Purification of nuclear factor I by DNA recognition site affinity chromatography

Purification of a novel factor which binds to the mouse alpha 2 (I) collagen promoter

We have identified and purified a DNA binding protein which specifically binds to a segment of the mouse alpha 2 (I) collagen promoter between -420 and -399 bp upstream of the start of transcription. Purification included heparin-agarose and sequence-specific DNA-affinity chromatography, followed by SDS-PAGE and renaturation of the DNA binding activity after elution from SDS-polyacrylamide gel. The DNA binding activity resides in two species of 42 kDa and 40 kDa, respectively. The levels of DNA binding activity of this factor, which has been tentatively designated as ColF1, are considerably higher in nuclear extracts of NIH-3T3 fibroblasts than in nuclear extracts from epidermal cells, lymphoid cells and transformed NIH-3T3 fibroblasts.

DNase activity in murine lenses: implications for cataractogenesis

In murine lens extracts a Mg(2+)-dependent DNase activity was found and characterized with respect to its ionic conditions. The lenticular DNase can be clearly distinguished from DNaseII. Only a moderate DNase activity is detectable in intact nuclei of lens cells from 1-day-old mice, but DNase is obviously present with high activity in lens cell nuclei from 7-day-old mice. During this time, when murine eyes are not yet open, and the fiber cell nuclei including the nuclear membrane remain to be completely digested, only weak activity can be detected in cytosolic lens extracts. In three allelic dominant mice mutants exhibiting hereditary cataracts the DNase activity is inhibited. The decrease of DNase activity follows the same directionality (Cat-2ns > Cat-2no > Cat-2t) as the decrease in the relative content of water soluble lens proteins, which might be used as a rough indicator for the severity of cataractogenesis. Both trends are highly significant (P < 0.0001).

Techniques for cloning cDNAs encoding interactive transcriptional regulatory proteins

Several approaches aimed at detecting and cloning interactive transcriptional regulatory proteins have been presented. All of the techniques can effectively identify specific interactions between two transcription proteins. However, interaction cloning and the two hybrid system have the added advantage of yielding a cDNA expression clone directly. The other methods, EMSA-mediated cloning, co-immunoprecipitation, oligonucleotide/PCR-facilitated cloning, Southwestern, and Farwestern, require additional manipulations to obtain a cDNA clone. Clearly, the interactive cloning system of choice will depend on the proteins under investigation.

Sequence-specific DNA affinity chromatography: application of a group-specific adsorbent for the isolation of restriction endonucleases

The use of sequence-specific DNA affinity adsorbents for the isolation of restriction endonucleases EcoRI and SphI to near homogeneity has been reported. However, the high cost of these adsorbents is a limiting factor for their wider application. This paper reports the application of sequence-specific DNA affinity ligands containing recognition sequences for 34 restriction endonucleases as group-specific ligands in the isolation of restriction endonucleases. Crude samples of six restriction endonucleases, namely BshFI, BamHI, SmaI, SacII, PvuII and SalI, were shown to bind to these adsorbents and could be eluted at different KCl concentrations. High purification factors and recoveries were obtained. Restriction endonuclease BshFI, an isoschizomer of HaeIII, from the microorganism Bacillus sphaericus was purified to near homogeneity employing a two-step procedure which involves DNA-cellulose chromatography and oligonucleotide-ligand affinity chromatography. The enzyme exists as a monomer with an apparent relative molecular mass of 34,000 as determined by both sodium dodecyl sulphate-polyacrylamide gel electrophoresis and size-exclusion chromatography.

Does histone H1 bind specifically to the nuclear factor I recognition sequence?

The issue of whether histone H1 possesses specificity of binding to certain nucleotide sequences in DNA is of fundamental importance to the suggested role of the linker histone in the regulation of gene transcription. The purpose of the present study was to reinvestigate the specificity of binding of histone H1 to the putative nuclear factor I (NFI) recognition sequence suggested by a previous report in the literature. The interaction of purified mouse liver histone H1 with a synthetic oligonucleotide representing the natural NFI binding site from the adenovirus 2 origin of replication cloned in pBR322 has been studied by filter binding and a solid-phase procedure performed on nitrocellulose filter-immobilized protein dots. No indication of specific interactions of the lysine-rich histone H1 with the NFI recognition sequence was obtained.

Downstream activating sequence within the coding region of a yeast gene: specific binding in vitro of RAP1 protein

Using a gel retardation assay, a protein factor that specifically interacts with a 33 bp intragenic sequence of the highly expressed and glucose-inducible SRP1 gene of Saccharomyces cerevisiae has been detected. This binding site is located in a transcribed region and within the open reading frame (positions +710 to +743 relative to the first base of the initiation codon). A mutant strain carrying a deletion of this binding site showed a dramatic decrease in steady-state levels of SRP1 transcripts. This decline is not the result of a decrease in mRNA stability, since expression of hybrid genes in which the SRP1 promoter was replaced by the heterologous CYC1 promoter was not affected by the binding site deletion. These findings suggest that the 33 bp sequence contains a cis-acting downstream activating element which is involved in the transcriptional activation of the SRP1 promoter. Sequence comparisons showed similarities between a site located within the 33 bp sequence and the high-affinity consensus binding site of the RAP1/GRF1 (also named TUF) factor and methylation interference experiments confirmed that this site was involved in the protein-DNA interaction. Both the results of competition experiments with upstream activating sequences of ribosomal protein genes (UASrpg), which are targets for RAP1 binding, and determination of the apparent molecular weight of the affinity-purified DNA-binding protein indicated that RAP1 factor recognized the SRP1 33 bp element. The 33 bp sequence was found to be unable to provide UAS activity when placed upstream of the TATA box and transcription start site.

Characterization of a high affinity octamer transcription factor binding site in the human lipoprotein lipase promoter

A high affinity octamer transcription factor (OTF-1) binding site has been identified and characterized at position--46 base pairs (bp) in the proximal human lipoprotein lipase (LPL) promoter. The affinity of the LPL OTF-1 binding site was approximately 15-fold greater than a consensus octamer sequence, ATTTGCAT, present at position--66 bp in the mouse Vk T1 promoter, and approximately 5-fold greater than the OTF-1 site present at position--49 bp in the human histone H2B promoter. Diethylpyrocarbonate interference assays have identified both 5' and 3' adenine nucleotides, which flank the core LPL ATTTGCAT sequence and interfere with OTF-1 binding when chemically modified. Introduction of mutations in either 5' or 3' flanking AT-rich sequences lowered the affinity of OTF-1 binding below the level observed with the wild-type LPL octamer oligomer. A double mutation in both flanking AT regions, however, greatly reduced the affinity of this site to levels similar to that observed with the mouse Vk T1 OTF site. An additional nuclear transcription factor, NF-Y, has been shown to bind to a functional CCAAT box motif located at -65 bp in the LPL promoter using specific alpha-NF-Y antisera. The observation of high affinity OTF-1 and NF-Y binding sites in a region of the proximal LPL promoter which is necessary for high levels of LPL transcription suggests that these sites with their associated proteins play important functional roles in the transcriptional activation of the LPL promoter during adipocyte differentiation.

Cloning and 5'-flanking sequence of a rat cholesterol 7 alpha-hydroxylase gene

A cholesterol 7 alpha-hydroxylase gene containing 8 kb of the 5'-flanking region and 5 kb of the transcription region which covers exons 1 to 5 was isolated from a rat genomic library. The 2015 bp nucleotide sequence 5'-upstream from the start codon was determined. This promotor region contains many liver-enriched or -specific elements (TGT3, HNF/LF-B1), putative hormone responsive elements (TRE, GRE, RRE or RARE) and ubiquitous transcription factor binding sites (NF-1, OCT-1). In addition, 21 CA repeats which have potential to form the Z-DNA structure were found in this region. These putative regulatory elements and repetitive motifs may play roles in the regulation of cholesterol 7 alpha-hydroxylase gene in the liver. The sequence identity of the rat gene to the human gene in this region is low. Only liver-enriched elements are conserved in the cholesterol 7 alpha-hydroxylase genes.

Interaction of the human polyomavirus, JCV, with human B-lymphocytes

The human polyomavirus, JCV, is the causative agent of the central nervous system demyelinating disease progressive multifocal leukoencephalopathy (PML). The principal target of JCV infection in the central nervous system (CNS) is the myelinating oligodendrocyte. However, the site of JCV multiplication outside of the CNS and the mechanism by which virus gains access to the brain are not known. Recently, JCV infected B-lymphocytes have been demonstrated in PML patients in several lymphoid organs, in circulating peripheral lymphocytes, and in brain, suggesting a possible role of B-lymphocytes in the dissemination of virus to the brain. The experiments reported here were undertaken to understand more about the interactions of JCV with human B-lymphocytes. The data show that JCV is able to multiply in either Epstein-Barr virus transformed (EBV) or EBV negative human B cell lines resulting in production of infectious, progeny virions. In addition, nuclear proteins extracted from these B cells bind to similar nucleotides within the JCV regulatory region that are bound by nuclear proteins extracted from human fetal glial cells, the most susceptible host and principal target cell for JCV infection in vitro. It is not known, however, whether these DNA binding proteins from susceptible B cells and glial cells are similar.

Insulin-producing cells contain a cell-specific repressor activity that functions through multiple E-box sequences

The cis-acting DNA element known as the E box (consensus sequence CAxxTG) plays an important role in the transcription of a number of cell-specifically expressed genes. The rat insulin I gene, for example, contains two such sequences (IEB1 and IEB2) that are recognized specifically by a characteristic beta cell nuclear factor insulin enhancer factor 1 (IEF1). To define the role of these elements better, we tested for cooperative interactions between the IEB sequences. Transfection experiments were performed with a series of plasmids containing the elements separated by different distances. Transcriptional activity in vivo is only modestly affected (less than two-fold) when the distances between the IEB elements are changed by a half-integral number of double-helical turns. Surprisingly, plasmids bearing four and six copies of the IEB motif showed sharply reduced activity as compared to those with two copies. In vitro DNA-binding studies revealed that this effect was not due to inability of IEF1 to bind to multiple copies of IEB. Moreover, multiple copies of the IEB sequence were able to inhibit activity of a cis-linked Moloney sarcoma virus (MSV) or insulin enhancer upon transfection to beta cells but not to other cell types. The above data are consistent with the view that beta cells contain a cell-specific repressor molecule capable of binding to multiple copies of IEB and thereby inhibiting transcription. This interpretation was further strengthened by in vivo competition and trans-activation experiments. The beta-cell-specific repressor activity identified by these studies may play an important role in mediating gene expression in insulin-producing cells, perhaps by regulating the access of helix-loop-helix transcription factors to E-box sequence elements.

Transcription factor loading on the MMTV promoter: a bimodal mechanism for promoter activation

The mouse mammary tumor virus (MMTV) promoter attains a phased array of six nucleosomes when introduced into rodent cells. This architecture excludes nuclear factor 1/CCAAT transcription factor (NF1/CTF) from the promoter before glucocorticoid treatment and hormone-dependent access of nucleolytic agents to promoter DNA. In contrast, when the promoter was transiently introduced into cells, NF1/CTF was bound constitutively and nucleolytic attack was hormone-independent. Thus, induction at this promoter was a bimodal process involving receptor-dependent remodeling of chromatin that allows NF1/CTF loading and direct receptor-mediated recruitment of additional transcription factors.

Interaction of a nuclear factor 1-like protein with a cAMP response element-binding protein in rat liver

1. The existence of both cAMP-responsive element binding factor and a nuclear factor 1-like (NF-1-like) protein in nuclear extracts from liver of cAMP-treated rat has been revealed. 2. Binding of these proteins to a DNA fragment containing both elements was cooperative, and 50% binding was achieved with considerably less protein than with a fragment bearing either element alone. 3. Cleavage of the fragment between the two elements abolished the apparent cooperative interaction. 4. Southwestern blot analysis showed that the NF-1-like protein has a molecular weight in the 28-30-kDa range. 5. The NF-1-like binding activity was very stable.

Characterization of a cofactor that regulates dimerization of a mammalian homeodomain protein

Dimerization among transcription factors has become a recurrent theme in the regulation of eukaryotic gene expression. Hepatocyte nuclear factor-1 alpha (HNF-1 alpha) is a homeodomain-containing protein that functions as a dimer. A dimerization cofactor of HNF-1 alpha (DCoH) was identified that displayed a restricted tissue distribution and did not bind to DNA, but, rather, selectively stabilized HNF-1 alpha dimers. The formation of a stable tetrameric DCoH-HNF-1 alpha complex, which required the dimerization domain of HNF-1 alpha, did not change the DNA binding characteristics of HNF-1 alpha, but enhanced its transcriptional activity. However, DCoH did not confer transcriptional activation to the GAL4 DNA binding domain. These results indicate that DCoH regulates formation of transcriptionally active tetrameric complexes and may contribute to the developmental specificity of the complex.

Redundant elements in the adenovirus type 5 inverted terminal repeat promote bidirectional transcription in vitro and are important for virus growth in vivo

The adenovirus inverted terminal repeat (ITR) contains a number of cis-acting elements that are involved in the initiation of viral DNA replication, as well as multiple binding motifs for the cellular transcription factors SP1 and ATF. In this study, we utilized a Hela cell transcription extract to demonstrate that the adenovirus type 5 ITR promotes bidirectional transcription in vitro. Primer extension analyses demonstrated that the ITR directed transcription at initiation sites both within the terminal repeat and at fixed distances outside of the ITR. The ITR also strongly stimulated transcription at the early region 1A (E1A) initiation site when it was situated immediately upstream of the E1A TATA box region. Deletion and point mutational analyses demonstrated that two distinct cis-acting elements were involved in these ITR-dependent transcriptional activities in vitro. Cellular transcription factors SP1 and ATF were previously shown to bind to these two regions. Analysis of viral mutants in vivo demonstrated that the NFIII/OCT-1 binding site and a conserved ATF motif were important for efficient viral growth. Regulatory elements in the ITR flanking region were found to functionally substitute for these sites.

Sequence-specific DNA affinity chromatography: application to the purification of EcoRI and SphI

Several rapid and effective methods have been described to obtain restriction endonucleases suitable for commercial exploitation. However, lengthy and laborious protocols have been necessary to obtain homogeneous enzymes. We now report the use of sequence-specific DNA affinity chromatography to purify restriction endonucleases to near homogeneity. Restriction endonucleases EcoRI and SphI from the microorganisms Escherichia coli RY 13 and Streptomyces phaeochromogenes, respectively, were purified to near homogeneity employing a two-step procedure which involves DNA-cellulose chromatography and oligonucleotide-ligand affinity chromatography.

Replication of an adenovirus type 34 mutant DNA containing tandem reiterations of the inverted terminal repeat

A mutant of human adenovirus type 34 (Ad34) has been isolated which contains DNA molecules with tandem reiterations of from two to eight copies of a 131-bp sequence within the right-sided inverted terminal repetition. Terminal heterogeneity was not eliminated by repeated plaque purifications indicating that the population of DNA molecules with various numbers of reiterations could rapidly evolve from the DNA of a single virus particle. These enlarged DNA molecules were capable of replication both in vivo and in vitro. The nucleotide sequence of the mutant Ad34 inverted terminal repetitions contained most of the essential features of the Ad origin of DNA replication. These features include the ATAATATACC sequence which is present between the highly conserved bases 9-18 in all human adenoviruses, as well as the consensus sequences for the binding of nuclear factor I and nuclear factor III. However, the reiterated sequences lacked a dG appropriately placed on the template strand to serve as a potential site for internal initiation. It appears that the rapid amplification of two to eight copies of the reiterated terminal sequences does not arise from internal initiation during replication but probably from homologous recombination.

Affinity chromatographic purification of a protein which binds specifically to the yeast leucine tRNA gene

A crude cell extract from yeast Saccharomyces cerevisae was fractionated by affinity chromatography using the leucine tRNA gene as the recognition site. This approach enables the rapid purification of a protein, which retained its full DNA binding capacity during the enrichment procedure. The active fraction contains two major polypeptides of 140 and 170 kDa and a minor component of 100 kDa. The 170-kDa component does not bind to the DNA. The likelihood that the DNA binding protein is one of the components of transcription factor tau is discussed.

Mutational analysis of single-stranded DNA templates active in the in vitro initiation assay for adenovirus DNA replication

Three distinct domains, A, the minimal origin, as well as B and C, the binding sites for the host nuclear factors, are required for efficient initiation of adenovirus (Ad) DNA replication at the termini. The initiation reaction was examined using partially purified nuclear extracts and various single-stranded oligomers as DNA templates. We observed that single-stranded oligomers containing Ad2 minimal origin (Ori) sequences (bp 1-18) from the I-strand of the Ad2 genome supported preterminal protein-dCMP complex formation in vitro. Using oligomers containing point mutations in the Ad2 minimal Ori sequence, six positions were identified as important to the function of the Ad2 minimal Ori sequence. Point mutations at position 7, 8, or 11 virtually abolished the ability of the oligomer to support the initiation reaction. Point mutations at position 4, 9, or 17 were found to decrease the ability of the oligomers to support the initiation reaction to 33, 67, and 58% of control, respectively. An oligomer complementary to the I-strand of the Ad2 minimal Ori was found to block initiation on minimal Ori template. A number of randomly selected nonspecific oligomers did not, in general, serve as templates for initiation with the exception of two oligomers, one of which was found to be about threefold more active than the control minimal Ori template. The biological significance of the in vitro initiation of Ad2 DNA replication on single-stranded DNA templates is discussed.

NRF-1: a trans-activator of nuclear-encoded respiratory genes in animal cells

The assembly of the respiratory apparatus requires the coordinate expression of a large number of genes from both nuclear and mitochondrial genetic systems. In vertebrate organisms, the molecular mechanisms integrating the activities of these distinct genomic compartments in response to tissue demands for respiratory energy remain unknown. A potential inroad to this problem came with the discovery of nuclear respiratory factor 1 (NRF-1), a novel transcriptional activator defined by mutational and DNA binding analysis of the somatic cytochrome c promoter. Functional NRF-1 sites are now observed in several other recently isolated nuclear genes whose products function in the mitochondria. Among these are genes encoding subunits of the cytochrome c oxidase (subunit VIc) and reductase (ubiquinone-binding protein) complexes. In addition, a functional NRF-1 site resides in the MRP RNA gene encoding the RNA moiety of a ribonucleoprotein endonuclease involved in mitochondrial DNA replication. Synthetic oligomers of these sites competitively displace NRF-1 binding to the cytochrome c promoter. NRF-1-binding activities for each site also have the same thermal lability, copurify chromatographically, and make similar guanosine nucleotide contacts within each recognition sequence. Moreover, NRF-1 recognition in vitro correlates with the ability of each site to stimulate expression in vivo from a truncated cytochrome c promoter. The presence of NRF-1-binding sites in nuclear genes encoding structural components of the mammalian electron transport chain, as well as the mitochondrial DNA replication machinery, suggests a mechanism for coordination of nuclear and mitochondrial genetic systems through the concerted modulation of nuclear genes.

Promoter evolution in BK virus: functional elements are created at sequence junctions

The archetypal strain of BK virus directed very little early gene expression compared with rearranged laboratory strains of the virus. One laboratory strain that was analyzed in detail contained newly created AP-1 binding enhancer modules spanning the junction between adjacent sequence repeats. Introduction of these sequences into the archetype activated the previously quiescent early promoter.

Affinity purification of specific DNA fragments using a lac repressor fusion protein

A new method for purification of specific DNA sequences using a solid phase technique has been developed based on a fusion between the Escherichia coli lac repressor gene (lacI) and the staphylococcal protein A gene (spa). The fusion protein, expressed in Escherichia coli, is active both in vivo and in vitro with respect to its three functional activities (DNA binding, IPTG induction, and IgG binding). The recombinant protein can be immobilized in a one-step procedure with high yield and purity using the specific interaction between protein A and the Fc-part of immunoglobulin G. The immobilized repressor can thereafter be used for affinity purification of specific DNA fragments containing the lac operator (lacO) sequence.

Interactions between nuclear factors and the hepatitis B virus enhancer

We have previously established that the tissue-specific activity of the hepatitis B virus (HBV) enhancer is mediated by trans-acting cellular factors. Here we have studied in vitro the interactions between the HBV enhancer DNA and cellular factors present in nuclear extracts from both liver and nonliver cell types. The results presented in this study imply the involvement of several distinct, ubiquitous, and liver-specific cellular factors with the HBV enhancer. Sequence analysis of the binding sites for these proteins on HBV DNA showed homologies to sequence motifs known to bind other previously characterized and purified transcription factors including CAAT/enhancer-binding protein. Thus, all of these binding sites may function in concert to activate liver-specific transcription of HBV genes from their respective promoters.

Nuclear factor I represses the reverse-oriented transcription from the adenovirus type 5 DNA terminus

The promoter activity of a cloned inverted terminal repeat (ITR) of human adenovirus (Ad) type 5 was found to be oriented in the opposite direction with respect to that of DNA replication in a cell-free transcription system using HeLa nuclear extracts. The major transcript was initiated outside the Ad sequence about 30 nucleotides downstream from the putative TATA-box located between nucleotide positions 9-18 of Ad 5 left terminus. Competitive transcription experiments using double-stranded oligonucleotides and isolated nuclear factor I revealed that nuclear factor I and its cognate binding site located upstream of the putative TATA-box are involved in negative regulation of the transcription from ITR promoter.

Transcriptional activator nuclear factor I stimulates the replication of SV40 minichromosomes in vivo and in vitro

SV40 DNA replication in vivo is greatly stimulated by cis-acting transcriptional elements. We studied a model viral chromosome containing a single binding site for the cellular transcriptional activator, nuclear factor I (NF-I/CTF), located adjacent to the replication origin. The presence of the NF-I recognition site increased replication efficiency over 20-fold in vivo. Purified NF-I had little effect on the replication efficiency in the standard SV40 cell-free system when the template was introduced as naked DNA. However, NF-I specifically prevented the repression of DNA replication that occurred when the template was preassembled into chromatin. Our data support a model in which the binding of a transcriptional activator perturbs the local distribution of nucleosomes, thereby increasing the accessibility of the origin region.

A transcription factor, TFIS, interacts with both the promoter and enhancer of the Xenopus rRNA genes

An activity that binds sequence specifically to the enhancer of the Xenopus laevis rRNA genes has been highly purified. This activity stimulates transcription of coinjected rRNA templates in Xenopus oocytes and has been named TFIS, as it binds to the enhancer sequences within the intergenic spacer. In addition to its enhancer binding activity, TFIS binds to the promoter of the Xenopus rRNA genes, as predicted by models for enhancer action. DNase I footprinting on promoter mutants suggests that there are three TFIS-binding sites between -70 and -240 and that TFIS binding is unusually tolerant of mutations. The large region of protein-DNA interaction and the occurrence of DNase I enhancements at integral multiples of the helical repeat are consistent with the promoter and enhancer DNA wrapping around TFIS.

NBP, a protein that specifically binds an enhancer of immunoglobulin gene rearrangement: purification and characterization

Immunoglobulin and T-cell receptor (TCR) genes are encoded in discrete germ line DNA segments that are joined by site-specific recombination during lymphocyte development. These DNA rearrangements are mediated by conserved heptamer and nonamer DNA sequence elements that lie near the sites of recombination. In this paper we show that the nonamer element coincides with the recognition site for a specific DNA-binding protein: mutations within the nonamer sequence, but not outside of it, decrease affinity for the binding protein by 300- to 1000-fold. Deletion of the binding site for the protein results in at least a 50-fold decrease in recombination frequency in vivo. By a combination of conventional and recognition site affinity chromatography, we have achieved greater than 20,000-fold purification of the protein from calf thymus, with an overall yield of 22%. The purified protein, which we now call nonamer-binding protein (NBP), has an apparent molecular weight of 63,000 and a frictional ratio of 1.27, suggesting that it exists as a globular monomer in 0.5 M NaCl. Our observations suggest that NBP is a component of the recombinational apparatus.

Rapid purification of the estrogen receptor by sequence-specific DNA affinity chromatography

Rapid purification of calf uterine estrogen receptor (ER) to near homogeneity has been accomplished by use of sequence-specific DNA affinity resin. Very high selectivity for the estrogen receptor is achieved through the use of DNA-Sepharose containing eight tandem copies of a consensus estrogen response element (ERE) DNA sequence. The highly purified ER prepared by this new scheme may be labeled economically with ligands of high specific activity. This purification scheme selects for intact receptors retaining function in both estrogen-binding and DNA-binding domains. Purified receptor has an electrophoretic mobility consistent with a molecular weight of 68,000, sediments as a 5S species on sucrose gradients, and reacts with antibody specific to the human estrogen receptor.