gene and portions of the pol gene of Moloney murine leukemia virus. The inserted pol gene sequences include the entire coding region for the mature enzyme and various amounts of additional coding sequences. Many of these constructs express high levels of reverse transcriptase activity even though the NH2 and COOH termini of the protein product only approximate the correct termini of the authentic protein.

The evolution and complexity of the genes encoding the cytoskeletal proteins of human epidermal cells.

In order to explore the differential expression and evolutionary conservation of the genes encoding the cytoskeletal proteins for human epidermal cells, we have constructed a library of bacterial plasmids containing inserts of double-stranded cDNAs complementary to the mRNAs of cultured human epidermal cells. Cloned hybrid plasmids containing 45-95% of the sequences present in keratin, actin, and tubulin mRNAs were isolated and characterized. To identify the cDNAs encoding the four major keratins of human epidermal cells, the clones were initially screened for their ability to hybridize strongly with 32P-labeled cDNA prepared from unfractionated epidermal mRNA (about 30% keratin mRNA). Strongly hybridizing clones were further characterized by positive hybrid selection. Two distinct classes of clones were identified: One class hybridized specifically to the 56 and 58kd keratin mRNAs and one class hybridized specifically to the 46 and 50kd keratin mRNAs. Each class is encoded by a separate multigene family of about 10 genes. The two classes of sequences are conserved throughout vertebrate evolution, indicating the functional importance of each class in filament assembly. Clones containing human cDNA sequences encoding a cytoplasmic actin and alpha-tubulin were selected by hybridization screening using 32P-labeled cloned cDNAs for the mRNAs of beta-actin and alpha-tubulin of embryonic chick brain. The identity of these clones was established by positive hybrid selection and by DNA sequence analysis. Similar to the keratins, the actins and tubulins are also encoded by multigene families which are highly evolutionarily conserved. The availability of cloned cDNAs specific for each of three types of epithelial cytoskeletal proteins allows us to investigate the coordinate expression of their mRNAs during terminal differentiation in human epidermis.

Expression of reverse transcriptase activity of human T-lymphotropic virus type III (HTLV-III/LAV) in Escherichia coli.

The pol gene from a biologically active clone of the human T-cell lymphotropic virus type III provirus was inserted into a bacterial expression vector. The resulting gene fusion induced the formation of active reverse transcriptase that could be readily detected in extracts of bacterial cells. The activity exhibited the template and divalent cation requirements of the authentic enzyme. These constructs will be useful for safe and rapid analysis of potential inhibitors of this important enzyme.