Interaction of the mouse chromosomal protein HMG-I with the 3' ends of genes in vitro

Site-specific DNA binding of the Schizosaccharomyces pombe origin recognition complex is determined by the Orc4 subunit

The mechanism by which origin recognition complexes (ORCs) identify replication origins was investigated using purified Orc proteins from Schizosaccharomyces pombe. Orc4p alone bound tightly and specifically to several sites within S. pombe replication origins that are genetically required for origin activity. These sites consisted of clusters of A or T residues on one strand but were devoid of either alternating A and T residues or GC-rich sequences. Addition of a complex consisting of Orc1, -2, -3, -5, and -6 proteins (ORC-5) altered neither Orc4p binding to origin DNA nor Orc4p protection of specific sequences. ORC-5 alone bound weakly and nonspecifically to DNA; strong binding required the presence of Orc4p. Under these conditions, all six subunits remained bound to chromatin isolated from each phase of the cell division cycle. These results reveal that the S. pombe ORC binds to multiple, specific sites within replication origins and that site selection, at least in vitro, is determined solely by the Orc4p subunit.

Bryostatin-1 specifically inhibits in vitro IgE synthesis

Bryostatin-1, a macrocyclic lactone, is an antineoplastic agent that potently activates protein kinase C. Bryostatin-1 (Bryo) had an immunomodulatory effect on murine B cells in that it specifically inhibited IgE production. IgE levels were inhibited in a B cell dose-response curve, whereas IgM and IgG1 were induced by Bryo treatment. Taken together, ELISPOT and surface Ig staining data suggested that Bryo inhibition occurred at the level of class switching. RT-PCR and real time PCR data showed that this inhibition was achieved at an early step in switch recombination, namely, the appearance of Iepsilon germline transcripts. Although Bryo caused a delay in the proliferative response of IL-4/CD40 ligand trimer-stimulated B cells, CFSE studies revealed that the Bryo-mediated inhibition of class switching to IgE occurred independently of the number of division cycles. Notably, Bryo showed the same specific IgE inhibition in human B cells. This study provides evidence for a unique mechanism regulating IgE production possibly downstream of PKC by specifically modulating Iepsilon germline transcription.

Two widely spaced initiator binding sites create an HMG1-dependent parvovirus rolling-hairpin replication origin

Minute virus of mice (MVM) replicates via a linearized form of rolling-circle replication in which the viral nickase, NS1, initiates DNA synthesis by introducing a site-specific nick into either of two distinct origin sequences. In vitro nicking and replication assays with substrates that had deletions or mutations were used to explore the sequences and structural elements essential for activity of one of these origins, located in the right-end (5') viral telomere. This structure contains 248 nucleotides, most-favorably arranged as a simple hairpin with six unpaired bases. However, a pair of opposing NS1 binding sites, located near its outboard end, create a 33-bp palindrome that could potentially assume an alternate cruciform configuration and hence directly bind HMG1, the essential cofactor for this origin. The palindromic nature of this sequence, and thus its ability to fold into a cruciform, was dispensable for origin function, as was the NS1 binding site occupying the inboard arm of the palindrome. In contrast, the NS1 site in the outboard arm was essential for initiation, even though positioned 120 bp from the nick site. The specific sequence of the nick site and an additional NS1 binding site which directly orients NS1 over the initiation site were also essential and delimited the inboard border of the minimal right-end origin. DNase I and hydroxyl radical footprints defined sequences protected by NS1 and suggest that HMG1 allows the NS1 molecules positioned at each end of the origin to interact, creating a distortion characteristic of a double helical loop.

Cell cycle regulation and functions of HMG-I(Y)

Members of the HMG-I(Y) family of "high mobility group" (HMG) proteins are distinguished from other nonhistone chromatin proteins by their ability to preferentially recognize the structure of the narrow minor groove of A.T-sequences of B-form DNA. In vivo the HMG-I(Y) proteins are localized in the A.T-rich G/Q bands and in the "scaffold-associated regions" (SARs) of metaphase chromosomes. These proteins also share with some of the other "HMG box" proteins the ability to recognize non-B-form structures, such as cruciforms (four-way junctions), as well as the possessing the capacity to introduce both bends and supercoils in substrate DNAs. These characteristics, along with their ability to specifically interact with a number of known transcription factors, enable the HMG-I(Y) proteins to function in vivo as structural transcription factors for a number mammalian genes. The HMG-I(Y) proteins are also in vivo substrates for the cell cycle regulated Cdc2 kinase which phosphorylates the DNA-binding domain(s) of the protein and, as a result, decreases their substrate binding affinity. This reversible in vivo pattern of Cdc2 kinase phosphorylations during the cell cycle is likely to play a major role in mediating the biological function(s) of the HMG-I(Y) proteins.

Substrate structure influences binding of the non-histone protein HMG-I(Y) to free nucleosomal DNA

High mobility group protein HMG-I(Y) selectively binds to stretches of A.T-rich B-form DNA in vitro by recognition of substrate structure rather nucleotide sequence. Recognition of altered DNA structures has also been proposed to explain the preferential binding of this non-histone protein to four-way junction DNA as well as to restricted regions of DNA on random-sequence nucleosome core particles. Here we describe experiments that examine the influence of intrinsic DNA structure, and of structure imposed by folding of DNA around histone cores, on the binding of HMG-I(Y). As substrates for binding, we chose defined-sequence DNA molecules containing A.T-rich segments demonstrated previously to have very different structures in solution. These segments are either intrinsically bent (phase A.T tracts), flexible (oligo[d(A-T)]), or straight and rigid [oligo(dA).oligo(dT)]. DNase-I and hydroxyl radical footprinting techniques were employed to analyze protein binding to these DNAs either free in solution or when they were reconstituted into monomer or dinucleosomes in vitro. Results indicate that the DNA structure exerts a significant influence on HMG-I(Y) binding both when substrates are free in solution and when they are wrapped into nucleosomal structures. For example, when DNA is free in solution, HMG-I(Y) prefers to bind to the narrow minor groove of A.T sequences but sometimes also binds to certain GpC residues having narrowed major grooves that are embedded in such sequences. On the other hand, depending on the structure and/or orientation assumed by particular A.T-rich segments on the surface of reconstituted histone octamers, HMG-I(Y) binding site selection on individual nucleosomes differs considerably. Two observations are of particular importance: (i) HMG-I(Y) can preferentially bind to certain types of A.T-DNA located on the surface of nucleosomes; and (ii) HMG-I(Y) binding can induce localized alterations in the helical periodicity and/or rotational setting of DNA on the surface of some nucleosomes. The abilities of HMG-I(Y) suggests that in vivo the protein may play an important role in recognizing and altering the structure of localized regions of chromatin.

Purification of a high-mobility-group 1 sea-urchin protein and cloning of cDNAs

The isolation of the sea urchin high-mobility-group 1 (HMG1) protein, the cloning of corresponding cDNA clones and the similarity to the human homologue are described. Sea urchin HMG1 was purified as one of the nuclear embryonic proteins which associate with an upstream regulatory element (E1) of the Strongylocentrotus purpuratus (Sp) CyIIIb actin-encoding gene. Using a synthetic oligodeoxyribonucleotide (oligo) which includes the E1 cis-acting element in a DNA affinity chromatography purification, the most prominent of the binding proteins was isolated and the N terminus sequenced. cDNA clones were isolated by screening an embryonic cDNA library with a synthetic oligo derived from the amino acid (aa) sequence. Comparison of the cDNAs ORF to known proteins revealed a 50% aa identity to the mammalian HMG1 and all the structural characteristics of this group of proteins. The sea urchin protein, SpHMG1, was synthesized in bacteria, as well as translated in vitro. Binding assays carried out with the recombinant SpHMG1 protein did not produce specific in vitro complexes with E1.

Interleukin 4-inducible phosphorylation of HMG-I(Y) is inhibited by rapamycin

The non-histone chromosomal protein HMG-I(Y) participates in repression of transcription directed by a promoter which confers interleukin 4 (IL-4)-inducible activation in transfected B cell lines. Metabolic labeling, phosphoamino acid analyses, and in vitro phosphorylation studies demonstrate that IL-4 induces serine phosphorylation of HMG-I(Y) in B lymphocytes. Phosphopeptide mapping shows that the predominant site of phosphorylation contains a casein kinase II consensus motif. The immunosuppressive agent rapamycin has been shown preferentially to inhibit IgE production by IL-4-treated human B cells. It is shown here that rapamycin inhibits both activation of the human germ line epsilon promoter by IL-4 and IL-4-inducible phosphorylation of HMG-I(Y). These findings demonstrate a rapamycin-sensitive pathway that transduces signals from the IL-4 receptor to nuclear factors that regulate inducible transcription. The affinity of normal nuclear HMG-I(Y) for DNA is increased by dephosphorylation in vitro, whereas in vitro kinase reactions using casein kinase II decrease recombinant HMG-I(Y) binding to DNA. These data further suggest a novel mechanism in which phosphorylation triggered by IL-4 or other cytokines could regulate the effects of HMG-I(Y) on gene transcription.

The non-histone chromosomal protein HMG-I(Y) contributes to repression of the immunoglobulin heavy chain germ-line epsilon RNA promoter

The rate of germ-line RNA transcription correlates with the rate of immunoglobulin heavy chain isotype switching. A promoter element for the transcription of RNA from the germ-line mouse immunoglobulin epsilon heavy chain constant region gene is induced by interleukin(IL)-4 and lipopolysaccharide, and is bound at its transcription initiation sites by an IL-4-inducible nuclear protein, NF-BRE. To examine the function of the binding site for this IL-4-inducible complex, substitution mutations were introduced in the promoter. These binding site mutations increased promoter activity and decreased binding of NF-BRE. To investigate the paradox of an IL-4-inducible protein binding to a repressor site in an IL-4-inducible promoter, we determined that the non-histone chromosomal protein HMG-I(Y) binds at the transcription initiation sites of the germ-line epsilon promoter. Assays with antisera against HMG-I(Y) revealed monomeric HMG-I(Y) in nuclear extracts. Cotransfection of an expression construct directing the synthesis of anti-sense HMG-I(Y) RNA also increased promoter activity, consistent with a repressor function of HMG-I(Y). Thus, the data are most consistent with a model in which HMG-I(Y) participates in repression of promoter activity. The effects of IL-4 may include derepression at this site.

HMG protein binding to an A/T-rich positive regulatory region of the pea plastocyanin gene promoter

Gel retardation assays using pea nuclear extracts have detected specific binding to regions of the promoter of the pea plastocyanin gene (petE). Several complexes which differ in sensitivity to competition with unlabelled promoter fragments and various DNA alternating copolymers, to heat treatment and to digestion with proteinase K have been detected. A protein factor, PCF1, forming one of these complexes was heat-stable and most sensitive to competition with poly(dAdT).poly(dAdT) compared to other alternating copolymers. DNase I footprinting assays showed that tracts of A/T-rich sequence within the -444 to -177 positive regulatory region of the petE promoter were protected in the presence of the pea nuclear extract. The factor PCF1 copurified with a high-mobility-group (HMG) protein preparation from pea chromatin. DNase I footprinting with the HMG protein preparation demonstrated that similar tracts of A/T-rich sequences within the promoter were protected. Southwestern-blot analysis of pea HMG proteins purified by gel filtration through Superose 12 detected a single DNA-binding species of 21 kDa. The properties of the factor PCF1 suggest that it is likely to be an HMG I protein.

The nonspecific DNA-binding and -bending proteins HMG1 and HMG2 promote the assembly of complex nucleoprotein structures

The mammalian high mobility group proteins HMG1 and HMG2 are abundant, chromatin-associated proteins whose cellular function is not known. In this study we show that these proteins can substitute for the prokaryotic DNA-bending protein HU in promoting the assembly of the Hin invertasome, an intermediate structure in Hin-mediated site-specific DNA inversion. Formation of this complex requires the assembly of the Hin recombinase, the Fis protein, and three cis-acting DNA sites, necessitating the looping of intervening DNA segments. Invertasome assembly is strongly stimulated by HU or HMG proteins when one of these segments is shorter than 104 bp. By use of ligase-mediated circularization assays, we demonstrate that HMG1 and HMG2 can bend DNA extremely efficiently, forming circles as small as 66 bp, and even 59-bp circles at high HMG protein concentrations. In both invertasome assembly and circularization assays, substrates active in the presence of HMG1 contain one less helical turn of DNA compared with substrates active in the presence of HU protein. Analysis of different domains of HMG1 generated by partial proteolytic digestion indicate that DNA-binding domain B is sufficient for both bending and invertasome assembly. We suggest that an important biological function of HMG1 and HMG2 is to facilitate cooperative interactions between cis-acting proteins by promoting DNA flexibility. A general role for HMG1 and HMG2 in chromatin structure is also suggested by their ability to wrap DNA duplexes into highly compact forms.

Hoechst 33258, distamycin A, and high mobility group protein I (HMG-I) compete for binding to mouse satellite DNA

The experiments described were designed to test the hypothesis that the (A+T)-specific DNA binding ligands Hoechst 33258 and distamycin A affect the condensation of mouse centromeric heterochromatin by competing for binding to satellite DNA with one or more chromosomal proteins. The studies focused on the nonhistone chromosomal protein HMG-I since its binding properties predict it would be a target for competition. Gel mobility shift assays show that HMG-I forms specific complexes with satellite DNA and that the formation of these complexes is competed for by both Hoechst and distamycin. In addition, methidium propyl EDTA Fe(II) [MPE Fe(II)] footprints of ligand-satellite DNA complexes showed essentially the same protection pattern for both drugs and a similar, but not identical, HMG-I footprint. If these in vitro results reflect the in vivo situation then the incomplete condensation of centromeric heterochromatin observed when mouse cells are grown in the presence of either chemical ligand could be a consequence of competition for binding of HMG-I (and possibly other proteins) to satellite DNA.

Sequence-specific binding of HMG-I(Y) to the proximal promoter of the gp91-phox gene

Screening of a cDNA expression library with a CCAAT-box element derived from the myelomonocyte-specific gp91-phox promoter resulted in the isolation of three independent HMG-I(Y) cDNA clones. Filter binding competition studies reveal that HMG-Y binds to this promoter element in a sequence-specific manner and exhibits a gradient of binding affinities for various A/T-rich sequences. Two adjacent A/T-rich regions within the gp91-phox promoter CCAAT-box element are required for maximal binding. In addition, competition experiments demonstrate that the binding affinity of HMG-Y is influenced by sequences that flank A/T-rich core binding sites.

Cell-cell interactions trigger the rapid induction of a specific high mobility group-like protein during early stages of conjugation in Tetrahymena

Conjugation in Tetrahymena represents an ordered developmental pathway which represents the sexual phase of the ciliate life cycle. This pathway is initiated when starved cells of opposite mating types are mixed and are allowed to make a series of cell-cell contacts (a period termed costimulation) which lead to the formation of mating pairs. Here, we demonstrate that two previously described abundant high mobility group (HMG)-like proteins, HMG B and HMG C, whose synthesis appeared to be coordinately regulated in vegetative cells, are not required during the same stages of conjugation. The level of mRNA for both HMG B and HMG C is high during vegetative growth and during the development of new macronuclei. However, specific induction of HMG B mRNA is observed soon after cells of opposite mating types are mixed. Thus, the genes which encode HMG B and HMG C in Tetrahymena can be controlled independently or coordinately. Nuclear run-on experiments show that a significant factor underlying the rapid induction of HMG B message early in the sexual cycle is an increase in the transcriptional activity of the HMG B gene. Experiments are presented which show that this induction of HMG B message requires protein synthesis and is dependent upon the cell-cell contacts made during costimulation. Essentially all of the HMG B protein, which is newly synthesized during this period, is targeted to parental macronuclei where it serves an as yet undetermined function(s).

The metaphase specific phosphorylation of HMG I

In vivo labelling of HeLa cells arrested in metaphase with [32P]-phosphate and in vitro phosphorylation of HMG I with the partially purified growth associated H1 kinase was used to study metaphase specific phosphorylation of HMG I. It was found that threonine 53 and 78 became phosphorylated. These amino acids are embedded in respectively the sequence PTPKR and TPGRK which are similar to the sequences phosphorylated by the growth associated H1 kinase.

An amplification-promoting sequence from mouse genomic DNA: interaction with a trans-acting factor that also affects gene expression

We previously identified murine DNA sequences that stimulate the amplification of cis-linked plasmid DNA in mouse cells under selective conditions (Holst et al., 1988). Here we focus on the structural features of one of these elements, the 229-bp element 5. The amplification-promoting activity was fully recovered from the middle part of element 5. The active region interacted in a sequence-specific way with a protein from nuclear extracts. Using footprinting analyses the binding region was characterized and subsequently shown to be functionally active as an amplification-promoting sequence, whereas a mutated binding site was inactive. Therefore, cis-acting element 5 functioned via interaction with a trans-acting factor. The same binding site was also active as a promoter element for RNA polymerase II transcription, because it efficiently reconstituted the activity of a truncated herpes simplex virus type 1 (HSV-1) thymidine kinase (tk) gene promoter lacking the distal Sp1 binding site. Thus, the same protein seems to function in both RNA polymerase II transcription and DNA amplification. Possible relationships between both functions are discussed.

Satellite DNAs contain sequences that induced curvature

The repeating units of mouse, rat, and alpha-monkey satellites have been cloned. All three show properties that are characteristic of curved DNA: (i) their migration in polyacrylamide gels is slower than predicted from their sequences, and (ii) they appear as curved molecules when visualized by electron microscopy. All three satellite repeats contain runs of d(A.T)n greater than or equal to 3 residues that are likely to be responsible for their curvature. From analysis of 20 different satellite DNA sequences, we conclude that, in satellite DNA, adenine residues show a high tendency to cluster in groups of three or more.

The amino acid sequence of the chromosomal protein HMG-Y, its relation to HMG-I and possible domains for the preferential binding of the proteins to stretches of A-T base pairs

The primary structure of the human high mobility group (HMG) protein HMG-Y has been established except for a few amino acids in the N-terminal and the C-terminal part of the protein. It was found that the sequence was identical to that of HMG-I except for a run of eleven amino acids. Like HMG-I the protein was N-terminally blocked and the palindromic sequence Pro-Arg-Gly-Arg-Pro occurred twice as in HMG-I. The binding of peptides derived from HMG-I (after thermolysin cleavage) to poly (dA-dT).poly(dA-dT) suggested that there are at least two different binding domains in the protein and that binding is not dependent upon an intact protein.