Three classes of mutations in the A subunit of the CCAAT-binding factor CBF delineate functional domains involved in the three-step assembly of the CBF-DNA complex

The mammalian CCAAT-binding factor CBF (also called NF-Y or CP1) consists of three subunits, CBF-A, CBF-B, and CBF-C, all of which are required for DNA binding and present in the CBF-DNA complex. In this study we first established the stoichiometries of the CBF subunits, both in the CBF molecule and in the CBF-DNA complex, and showed that one molecule of each subunit is present in the complex. To begin to understand the interactions between the CBF subunits and DNA, we performed a mutational analysis of the CBF-A subunit. This analysis identified three classes of mutations in the segment of CBF-A that is conserved in Saccharomyces cerevisiae and mammals. Analysis of the first class of mutants revealed that a major part of the conserved segment was essential for interactions with CBF-C to form a heterodimeric CBF-A/CBF-C complex. The second class of mutants identified a segment of CBF-A that is necessary for interactions between the CBF-A/CBF-C heterodimer and CBF-B to form a CBF heterotrimer. The third class defined a domain of CBF-A involved in binding the CBF heterotrimer to DNA. The second and third classes of mutants acted as dominant negative mutants inhibiting the formation of a complex between the wild-type CBF subunits and DNA. The segment of CBF-A necessary for DNA binding showed sequence homology to a segment of CBF-C. Interestingly, these sequences in CBF-A and CBF-C were also homologous to the sequences in the histone-fold motifs of histones H2B and H2A, respectively, and to the archaebacterial histone-like protein HMf-2. We discuss the functional domains of CBF-A and the properties of CBF in light of these sequence homologies and propose that an ancient histone-like motif in two CBF subunits controls the formation of a heterodimer between these subunits and the assembly of a sequence-specific DNA-protein complex.

Recombinant rat CBF-C, the third subunit of CBF/NFY, allows formation of a protein-DNA complex with CBF-A and CBF-B and with yeast HAP2 and HAP3

The CCAAT binding factor CBF is a heteromeric transcription factor, which binds to functional CCAAT motifs in many eukaryotic promoters. cDNAs for the A and B subunits of CBF (CBF-A and CBF-B) and for their yeast homologues HAP3 and HAP2 have been previously isolated, but the purified recombinant CBF-A and CBF-B together are unable to bind to CCAAT motifs in DNA. Here we report the isolation of a cDNA coding for rat CBF-C, demonstrate that recombinant CBF-C is required together with CBF-A and CBF-B to form a CBF-DNA complex, and show that CBF-C is present in this protein-DNA complex together with the other two subunits. We further show that CBF-C allows formation of a complex between the purified recombinant yeast HAP2 and HAP3 polypeptides and a CCAAT-containing DNA and is present in this complex, implying the existence of a CBF-C homologue in yeast. We show that CBF-A and CBF-C interact with each other to form a CBF-A-CBF-C complex and that CBF-B does not interact with CBF-A or CBF-C individually but that it associates with the CBF-A-CBF-C complex. Our results indicate that CBF is a unique evolutionarily conserved DNA binding protein.

Studies on transcription activation by the multimeric CCAAT-binding factor CBF

The CCAAT-binding factor CBF is a heteromeric transcription factor that specifically binds to CCAAT sequences in many eukaryotic genes. CBF consists of three subunits, CBF-A, CBF-B, and CBF-C, all three of which are necessary for DNA binding. In this study we examined the transcription activation function of CBF by two different approaches. We first used a heterologous system in which a series of deletion mutations of CBF-B, fused to the bacterial LexA DNA binding domain, were transfected into HeLa cells together with a reporter gene driven by a minimal promoter containing LexA binding sites. These experiments showed that CBF-B needed both a glutamine-rich domain and an adjacent serine/threonine-rich domain to activate the reporter gene optimally. The glutamine-rich domain by itself activated transcription only modestly. We also set up an in vitro transcription reconstituted system in which trans-activation by CBF occurred through a physiological CCAAT motif. Nuclear extracts from NIH 3T3 cells were first depleted of CBF and then complemented with recombinant CBF-B and a highly purified fraction containing native CBF-A and CBF-C. Recombinant full-length CBF-B together with CBF-A and CBF-C activated transcription of several alpha 2(I) collagen gene promoter constructs. We then tested whether in this system the glutamine- and serine/threonine-rich domains of CBF-B were needed for trans-activation by CBF. We generated a truncated form of CBF-B that was still able to bind DNA in the presence of CBF-A and CBF-C. Even in the absence of the glutamine- and serine/threonine-rich domains of CBF-B, reconstituted CBF did activate transcription, suggesting that CBF transcriptional activation can also be mediated by the other subunits of CBF or by another transcription factor present in the nuclear extracts that interacts with CBF. Taken together our results suggest a model in which CBF has the potential to activate transcription either through the glutamine- and serine/threonine-rich domains of CBF-B or through the other subunits of CBF or through another component recruited by CBF.

Studies on the structure of the mouse CBF-A gene and properties of a truncated CBF-A isoform generated from an alternatively spliced RNA

CCAAT-binding factor (CBF), a heteromeric transcription factor that binds to sequences containing a CCAAT motif, is composed of three subunits, A, B and C, which are all required for DNA binding. The mouse CBF-A gene contains seven coding exons, which span 12 kb. Evidence is also presented for an additional 5' untranslated exon. The 90-amino-acid (aa) segment of CBF-A, which shows a high degree of sequence identity with the yeast transcription factor, HAP3, is split into exons 3 and 4. An alternatively spliced RNA that lacks exon 3 was identified by polymerase chain reaction. Although removal of exon 3 interrupts the CBF-A reading frame, a potential start codon at the 3' end of exon 2 is in the same reading frame as the reading frame encoding CBF-A in exons 4 to 7. A CBF-A polypeptide of the predicted 17-kDa, size, was indeed identified after in vitro transcription and translation of the DNA complementary to RNA (cDNA) corresponding to the alternatively spliced CBF-A mRNA. In contrast to full-length CBF-A, this truncated CBFA did not bind to a DNA sequence containing the CCAAT motif in the presence of the other two components of CBF. This result indicates that the segment corresponding to the exons missing in the truncated isoform of CBF-A is essential for the binding of CBF to DNA.

Three different polypeptides are necessary for DNA binding of the mammalian heteromeric CCAAT binding factor

Full-length cDNA clones for the CBF-A and CBF-B subunits of the CCAAT binding mammalian heteromeric transcription factor (CBF) have previously been isolated from both rat and mouse. Whereas recombinant CBF-B binds to DNA after complementation with a highly purified CBF-A fraction, recombinant CBF-A was unable to bind to DNA after complementation with either purified CBF-B or recombinant CBF-B. However, when recombinant CBF-A, synthesized as a fusion protein with glutathione S-transferase was denatured together with a highly purified fraction containing CBF-A in the presence of 5.5 M guanidine hydrochloride and subsequently renatured, the recombinant CBF-A bound to DNA after complementation with CBF-B. This binding of recombinant CBF-A could not be detected if recombinant CBF-A was not mixed during the denaturation-renaturation process together with the purified fraction containing the 32-kDa CBF-A. Using a Southwestern blot we demonstrated that a polypeptide of approximately 40 kDa, present in the purified CBF-A fraction, bound to DNA after complementation with both recombinant CBF-A and CBF-B. After fractionation of the purified CBF-A preparation by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, a species of approximately 40 kDa was eluted from the gel and shown to have DNA binding activity after complementation with both recombinant CBF-A and CBF-B. Our results indicate that a third polypeptide, designated CBF-C, forms a tight complex with CBF-A. Together with CBF-A and CBF-B, CBF-C is required for the DNA binding activity of CBF.

Biochemical analysis of the B subunit of the heteromeric CCAAT-binding factor. A DNA-binding domain and a subunit interaction domain are specified by two separate segments

CCAAT-binding factors A (CBF-A) and B (CBF-B) are two subunits of the heteromeric CCAAT-binding factor. Portions of CBF-A and CBF-B have a high degree of amino acid sequence identity to segments of the HAP3 and HAP2 subunits of a yeast multimeric transcription factor. We show here that the subunits of CBF interact with each other in the absence of DNA binding. This interaction was revealed by cross-linking and coimmunoprecipitation studies. Both the DNA binding and subunit interaction functions of CBF-B have been examined by mutational analysis. A segment of 83 amino acids from residues 252 to 334, which corresponds to the evolutionarily conserved portion of CBF-B, is necessary and sufficient for CBF-A-dependent DNA binding. Carboxyl-terminal deletions of this segment (or mutations in arginine residues in this carboxyl-terminal part) abolish DNA binding, but do not alter subunit interactions between CBF-A and CBF-B. Mutations in hydrophobic amino acids within the amino-terminal part of the evolutionarily conserved sequence at positions 252-334 result in loss of both DNA binding and subunit interaction activities. Our results indicate that the evolutionarily conserved segment of CBF-B contains both DNA-binding and subunit interaction domains and that the integrity of both domains is essential for DNA binding.

Purification and molecular cloning of the "A" chain of a rat heteromeric CCAAT-binding protein. Sequence identity with the yeast HAP3 transcription factor

CCAAT-binding factor (CBF) is a heteromeric mammalian transcription factor which binds to sequences containing a CCAAT motif in a number of promoters such as those for type I collagen, albumin, MHC Class II, beta-actin, and others. It consists of two different components that are both needed for DNA binding. We have purified the "A" chain of CBF to apparent homogeneity by sequence-specific DNA affinity chromatography followed by Mono S and Mono Q ion-exchange chromatography and obtained the amino acid sequences of tryptic peptides of this polypeptide. Amino acid sequences of two of these tryptic peptides were used to synthesize oligonucleotide primers. The primers served to obtain a small cDNA by the polymerase chain reaction method, which was then further used to obtain larger cDNA clones. DNA sequence analysis of a representative cDNA clone revealed the presence of an open reading frame of 207 amino acids coding for a putative polypeptide of 25 kDa. Transcription of these cDNAs in vitro followed by translation in a reticulocyte lysate produced a polypeptide that migrated on sodium dodecyl sulfate-polyacrylamide gel electrophoresis with the same mobility as the native A chain. The deduced amino acid sequence of the A chain showed a remarkable identity over a length of 90-amino acid residues with a sequence of the Hap3 polypeptide, a component of a heteromeric multisubunit yeast transcription factor.

The B subunit of a rat heteromeric CCAAT-binding transcription factor shows a striking sequence identity with the yeast Hap2 transcription factor

CBF is a heteromeric mammalian transcription factor that binds to CCAAT sequences in a number of promoters such as the two type I collagen promoters, the albumin promoter, the major histocompatibility complex class II promoter, and others. It is composed of two components, A and B, that are both needed for DNA binding. We have isolated a rat cDNA containing the complete 341-amino acid coding sequence of the B component of CBF. Expression of this cDNA in vitro generates a polypeptide that shows the same dependency on the A component as the native B component in the formation of a complex with a CCAAT-containing DNA. The C-terminal portion of the B component from residue 260 to residue 312 shows a 75% sequence identity with a portion of the Hap2 protein, a component of a heteromeric CCAAT-binding protein in yeast. In contrast, the rest of the protein shows little sequence homology with Hap2, although both proteins contain glutamine-rich domains. In the B component of CBF this domain spans the amino-terminal 60% of the protein, whereas in Hap2 this domain is much smaller. Hence, only a few changes in one domain of this protein were tolerated during evolution between yeast and mammals, whereas the rest of the protein diverged much more extensively.

Selective activation of transcription by a novel CCAAT binding factor

A novel CCAAT binding factor (CBF) composed of two different subunits has been extensively purified from rat liver. Both subunits are needed for specific binding to DNA. Addition of this purified protein to nuclear extracts of NIH 3T3 fibroblasts stimulates transcription from several promoters including the alpha 2(I) collagen, the alpha 1(I) collagen, the Rous sarcoma virus long terminal repeat (RSV-LTR), and the adenovirus major late promoter. Point mutations in the CCAAT motif that show either no binding or a decreased binding of CBF likewise abolish or reduce activation of transcription by CBF. Activation of transcription requires, therefore, the specific binding of CBF to its recognition sites.

Properties of B-ring analogues of colchicine

Absorption spectra of colchicine and its analogues are affected by the presence of the B-ring, although it is not part of the chromophore (C-ring). Thus, 2-methoxy-5-(2',3'4'-trimethoxyphenyl)tropone has absorption maxima at 341 nm, whereas that of desacetamidocolchicine is at 353 nm. A similar red shift in the lambda max of colchicine, desacetamidocolchicine and 2-methoxy-(2',3',4'-trimethoxyphenyl)tropone also occurs when they are immobilized in the binding site to tubulin or in pure glycerol. We also observed that the B-ring of colchicine alone or with substituent does not affect the UV-induced rearrangement of colchicine to lumicolchicine. However, in the absence of the B-ring, as in the case of 2-methoxy-5-(2',3'4'-trimethoxyphenyl)tropone, the rearrangement reaction of the C-ring slows down significantly.

B ring regulation of colchicine binding kinetics and fluorescence

Several properties of the colchicine-tubulin interaction such as association rate, reversibility, and the promotion of drug fluorescence have been related to the B ring of colchicine. The B ring itself retards the binding rate, and substitution at C-7 leads to further binding rate decreases that appear to be related to both substituent bulk and the presence of a N-acyl group. Thus, the decreasing order of binding rates is 2-methoxy-5-(2',3',4'-trimethoxyphenyl)tropone greater than deacetamidocolchicine greater than deacetylcolchicine greater than or equal to colcemid greater than colchicine greater than N-benzoyldeacetylcolchicine, etc. The apparent irreversibility of the binding seems more closely related to the presence of an N-acyl group rather than the bulk of the substituent at C-7. Substitution at C-7 also affects the tropolone fluorophore. Thus, amines (deacetylcholchicine, colcemid, or N-methylcolcemid) fluoresce poorly in the presence of tubulin, whereas substitution of the amino group with an acyl group enhances fluorescence. The presence of an N-acyl group at C-7 is essential for enhanced fluorescence. We conclude that, in addition to A- and the C-ring portion of the molecule, the B ring of colchicine is a third determinant recognized by the binding site on tubulin.