High-affinity binding site for a specific nuclear protein in the human IgM gene

A cellular DNA-binding protein that activates eukaryotic transcription and DNA replication

Transcription factor CTF, which is responsible for selective recognition of eukaryotic promoters that contain the sequence CCAAT, was purified to apparent homogeneity by sequence-specific DNA affinity chromatography. Binding sites for CTF in the human Ha-ras and alpha-globin promoters were highly homologous to sequences recognized by nuclear factor I (NF-I), a cellular DNA-binding protein that is required for the initiation of adenovirus DNA replication in vitro. To determine the relationship between CTF and NF-I, we compared the biochemical properties of these two proteins. CTF and NF-I were found to be indistinguishable in polypeptide composition, DNA-binding properties, immunological cross-reactivity, and in vitro stimulation of DNA replication and transcription initiation. We conclude that CTF/NF-I can serve both as a transcription selectivity factor for RNA polymerase II and as an initiation factor for adenovirus DNA replication.

Multiple nuclear proteins bind upstream sequences in the promotor region of a T-cell receptor beta-chain variable-region gene: evidence for tissue specificity

DNA-nuclear protein binding interactions were examined in the promoter region of a representative T-cell receptor Ti beta-chain variable-region gene by means of electrophoretic mobility-shift and DNase I-protection analysis. Within 175 bases upstream of the transcription initiation site, four protected regions ("footprints") were identified on the coding strand, at nucleotides -46 to -68 (I), -72 to -92 (II), -113 to -134 (III), and -136 to -175 (IV). Nuclear proteins (0.6 M NaCl fraction from a heparin-Sepharose column chromatography of nuclear extracts) of a variety of cell types produced footprints I, III, and IV and a fifth footprint (beyond nucleotide -200). In contrast, footprint II was produced only by T-cell extracts, although nuclear extracts of a transformed B-lymphoblastoid line produced a partial footprint in this region. Furthermore, footprint analysis of the noncoding strand showed that a continuous region of protection corresponding to the entire region of footprints I and II was generated, along with a DNase I-hypersensitive site, by nuclear proteins derived from T cells but not other cell types. Footprint I has the sequence structure of many well-defined protein-DNA binding sites. Nucleotide sequences in the region of footprint II bore no homology to known sequences, whereas those in the areas of footprints III and IV were similar to motifs within immunoglobulin and other enhancers. These findings may have implications for the tissue specificity of human Ti beta-chain gene transcription.

Human immunoglobulin kappa gene enhancer: chromatin structure analysis at high resolution

The murine immunoglobulin kappa gene enhancer has previously been found to coincide with a region of altered chromatin structure reflected in a DNase I hypersensitivity site detectable on Southern blots of B-cell DNA. We examined the chromatin structure of the homologous region of human DNA using the high-resolution electroblotting method originally developed for genomic sequence analysis by G. Church and W. Gilbert (Proc. Natl. Acad. Sci. USA 81:1991-1995, 1984). Analysis of DNA isolated from cells treated in vivo with dimethyl sulfate revealed two B-cell-specific sites of enhanced guanine methylation. Both sites are located within perfect inverted repeats theoretically capable of forming cruciform structures; one of these repeats overlaps an enhancer core sequence. No enhancement or protection of guanine methylation was observed within sequences similar to sites of altered methylation previously described in the immunoglobulin heavy-chain enhancer. Treatment of isolated nuclei with DNase I or a variety of restriction endonucleases defined a B-cell-specific approximately 0.25-kilobase region of enhanced nuclease susceptibility similar to that observed in the murine kappa enhancer. The 130-base-pair DNA segment that shows high sequence conservation between human, mouse, and rabbit DNAs lies at the 5' end of the nuclease-susceptible region.

Analysis of nuclear factor I binding to DNA using degenerate oligonucleotides

Nuclear factor I (NFI) binds tightly to DNA containing the consensus sequence TGG(N)6-7GCCAA. To study the role of the spacing between the TGG and GCCAA motifs, oligonucleotides homologous to the NFI binding site FIB-2 were synthesized and used for binding assays in vitro. The wild-type site (FIB-2.6) has a 6bp spacer region and binds tightly to NFI. When the size of this spacer was altered by +/- 1 or 2bp the binding to NFI was abolished. To further assess the role of the spacer and bases flanking the motifs, two oligonucleotide libraries were synthesized. Each member of these libraries had intact TGG and GCCAA motifs, but the sequence of the spacer and the 3bp next to each motif was degenerate. The library with a 6bp spacer bound to NFI to 40-50% the level of FIB-2.6. The library with a 7bp spacer bound to NFI to only 4% the level of FIB-2.6 and some of this binding was weaker than that of FIB-2.6 DNA. This novel use of degenerate DNA libraries has shown that: 1) the structural requirements for FIB sites with a 7bp spacer are more stringent than for sites with a 6bp spacer and 2) a limited number of DNA structural features can prevent the binding of NFI to sites with intact motifs and a 6bp spacer region.

Characterisation of chicken erythroid nuclear proteins which bind to the nuclease hypersensitive regions upstream of the beta A- and beta H-globin genes

Chicken erythrocyte sequence-specific nuclear DNA-binding proteins, which bind to the 5'-flanking DNAseI hypersensitive sites of the erythrocyte chromosomal beta A- and beta H-globin genes, have been fractionated by HPLC gel filtration. Three beta A-globin gene DNA binding activities (to sites A, B and B' (10-12)) were separated. The erythroid precursor cell line HD3 has beta A-globin gene sites B and B' binding activities, but binding to site A is detected only after the HD3 cells are induced to differentiate. The fractionated protein binds to a redefined site B', which contains at its center the globin CACCC consensus sequence. The chromosomal beta H-globin gene has two 5'-flanking DNAseI hypersensitive sites which bracket two sequences (H and H') bound by erythrocyte and HD3 nuclear protein in vitro. The beta H- and beta A-globin gene binding sites (H and B) contain variants of the sequences bound by Nuclear Factor 1 and the TGGCA-binding protein, and their protein binding activity(ies) co-purify after HPLC gel filtration.

MDBK nuclear factor-binding site of various serotypes of adenovirus DNA

A fraction with the ability to bind the terminal fragment of equine adenovirus (EAd) DNA was prepared from MDBK cell nuclei. The fraction (MDBK nuclear factor) bound to the terminal fragment of all human and animal adenovirus DNAs examined except avian adenovirus EDS-76. However, the terminal fragments of two animal adenoviruses, EAd and bovine adenovirus type 3 (BAd3), showed higher affinity for the nuclear factor than the others. The MDBK nuclear factor-binding site determined by footprinting analysis was the sequence located between nucleotides 22 and 46 in EAd, between 36 and 53 in canine adenovirus type 2, and between 20 and 46 in BAd3, counting from the terminus. The respective binding site contained a sequence resembling the consensus sequence. The binding site of Ad4 DNA was not within the inverted terminal repetition, but was located at least 550 base pairs apart from the terminus.

Nuclear factor III, a novel sequence-specific DNA-binding protein from HeLa cells stimulating adenovirus DNA replication

Dissection and reconstitution of the adenovirus DNA replication machinery has led to the discovery of two HeLa nuclear proteins which are required in conjunction with three viral proteins. One of these, nuclear factor I (NF-I), recognizes an internal region of the origin between nucleotides 25 and 40 and by binding to one side of the helix stimulates the initiation reaction up to 30-fold. NFI-binding sites have been observed upstream of several cellular genes, such as chicken lysozyme, human IgM and human c-myc, and coincide in most cases with DNase I hypersensitive regions. Here we report the identification of a novel DNA-binding protein from HeLa nuclei, designated NF-III, that recognizes a sequence in the adenovirus origin very close to the NFI-binding site, between nucleotides 36 and 54. This sequence includes the partially conserved nucleotides TATGATAATGAG. NF-III stimulates DNA replication four- to sixfold by increasing the initiation efficiency. Potential cellular binding sites include promoter elements of the histone H2B gene, the human interferon beta gene, the human and mouse immunoglobulin VK and VH genes and the mammal/chicken/Xenopus laevis U1 and U2 small nuclear RNA genes. Furthermore, a subset of the herpes simplex virus immediate early promoter specific TAATGARAT elements is homologous with the adenovirus 2 (Ad-2) NFIII-binding site.

The DNase I sensitive domain of the chicken lysozyme gene spans 24 kb

We have determined the DNase I sensitive chromatin domain of the lysozyme gene in the hen oviduct. When nuclei were digested with DNase I, about 14 kb of upstream and 6 kb of downstream sequences in addition to the 4 kb long transcribed region were preferentially degraded. The transcription start site is located near the center of the approximately 24 kb long sensitive domain. At the 3' boundary there is a rather abrupt transition from the DNase I sensitive to the resistant chromatin configuration whereas at the 5' border this transition occurs in a gradual fashion over 6-7 kb of DNA. No obvious correlation between the boundaries of the domain and repetitive sequences could be established. DNase I-hypersensitive sites are clustered within the boundaries of the sensitive domain which seems to represent a functional unit of the gene.

High affinity binding site for nuclear factor I next to the hepatitis B virus S gene promoter

The hepatitis B virus (HBV) surface antigen (HBsAG) is encoded by the S gene under the regulation of a promoter in the pre-S1 region. The S gene promoter does not contain a 'TATA' box-like sequence, but there is a sequence resembling, in part, the late promoter of Simian virus 40 (SV40). In an attempt to study the regulation of the S gene promoter we looked for cellular proteins which bind to this region. We report here that a nuclear protein is tightly bound to the HBV genome at a position approximately 190 bases upstream from the S gene promoter. Evidence is provided to show that (a) this nuclear protein is the nuclear factor I (NF-I) that was previously found to be bound to the inverted terminal repeat of the adenovirus (Ad) DNA and to enhance Ad DNA replication in vitro and (b) this NF-I binding site is required for optimal activity of the S gene promoter.

A negative transcriptional control element located upstream of the murine c-myc gene

We have investigated the nature of regulatory sequences within the vicinity of the murine c-myc locus by analyzing the expression of myc-chloramphenicol acetyl transferase (CAT) vectors transfected into a human lymphoblastoid cell line (BJAB) and a monkey fibroblast line (COS). CAT enzymatic assays and S1 nuclease protection experiments reveal that a negative element resides 428-1188 bp 5' of the first c-myc promoter, P1. This 760-bp segment of 5'-flanking c-myc DNA dramatically inhibits CAT gene expression in the pSV2CAT vector when placed in either orientation approximately 1.7 kb 3' (and approximately 3.2 kb 5' on the circular plasmid) from the SV40 promoter region. By employing this strategy, we were unable to identify an analogous DNA segment that is closer to or within the first c-myc exon. We propose that this 5' c-myc region be termed a 'dehancer' since this negative element has the opposite properties of a transcriptional enhancer.

Purification of a cellular, double-stranded DNA-binding protein required for initiation of adenovirus DNA replication by using a rapid filter-binding assay

A rapid and quantitative nitrocellulose filter-binding assay is described for the detection of nuclear factor I, a HeLa cell sequence-specific DNA-binding protein required for the initiation of adenovirus DNA replication. In this assay, the abundant nonspecific DNA-binding activity present in unfractionated HeLa nuclear extracts was greatly reduced by preincubation of these extracts with a homopolymeric competitor DNA. Subsequently, specific DNA-binding activity was detected as the preferential retention of a labeled 48-base-pair DNA fragment containing a functional nuclear factor I binding site compared with a control DNA fragment to which nuclear factor I did not bind specifically. This specific DNA-binding activity was shown to be both quantitative and time dependent. Furthermore, the conditions of this assay allowed footprinting of nuclear factor I in unfractionated HeLa nuclear extracts and quantitative detection of the protein during purification. Using unfrozen HeLa cells and reagents known to limit endogenous proteolysis, nuclear factor I was purified to near homogeneity from HeLa nuclear extracts by a combination of standard chromatography and specific DNA affinity chromatography. Over a 400-fold purification of nuclear factor I, on the basis of the specific activity of both sequence-specific DNA binding and complementation of adenovirus DNA replication in vitro, was affected by this purification. The most highly purified fraction was greatly enriched for a polypeptide of 160 kilodaltons on silver-stained sodium dodecyl sulfate-polyacrylamide gels. Furthermore, this protein cosedimented with specific DNA-binding activity on glycerol gradients. That this fraction indeed contained nuclear factor I was demonstrated by both DNase I footprinting and its function in the initiation of adenovirus DNA replication. Finally, the stoichiometry of specific DNA binding by nuclear factor I is shown to be most consistent with 2 mol of the 160-kilodalton polypeptide binding per mol of nuclear factor I-binding site.

Transcriptional regulation of the human cytomegalovirus major immediate-early gene is associated with induction of DNase I-hypersensitive sites

Human teratocarcinoma cells were used to examine structural features associated with expression of the major immediate-early (IE) gene of human cytomegalovirus. By immunofluorescence, comparison of RNA levels, and in vitro transcription of nuclei, we showed that the major IE gene is inactive in undifferentiated but active in differentiated cells. Therefore, the block in human cytomegalovirus replication in teratocarcinoma cells appears to be at the transcriptional level, in one of the initial genes transcribed. In addition, the in vitro transcription experiments demonstrated that in permissive infections the gene was transcriptionally inactive late in infection. A comparison of the structural features of the promoter region with the active and inactive IE genes showed the presence of constitutive and inducible DNase I-hypersensitive sites. The majority of the constitutive sites existed at -175, -275, -375, -425, and -525 relative to the cap site in an area which has been shown to be capable of simian virus 40 enhancer function. In contrast, the inducible DNase I sites were located outside this region at -650, -775, -875, and -975.

The lac operator as a phenotypic label for DNA fragments cloned in Escherichia coli

To confer a detectable phenotype on any DNA fragment cloned in Escherichia coli, one can label the fragment by ligating it to the lac operator so that host cells can be identified as blue colonies on agar plates. This screening strategy is similar to that used for the pUC and M13 series of vectors, but does not require the vector to contain the lacZ gene. Instead, the presence of the lac operator on the multicopy vector results in the induction of the host cell beta-galactosidase by titrating out the repressor. This paper describes how pUC/M13 vectors or synthetic oligodeoxynucleotides can be used to supply the operator label, and shows how this method has been used to position unique restriction sites for initiating BAL 31 deletions. This approach may be particularly helpful when a given DNA fragment is to be cloned in many different constructs or is to pass through many sequential cloning steps.

Role of an RNA cleavage/poly(A) addition site in the production of membrane-bound and secreted IgM mRNA

The switch from membrane-bound to secreted IgM is accomplished by producing alternative forms of mRNA from a single mu heavy-chain gene. This process might be controlled at any of three steps--transcription termination, RNA splicing, or RNA cleavage/poly(A) addition. To distinguish between these possibilities, we have constructed a model human mu gene and observed its expression in early- and late-stage murine B cells. In each case, expression of the model gene reflects the state of development of the host cell; i.e., more of the mRNA for membrane-bound IgM is made in early B cells and more of the secreted form is made in late B cells. Using systematic deletions and analyses of RNA products of the model gene, we implicate RNA cleavage/poly(A) addition as the governing reaction. Removal of the cleavage/poly(A) signal for secreted mu mRNA by a series of BAL-31 deletions produces not only a decrease in secreted mu mRNA but also a compensatory increase in the membrane-bound form. Further, transcripts that do not terminate to the 5' side of the membrane anchor exons are found in cells producing only secreted IgM. As defined by these deletions, we establish that the RNA cleavage signal spans at least 35 bases and speculate that it forms an RNA stemloop that may be important in 3' end formation.

Putative repressor binding sites in the regions mediating transcriptional control of viral and cellular genes

In this study, the sequences of several cellular genes (c-myc, c-fos, c-sis, c-mos, and the genes for urokinase, heat shock proteins, interleukin-2 and its receptor), thought to be controlled by negative regulatory factors, were examined. As a result of this comparison, multiple (and often clustered) copies of a 12 basepair (bp) element were identified in the flanking regions of these genes. Moreover, sequences with close homology to this 12 bp element were identified in specific control regions of some DNA and RNA tumor viruses. A consensus sequence (TTG nnn TTTTTT) was derived from an analysis of 111 of these elements. These sequence homologies have yielded a coherent first hypothesis, namely that this 12 bp element is the binding site of a transcriptional repressor protein.