Cdc2 and mitogen-activated protein kinases modulate DNA binding properties of the putative transcriptional regulator Chironomus high mobility group protein I

Cells of the dipteran insect Chironomus contain a high mobility group protein that is homologous to the mammalian high mobility group proteins I/Y (HMGI/Y). These proteins facilitate the assembly of higher order nucleoprotein complexes. In proliferating cells, >30% of Chironomus HMGI was found to be phosphorylated. The phosphorylation sites were mapped to Ser3, Ser22, and Ser72 and were found to be substrates for the kinases Cdc2 (and mitogen-activated protein (MAP)), MAP, and Ca2+/phospholipid-dependent protein kinase, respectively. In mitotically arrested cells, the extent of phosphorylation at Ser3 increased, whereas phosphorylation at Ser22 remained unchanged. In nondividing cells, phosphorylation at Ser3 and Ser22 was strongly reduced. The DNA binding affinity of Chironomus HMGI was not influenced by single phosphorylation at Ser3 or Ser22. In contrast, phosphorylation at both of these sites resulted in a 10-fold weakening of the binding activity and altered the mode of protein-DNA interaction. Since both human and murine HMGI/Y proteins, similarly to the insect HMGI protein, possess phosphorylation sites for Cdc2 and MAP kinases that intersperse the AT-hook DNA-binding motifs, our results may reflect a general mechanism that regulates the properties and function of this class of putative transcriptional regulators.

Formation of a regulatory factor X/X2 box-binding protein/nuclear factor-Y multiprotein complex on the conserved regulatory regions of HLA class II genes

Coordinate regulation of MHC class II genes occurs in a tissue-specific and cytokine-inducible manner. While the upstream regulatory sequences are conserved among all MHC class II genes, multiple base pair changes are found, even within the essential X box region. Analysis of all class II X boxes reveals differential binding between two transcription factors known to interact with the X box region, regulatory factor X and X2 box-binding protein (RFX and X2BP) of the HLA-DRA gene. These data presented a paradox with regard to the coordinate regulation of the class II genes if the factors though to regulate the HLA-DRA gene do not bind to the homologous sequence of all class II genes. Previous results suggested that cooperative interactions between the DNA binding proteins may be the key to understanding this paradox. Here RFX/X2BP/DNA complexes were formed on all class II isotypes regardless of the ability of the X box region to bind either factor individually. To further determine the role of the interactions between the X and Y factors, multiprotein/DNA complexes containing RFX, X2BP, NF-Y, and X-Y box DNA of the DRA and DRB genes were formed. This quaternary complex was extremely stable to competitor DNA, with a half-life > 4 h. These results suggest that the conserved X and Y boxes of class II genes function similarly and define a single multiprotein regulatory complex for class II expression in B cells.

Oncogenic raf-1 induces the expression of non-histone chromosomal architectural protein HMGI-C via a p44/p42 mitogen-activated protein kinase-dependent pathway in salivary epithelial cells

The enzyme activity of mitogen-activated protein kinase (MAP kinase) increases in response to agents acting on a variety of cell surface receptors, including receptors linked to heterotrimeric G proteins. In this report, we demonstrated that Raf-1 protein kinase activity in the mouse parotid glands was induced by chronic isoproterenol administration in whole animals. To investigate the molecular nature underlying cellular responses to Raf-1 activation, we have stably transfected rat salivary epithelial Pa-4 cells with human Raf-1-estrogen receptor fusion gene (DeltaRaf-1:ER) and used mRNA differential display in search of messages induced by DeltaRaf-1:ER activation. Through this approach, the gene encoding non-histone chromosomal protein HMGI-C was identified as one of the target genes activated by oncogenic Raf-1 kinase. Activation of Raf-1 kinase resulted in a delayed and sustained increase of HMGI-C expression in the Pa-4 cells. The induction of HMGI-C mRNA level is sensitive to both the protein synthesis inhibitor cycloheximide and transcription inhibitor actinomycin D. The role of the extracellular signal-related kinase (ERK) signaling pathway in the HMGI-C induction was highlighted by the result that the MAP kinase kinase (MEK) inhibitor, PD 98059, blocked DeltaRaf-1:ER- and 12-O-tetradecanoylphorbol-13-acetate-stimulated HMGI-C induction. Altogether, these findings support the notion that the Raf/MEK/ERK signaling module, at least in part, regulates transcriptional activation of the chromosomal architectural protein HMGI-C.

Alleviation of histone H1-mediated transcriptional repression and chromatin compaction by the acidic activation region in chromosomal protein HMG-14

Histone H1 promotes the generation of a condensed, transcriptionally inactive, higher-order chromatin structure. Consequently, histone H1 activity must be antagonized in order to convert chromatin to a transcriptionally competent, more extended structure. Using simian virus 40 minichromosomes as a model system, we now demonstrate that the nonhistone chromosomal protein HMG-14, which is known to preferentially associate with active chromatin, completely alleviates histone H1-mediated inhibition of transcription by RNA polymerase II. HMG-14 also partially disrupts histone H1-dependent compaction of chromatin. Both the transcriptional enhancement and chromatin-unfolding activities of HMG-14 are mediated through its acidic, C-terminal region. Strikingly, transcriptional and structural activities of HMG-14 are maintained upon replacement of the C-terminal fragment by acidic regions from either GAL4 or HMG-2. These data support the model that the acidic C terminus of HMG-14 is involved in unfolding higher-order chromatin structure to facilitate transcriptional activation of mammalian genes.

DNA sequence context and protein composition modulate HMG-domain protein recognition of cisplatin-modified DNA

Proteins containing the high mobility group (HMG) DNA-binding domain form specific complexes with cisplatin-modified DNA which shield the major intrastrand d(GpG) and d(ApG) cross-links from excision repair. The molecular basis for the specificity of binding was investigated for the two isolated domains of HMG1 with a series of 15-bp oligonucleotides, d(CCTCTCN1G*G*N2TCTTC). (GAAGAN3CCN4GAGAGG), where asterisks denote N7-modification of guanosine with cisplatin. Alteration of the nucleotides flanking the platinum lesion modulated HMG1domA recognition in this series by over 2 orders of magnitude and revealed an unprecedented preference for N2 = dA > T > dC. The flanking nucleotide preference for HMG1domB interaction with this oligonucleotide series was less pronounced and had only a 20-fold range of binding affinities. For the N1 = N2 = dA 15-bp probe, 100-fold stronger binding occurred with HMG1domA (Kd = 1.6 +/- 0.2 nM) compared to HMG1domB (Kd = 134 +/- 18 nM). The platinum-dependent recognition of the N1 = N2 = dA 15-bp probe saturates at 1 equiv of HMG1domA and is highly specific, as evidenced by the 1000-fold decrease in HMG1domA binding affinity for the corresponding unplatinated oligonucleotide. HMG domains were unable to bind specifically to cisplatin-modified DNA-RNA hybrids, revealing the need for a deoxyribose sugar backbone for specific complex formation with HMG-domain proteins. Protein-DNA contacts which may account for these observed binding preferences are proposed, and potential implications for the biological processing of cisplatin-DNA adducts are discussed.

Oxidation of a critical methionine modulates DNA binding of the Drosophila melanogaster high mobility group protein, HMG-D

HMG-D is a major high mobility group chromosomal protein present during early embryogenesis in Drosophila melanogaster. During overexpression and purification of HMG-D from E. coli, a key DNA binding residue, methionine 13, undergoes oxidation to methionine sulfoxide. Oxidation of this critical residue decreases the affinity of HMG-D for DNA by three-fold, altering the structure of the HMG-D-DNA complex without affecting the structure of the free protein. This work shows that minor modification of DNA intercalating residues may be used to fine tune the DNA binding affinity of HMG domain proteins.

The solution structure of an HMG-I(Y)-DNA complex defines a new architectural minor groove binding motif

The solution structure of a complex between a truncated form of HMG-I(Y), consisting of the second and third DNA binding domains (residues 51-90), and a DNA dodecamer containing the PRDII site of the interferon-beta promoter has been solved by multidimensional nuclear magnetic resonance spectroscopy. The stoichiometry of the complex is one molecule of HMG-I(Y) to two molecules of DNA. The structure reveals a new architectural minor groove binding motif which stabilizes B-DNA, thereby facilitating the binding of other transcription factors in the opposing major groove. The interactions involve a central Arg-Gly-Arg motif together with two other modules that participate in extensive hydrophobic and polar contracts. The absence of one of these modules in the third DNA binding domain accounts for its-100 fold reduced affinity relative to the second one.

Chromosomal location and expression of the single-copy gene encoding high-mobility-group protein HMG-I/Y in Arabidopsis thaliana

A cDNA encoding the HMG-I/Y protein from Arabidopsis thaliana has been isolated and characterised by nucleotide sequencing. The 903 bp cDNA contains a 612 bp open reading frame encoding a protein of 204 amino acid residues showing homology to HMG-I/Y proteins from other plant species. The protein contains four copies of the 'AT-hook' motif which is involved in binding A/T-rich DNA. Southern blotting showed that the HMG-I/Y gene was present in a single copy in the Arabidopsis genome. The gene was localised to the top of chromosome 1 by RFLP analysis of F8 recombinant inbred lines. Northern blotting showed that the gene was expressed in all organs examined, with the highest expression in flowers and developing siliques.

Molecular cloning and characterization of a cDNA for the highly conserved HMG-like protein (Pf16) gene of Plasmodium falciparum

A cDNA clone (PfHB3-2-4) of 1538 bp corresponding to the highly conserved HMG-like protein (Pf16) was isolated. However, northern analysis suggests that the mRNA is about 2.2 to 2.3 kb. Analysis by RT-PCR indicated that the 0.6 to 0.7 kb sequence missing in the cDNA maps to the 3' end, suggesting that the cDNA is terminated within the 26 adenosine residues that are in the middle of the Pf16 sequence. The most unique feature about this cDNA is the presence of two open reading frames (ORF), one from nucleotides 91 to 927 and the other starting from 1421. The second ORF corresponds to Pf16. Expression of the cDNA clones in Escherichia coli and translation in rabbit reticulocytes of RNA transcribed from the T7 promoter of the cDNA clones revealed that only the 3' end Pf16 is translated from this mRNA. Further experiments with antisense oligonucleotides specific for Pf16 indicated that the Pf16 protein serves an important function in the life cycle of the parasite.

AND-1, a natural chimeric DNA-binding protein, combines an HMG-box with regulatory WD-repeats

Using a specific monoclonal antibody (mAb AND-1/23-5-14) we have identified, cDNA-cloned and characterized a novel DNA-binding protein of the clawed toad, Xenopus laevis, that is accumulated in the nucleoplasm of oocytes and various other cells. This protein comprises 1,127 amino acids, with a total molecular mass of 125 kDa and a pI of 5.27. It is encoded by a mRNA of approximately 4 kb and contains, in addition to clusters of acidic amino acids, two hallmark motifs: the amino-terminal part harbours seven consecutive ‘WD-repeats’, which are sequence motifs of about 40 amino acids that are characteristic of a large group of regulatory proteins involved in diverse cellular functions, while the carboxy terminal portion possesses a 63-amino-acid-long ‘HMG-box’, which is typical of a family of DNA-binding proteins involved in regulation of chromatin assembly, transcription and replication. The DNA-binding capability of the protein was demonstrated by DNA affinity chromatography and electrophoretic mobility shift assays using four-way junction DNA. Protein AND-1 (acidic nucleoplasmic DNA-binding protein) appears as an oligomer, probably a homodimer, and has been localized throughout the entire interchromatinic space of the interphase nucleoplasm, whereas during mitosis it is transiently dispersed over the cytoplasm. We also identified a closely related, perhaps orthologous protein in mammals. The unique features of protein AND-1, which is a ‘natural chimera’ combining properties of the WD-repeat and the HMG-box families of proteins, are discussed in relation to its possible nuclear functions.

Expression of high-mobility group-1 mRNA in human gastrointestinal adenocarcinoma and corresponding non-cancerous mucosa

An 1194-nucleotide complementary DNA clone, FM1, encoding a human high-mobility group-1 protein (HMG-1) was isolated from a well-differentiated human gastric-carcinoma cell line complementary DNA library by a differential screening method. FM1 is similar to the published human HMG-1 in mature protein, with only 3 different codons at positions 11, 149, and 190. We analyzed 33 gastric and colorectal adenocarcinomas for expression of the FM1 gene. Northern-blot analysis revealed that all of the cancers expressed FM1 at a higher level than in corresponding non-cancerous mucosa, with 2 transcripts of approximately 1.4 and 2.4 kilobases. The FM1 expression level in the non-cancerous tissues increased with the depth of accompanying cancer invasion. Only 18.2% of well-differentiated cancers showed a higher expression level in corresponding non-cancerous tissues, whereas the expression in corresponding non-cancerous tissues was significantly higher in moderately (60%) and poorly differentiated (83.3%) cancers. In situ hybridization demonstrated the location of FM1 mRNA in well- and poorly differentiated gastric-cancer cells as well as in non-cancerous tissue adjacent to poorly differentiated gastric cancer, but no hybridization was detected in normal epithelial cells adjacent to well-differentiated gastric cancer. These findings may provide new information on HMG-1 mRNA expression in human gastrointestinal cancer and suggest a correlation between FM1 mRNA expression to the differentiation and the stage of human gastrointestinal adenocarcinomas.

The acidic tail of the high mobility group protein HMG-D modulates the structural selectivity of DNA binding

HMG-D is one of the Drosophila counterparts of the vertebrate HMG1/2 class of abundant chromosomal proteins and contains three domains: an HMG domain followed by a basic region and a short acidic carboxyterminal tail. We show that the HMG domain of HMG-D does not bind to deformed DNA structures such as DNA bulges, cis-platinated DNA or four-way junctions but does bind tightly to DNA microcircles, suggesting that in vivo the natural ligands of this domain are tightly bent DNA loops. The flanking basic region substantially increases the DNA-binding activity of the HMG domain to DNA ligands other than microcircles. We demonstrate that the acidic tail alters the structural selectivity of DNA binding by increasing the affinity for deformed DNA and decreasing the affinity for linear B-DNA. Finally, we show that the acidic tail increases the efficiency of constraining preformed negative supercoils but conversely decreases the efficiency of supercoiling relaxed DNA in the presence of topoisomerase I.

Structural transitions of a GG-platinated DNA duplex induced by pH, temperature and box A of high-mobility-group protein 1

[1H, 15N] and 1H NMR, and CD spectroscopy are used to show that the duplex d(A-T-A-C-A-T-Pt 7G-Pt7G-T-A-C-A-T-A).d(T-A-T-G-T-A-C-C-A-T-G-T-A-T), where Pt7G is platinated guanine, containing the cis-[Pt(NH3)2]2+ adduct, undergoes reversible temperature-induced (T0.5 310 K) and pH-induced (pKa approximately 4.8) transitions between kinked-duplex and distorted forms, with the latter forms predominating at high temperature and low pH. A related pH-induced structural change was observed for the unplatinated duplex (pKa 4.69, Hill coefficient n = 1.4) but was less cooperative than for the platinated duplex (n = 2). The pH-induced transition is attributed to protonation of cytosine residues and has wider implications, since many reported NMR studies of DNA are carried out near pH 5 to minimize NH-exchange rates. The [Pt(en)]2+ (where en is 1,2-ethanediamine) GG chelate of the same duplex is shown to exist in kinked and distorted forms, and the [1H,15N]-NMR shifts for the kinked form are indicative of the presence of highly stereospecific interactions with the Pt-NH protons. On binding of the duplex platinated with [Pt(NH3)2]2+ to high-mobility-group protein 1 (HMG1) box A, similar changes in shifts of the Pt-NH3 resonances to those induced by raising the temperature or lowering the pH were observed. The specific changes in 1H-NMR chemical shifts of HMG1 box A are consistent with binding of the platinated duplex (intermediate exchange rate on the 1H-NMR time-scale) to the concave face of the protein via helices I and II and the intervening loop.

Structural and functional consequences of mutations within the hydrophobic cores of the HMG1-box domain of the Chironomus high-mobility-group protein 1a

The high-mobility-group protein 1 box domain (HMG1-BD) is a structural element found in several DNA-binding proteins in eukaryotic cells. Its structure is dominated by three alpha-helices. The spatial arrangement of these helices into an L-shaped molecule is maintained by a number of apolar residues organized into a main and a secondary hydrophobic core. To analyze the significance of these residues for proper folding, conformational stability, and ability to bind and bend DNA, we have mutated the highly conserved Trp14 of the Chironomus HMG1a protein and have synthesized a series of N-terminally truncated forms. The observed alterations in DNA-binding and DNA-bending characteristics were correlated with structural consequences, as revealed by CD spectroscopy, limited trypsin digestion, and transverse urea gradient gel electrophoresis. Mutation of the Trp14 residue (Chironomus [W14A]HMG1a) and deletion of the seven N-terminal residues, respectively, which are members of the main and the secondary core of Chironomus HMG1a, both resulted in a substantial unfolding of the protein. Unexpectedly, these mutants still retained their ability to bind and bend DNA. Conformational analysis of wild-type cHMG1a and [W14A]cHMG1a showed that the proteins unfold at 2-4 M urea. In contrast, their DNA complexes persisted even at 6-8 M of the denaturant. Multiple contacts between the HMG1-BD and the DNA are probably responsible for the unusual stability of the complexes.

High-mobility-group proteins and cancer--an emerging link

In the last few years, considerable interest has been generated in the role of high-mobility-group (HMG) proteins, and HMG box proteins generally, in cancer development and therapy. These proteins were discovered in the early 1970s (Goodwin et al. 1973) as a group of nonhistone proteins. Some members of the HMG protein family (i) constitute a class of important architectural proteins involved in transcriptional regulation of genes, (ii) are frequently expressed in transformed cells at levels that correlate with the degree of neoplastic cell transformation, (iii) participate in gene rearrangements, which are linked to the emergence of benign solid tumors, (iv) confer the ability to recognize DNA-cisplatin adducts selectively, and (v) provide a new delivery system for efficient gene transfer. It should be considered that some HMG proteins, acting as architectural proteins that bring many of the transcription factors into precise three-dimensional shapes, may have a similar critical role in neoplastic transformation to that of some transcription factors themselves.

Characterization of a high mobility group 1/2 homolog in yeast

A 35-kDa polypeptide belonging to the high mobility group family of proteins was purified from the yeast Saccharomyces cerevisiae on the basis of its association with a DNA helicase activity. Amino acid sequence alignment suggests that this protein, Hmo1p, is related to the HMG1/2 class of chromatin-associated proteins. Consistent with this prediction, the Hmo1 protein immunolocalizes to the nucleus, binds single-stranded DNA, and unwinds DNA in the presence of eukaryotic DNA topoisomerase I. While the purified protein has no DNA helicase activity on its own, immunoprecipitation experiments confirm that Hmo1p associates with a 5' to 3' DNA helicase activity in nuclear extracts. The in vivo role of the protein was investigated by constructing an hmo1 deletion mutant. This strain has a severe growth defect, reduced plasmid stability, and chromatin that is hypersensitive to micrococcal nuclease digestion. Taken together, the data indicate that HMO1 is likely to be the homolog of HMG1/2 in higher cells and that it plays an important role in genome maintenance.

Maize chromosomal HMGc. Two closely related structure-specific DNA-binding proteins specify a second type of plant high mobility group box protein

The chromosomal high mobility group (HMG) proteins are small and abundant non-histone proteins common to eukaryotes. We have purified the maize HMGc protein from immature kernels and characterized it by mass spectrometry and amino acid sequence analysis. HMGc could be resolved into two similar proteins by reversed phase chromatography. Cloning and characterization of the corresponding cDNAs revealed that they encode two closely related maize HMGc proteins, now termed HMGc1 and HMGc2. Their theoretical masses of 15,316 and 15,007 Da are >300 Da lower than the masses determined for the proteins purified from maize, indicating post-translational modifications of the proteins. Despite sequence similarity to maize HMGa (and previously described homologous proteins of other species) amino acid sequence alignments reveal that HMGc is in several conserved regions distinct from these proteins. Consequently, we have identified a novel type of plant protein containing an HMG box DNA binding domain and belonging to the HMG1 protein family. HMGc1 and HMGc2 were expressed in Escherichia coli, purified to homogeneity, and analyzed for their DNA binding properties. They proved to bind to DNA structure-specifically since they formed complexes with DNA minicircles at concentrations approximately 100-fold lower than the concentrations required to form complexes with linear fragments of identical sequence. Furthermore, HMGc1 and HMGc2 can constrain negative superhelical turns in plasmid DNA.

The Schizosaccharomyces pombe map1 gene encodes an SRF/MCM1-related protein required for P-cell specific gene expression

Cells of Schizosaccharomyces pombe undergo mating and meiosis when starved for a nitrogen source. In this process a P and and M cell first mate to generate a diploid zygote, which subsequently enters meiosis and sporulates. The P mating type is controlled by the mat1-Pc gene at the mating type locus, together with a gene called map1. We show that these two functions are required for expression of the P-specific gene map3. We have cloned the map1 gene and show that it encodes a putative MADS-box containing transcription factor related to mammalian Serum Response Factor (SRF) and Saccharomyces cerevisiae MCM1. The Mat1-Pc protein contains a motif characteristic for proteins that interact with MADS-box factors, suggesting that Mat-Pc and Map1 may form a heterodimer that activates the P-specific map3 gene.

A novel activity of HMG domains: promotion of the triple-stranded complex formation between DNA containing (GGA/TCC)11 and d(GGA)11 oligonucleotides

The high mobility group protein (HMG)-box is a DNA-binding domain found in many proteins that bind preferentially to DNA of irregular structures in a sequence-independent manner and can bend the DNA. We show here that GST-fusion proteins of HMG domains from HMG1 and HMG2 promote a triple-stranded complex formation between DNA containing the (GGA/TCC)11 repeat and oligonucleotides of d(GGA)11 probably due to G:G base pairing. The activity is to reduce association time and requirements of Mg2+ and oligonucleotide concentrations. The HMG box of SRY, the protein determining male-sex differentiation, also has the activity, suggesting that it is not restricted to the HMG-box domains derived from HMG1/2 but is common to those from other members of the HMG-box family of proteins. Interestingly, the box-AB and box-B of HMG1 bend DNA containing the repeat, but SRY fails to bend in a circularization assay. The difference suggests that the two activities of association-promotion and DNA bending are distinct. These results suggest that the HMG-box domain has a novel activity of promoting the association between GGA repeats which might be involved in higher-order architecture of chromatin.

Genomic structure and expression of the murine Hmgi-c gene

The murine Hmgi-c gene, a member of the Hmgi gene family, contains five exons encompassing >110 kb of genomic DNA at the pygmy locus on mouse chromosome 10. Northern analysis identified a 4.1 kb transcript which contains a 324 bp open reading frame encoding a 12 kDa HMGI-C protein. Further analysis defined both the 5' and 3' untranslated regions of the Hmgi-c mRNA species as 658 and 2967 bp respectively. The HMGI-C protein has three consecutive AT hook DNA binding domains and an acidic domain, each of which are encoded by individual exons; such an organization is conserved among the HMGI gene family members from insects to mammals. Similar to the HMGI/Y proteins, the HMGI-C protein does not function as a typical transcriptional activator. Developmental studies revealed that the Hmgi-c gene is expressed predominantly during mouse embryogenesis. Since the human homolog is disrupted in a number of tumors, HMGI-C could play an important role in cell proliferation and differentiation during mammalian development.

Repair of cisplatin--DNA adducts by the mammalian excision nuclease

Nucleotide excision repair is one of the many cellular defense mechanisms against the toxic effects of cisplatin. An in vitro excision repair assay employing mammalian cell-free extracts was used to determine that the 1,2-d(ApG) intrastrand cross-link, a prevalent cisplatin-DNA adduct, is excised by the excinuclease from a site-specifically modified oligonucleotide 156 base pairs in length. Repair of the minor interstrand d(G)/d(G) cross-link was not detected by using this system. Proteins containing the high mobility group (HMG) domain DNA-binding motif, in particular, rat HMG1 and a murine testis-specific HMG-domain protein, specifically inhibit excision repair of the intrastrand 1,2-d(GpG) and -d(ApG) cross-links. This effect was also exhibited by a single HMG domain from HMG1. Similar inhibition of repair of a site-specific 1,2-d(GpG) intrastrand cross-link by an HMG-domain protein also occurred in a reconstituted system containing highly purified repair factors. These results indicate that HMG-domain proteins can block excision repair of the major cisplatin-DNA adducts and suggest that such an activity could contribute to the unique sensitivity of certain tumors to the drug. The reconstituted excinuclease was more efficient at excising the 1,3-d(GpTpG) intrastrand adduct than either the 1,2-d(GpG) or d(ApG) intrastrand adducts, in agreement with previous experiments using whole cell extracts [Huang, J. -C., Zamble, D. B., Reardon, J. T., Lippard, S. J., Sancar, A. (1994) Proc. Natl. Acad. Sci. U.S.A. 91, 10394-10398]. This result suggests that structural differences among the platinated DNA substrates, and not the presence of unidentified cellular factors, determine the relative excision repair rates of cisplatin-DNA intrastrand cross-links in the whole cell extracts.

Localized DNA flexibility contributes to target site selection by DNA-bending proteins

Certain DNA-binding proteins function as architectural elements by bending DNA. We have studied the binding of three such proteins, the prokaryotic HU and integration host factor (IHF) and the eukaryotic HMG1, to DNA in which flexibility is enhanced by tandem mismatches and by substituting 5-hydroxymethyluracil (hmU) for thymine (T). IHF and HU have higher affinity for DNA with two 4-nt loops than for perfect duplex DNA with a sequence that corresponds to a binding site for the phage-encoded homolog, TF1. HU has a high affinity for DNA with 4-nt loops separated by 9 bp (Kd = 3.5 nM), with suboptimal binding for other loop separations. IHF-binding is optimal when 4-nt loops are 8 to 9 bp apart; optimal complex formation with DNA representing the specific IHF-binding site H' requires that loops do not disrupt the consensus sequence and that one 4-nt loop borders the dyad axis-proximal block of consensus sequence (Kd = 0.3 nM, approximately tenfold lower than for H' perfect duplex DNA). HMG1 also binds preferentially to DNA with loops. All three proteins bind more tightly to DNA in which thymine is replaced with hmU. IHF has a tenfold higher affinity for hmU-DNA without a consensus IHF site (Kd = 7.6 nM) than for the corresponding T-DNA but does exhibit site-selectivity in hmU-DNA; Kd = 0.6 nM for the hmU-containing version of H'. Tighter binding to hmU-DNA is consistent with greater flexibility, and the distinct influence of loop position on complex formation suggests that sequence-dependent variations in flexibility of duplex DNA play a significant role in target-site selection by these DNA-bending proteins.

SOX genes: architects of development

Development in higher organisms involves complex genetic regulation at the molecular level. The emerging picture of development control includes several families of master regulatory genes which can affect the expression of down-stream target genes in developmental cascade pathways. One new family of such development regulators is the SOX gene family. The SOX genes are named for a shared motif called the SRY box a region homologous to the DNA-binding domain of SRY, the mammalian sex determining gene. Like SRY, SOX genes play important roles in chordate development. At least a dozen human SOX genes have been identified and partially characterized (Tables 1 and 2). Mutations in SOX9 have recently been linked to campomelic dysplasia and autosomal sex reversal, and other SOX genes may also be associated with human disease.

Structural and functional homology between the 29 kD rat liver nucleoprotein and the high mobility group 1 protein

A 29 kD soluble rat liver nucleoprotein (p29) has increased binding affinity for the hormone responsive element (RE) of the rat haptoglobin (Hp) gene during the acute-phase reaction. In this work the possibility of its structural and functional homology to the high mobility group 1 (HMG1) nonhistone protein constituent of chromatin was examined. The results of two-dimensional gel electrophoresis, Southwestern and Western immunoblot analyses, showed that p29 and HMG1 are homologous protein species. On the basis of in vitro and in vivo phosphorylation/dephosphorylation experiments, we discuss the modulatory role of phosphate groups in view of the structure and function of p29.