Isolation and partial sequence of bovine cDNA clones for the high-mobility-group protein (HMG-1)

Mutations synthetically lethal with cep1 target S. cerevisiae kinetochore components

CP1 (encoded by CEP1) is a Saccharomyces cerevisiae chromatin protein that binds a DNA element conserved in centromeres and in the 5'-flanking DNA of methionine biosynthetic (MET) genes. Strains lacking CP1 are defective in chromosome segregation and MET gene transcription, leading to the hypothesis that CP1 plays a general role in assembling higher order chromatin structures at genomic sites where it is bound. A screen for mutations synthetically lethal with a cep1 null allele yielded five recessive csl (cep1 synthetic lethal) mutations, each defining a unique complementation group. Four of the five mutations synergistically increased the loss rate of marker chromosomes carrying a centromere lacking the CP1 binding site, suggesting that the cep1 synthetic lethality was due to chromosome segregation defects. Three of these four CSL genes were subsequently found to be known or imputed kinetochore genes: CEP3, NDC10, and CSE4. The fourth, CSL4, corresponded to ORF YNL232w on chromosome XIV, and was found to be essential. A human cDNA was identified that encoded a protein homologous to Csl4 and that complemented the csl4-1 mutation. The results are consistent with the view that the major cellular role of CP1 is to safeguard the biochemical integrity of the kinetochore.

The HMG-1 box protein family: classification and functional relationships

The abundant and highly-conserved nucleoproteins comprising the high mobility group-1/2 (HMG-1/2) family contains two homologous basic domains of about 75 amino acids. These basic domains, termed HMG-1 boxes, are highly structured and facilitate HMG-DNA interactions. Many proteins that regulate various cellular functions involving DNA binding and whose target DNA sequences share common structural characteristics have been identified as having an HMG-1 box; these proteins include the RNA polymerase I transcription factor UBF, the mammalian testis-determining factor SRY and the mitochondrial transcription factors ABF2 and mtTF1, among others. The sequences of 121 HMG-1 boxes have been compiled and aligned in accordance with thermodynamic results from homology model building (threading) experiments, basing the alignment on structure rather than by using traditional sequence homology methods. The classification of a representative subset of these proteins was then determined using standard least-squares distance methods. The proteins segregate into two groups, the first consisting of HMG-1/2 proteins and the second consisting of proteins containing the HMG-1 box but which are not canonical HMG proteins. The proteins in the second group further segregate based on their function, their ability to bind specific sequences of DNA, or their ability to recognize discrete non-B-DNA structures. The HMG-1 box provides an excellent example of how a specific protein motif, with slight alteration, can be used to recognize DNA in a variety of functional contexts.

cDNA sequence and structure of a gene encoding trout testis high-mobility-group-1 protein

Perchloric acid extraction of trout testis nuclei revealed the presence of two large high-mobility-group (HMG) proteins, HMG-T1 and HMG-T2. The sequence of a complete cDNA (1407 bp) for trout testis HMG-1 protein (referred as to HMG-T1) has been determined. The deduced HMG-T1 protein contains 203 amino acids with more than 86% similarity to mammalian HMG-1 proteins. A single-sized mRNA for HMG-T1 has been detected by Northern-blot analysis consistent with the size derived from the HMG-T1 cDNA. Amplification of human and trout genomic DNAs by polymerase chain reaction using primers specific for trout and human HMG-1 cDNAs revealed that unlike the human genome, which contains predominantly intronless HMG-1 sequences, intronless HMG-T1 sequences were not found in the fish genome. Southern-blot analysis suggested that the trout testis HMG-1 gene is encoded by at least two sequences with high similarity. A gene encoding HMG-T1 protein has been isolated from a trout testis genomic library and by PCR of trout genomic DNA (3879 bp). The trout testis HMG-1 gene is organized into five exons (four exons corresponding to the protein-coding region) and its exon/intron boundaries are identical to those of the human HMG-2 gene [Shirakawa, H. & Yoshida, M. (1992). J. Biol. Chem. 267, 6641-6645] suggesting the evolution of HMG-1 and HMG-2 genes from a common ancestor.

A retropseudogene for non-histone chromosomal protein HMG-1

Southern analysis of the human genome revealed that there are several sequences with homology to the nonhistone chromosomal protein HMG-1. The majority of the HMG-1 sequences are intronless as suggested from the polymerase chain reaction of HeLa DNA. Sequencing of a clone from a human placenta genomic library revealed that the clone was intronless and displayed 99% homology to the human HMG-1 cDNA. The 5' regulatory motif, CCAAT, is present in the clone but there is no TATA-box. Most of the differences between the HMG-1 cDNA sequence and the clone involve point mutations with no interruption of the reading frame. The sequence is flanked at 5' and 3' ends by a 15 nucleotide long direct repeat suggesting that the clone is a processed HMG-1 retropseudogene. Sequence differences between the reading frames of the HMG-1 pseudogene and HMG-1 cDNA indicated that the pseudogene arose relatively late in evolution, approximately one million years ago. The present paper is the first study on a genomic sequence related to HMG-1 genes.

Sequence of a cDNA encoding chicken high-mobility-group protein-2

There are several members of the high-mobility-group (HMG) of DNA-binding proteins, including HMG-1, HMG-2, HMG-14 and HMG-17 [Johns: The HMG Chromosomal Proteins. Academic Press, London, 1982]. We report here sequences encoding the chicken HMG-2 protein of 207 amino acids (aa). This assignment is made on the basis of available data which indicate 89% homology of the chicken aa sequence to porcine HMG-2. This compares with 78-81% homology to the HMG-1 proteins of rat, hamster, human, porcine, and bovine origin.

Non-histone chromosomal protein HMG1 reduces the histone H5-induced changes in c.d. spectra of DNA: the acidic C-terminus of HMG1 is necessary for binding to H5

Chemical cross-linking was used to study the interaction between non-histone high-mobility-group (HMG)1 and histone H5 in free solution. The presence of acidic C-terminal domain in HMG1 was shown to be a prerequisite for HMG1 binding to histone H5. The objective of this communication is to ascertain whether HMG1 could affect the conformation of DNA associated with a linker histone H5. Complexes of histone H5 with chicken erythrocyte DNA or an alternating purine-pyrimidine polynucleotide poly[d(A-T)] were prepared at different molar ratios H5/DNA. Changes in DNA conformation in the complexes with histone H5 or H5/HMG1 were monitored by circular dichroism (c.d.). Depending on the molar ratio H5/poly[d(A-T)], under conditions limiting the complex aggregation, three distinct types of c.d. spectra were observed. The addition of HMG1 to H5-DNA complexes reduced in all cases the histone H5-induced conformational changes in poly[d(A-T)]. The sensitivity of H5-poly[d(A-T)] complexes to HMG1 was inversely proportional to the amount of H5 in the complex. The effect of HMG1 was not observed upon removal of the acidic C-terminal domain of HMG1.

High mobility group proteins 1 and 2 function as general class II transcription factors

High mobility group (HMG) proteins 1 and 2 are thought to be associated with chromatin enriched in active gene sequences, to stimulate endogenous transcription of class II and III genes using HMG-depleted nuclei, and to bind specific DNA sequences upstream of the coding regions of trout HMG-T and human beta-globin genes. In testing the possibility that these proteins may act as general transcription factors, the run-off transcription of trout protamine, human beta-globin, adenovirus 2 major late promoter, and herpes simplex virus (HSV) thymidine kinase genes was found to be inhibited by affinity-purified HMG-1 and -2 antibodies. The inhibition was partially relieved by exogenously added HMG-1 or -2. A complementation assay showed that the 0.15 M KCl flowthrough of HeLa nuclear extract fractionated by anion-exchange chromatography (DE-52) could be replaced by purified HMG-1 and/or -2 to complement transcription of the trout protamine gene by the 0.5 M KCl eluate fraction. Inhibition studies with heparin showed that HMG-1 and -2 were required for initiation of transcription. These results indicate an absolute requirement of HMG-1 and -2 for class II gene transcription. Western blotting and transcription reconstituted with purified factors show a copurification of HMG-1 and -2 with factor II B, described earlier by Reinberg and Roeder [(1987) J. Biol. Chem. 262, 3310-3321].

Isolation and characterization of folded fragments released by Staphylococcal aureus proteinase from the non-histone chromosomal protein HMG-1

HMG-1 was isolated from newborn calf thymus without exposure to overt denaturing conditions. The purified protein was digested under several solvent conditions with the proteinase (endoproteinase GluC) from Staphylococcus aureus strain V8. We found that the preferred site of attack by the enzyme on HMG-1 was influenced markedly by ionic strength and temperature. In 0.35 M NaCl/50 mM Tris-phosphate (pH 7.8) at 37 degrees C, cleavage near the junction between the A and B domains is predominant, as previously reported by Carballo et al. (EMBO J. 2 (1983) 1759-1764). However, in 50 mM Tris-phosphate (pH 7.8) lacking NaCl and at 0 degrees C, cleavage between the B and C domains strongly predominates. Three major products of the digestions were purified and characterized. The fragment consisting of domains B and C was found by circular dichroism to contain a substantial amount of helix. This re-emphasizes the importance of avoiding overt denaturing conditions when working with members of the HMG-1 family.

Prothymosin alpha is a nuclear protein

The cellular location of the so-called 'thymic hormone' prothymosin alpha has been studied by microinjection into the cytoplasm of Xenopus oocytes, followed by separate monitoring of nuclear and cytoplasmic concentrations. It is shown that prothymosin alpha migrates to the nucleus at a rate comparable to that of histone H1. Prothymosin alpha cannot therefore be a hormone in the usual sense of the word.

A human placental cDNA clone that encodes nonhistone chromosomal protein HMG-1

From a human placental lambda gt11 cDNA library, we have isolated a cDNA clone that encodes the entire 215-residue amino acid sequence of HMG-1. Analysis of an internal sequence similarity suggests that the DNA-binding domains of HMG-1 are separated by a rather long and flexible linker segment. Southern blotting of DNA digested with BamHI indicated a highly variable number of genes (or pseudogenes) for HMG-1 in different species. Characterization of HMG-1 mRNA expression by Northern blotting showed that three mRNA species of approximately 1.0, 1.4 and 2.4 kb were expressed in all mammalian organs and cell lines examined. These included several rat organs at different stages of development. Northern analysis also suggested the occurrence of HMG-1 mRNA in an invertebrate and a plant species.

The nucleoplasmin nuclear location sequence is larger and more complex than that of SV-40 large T antigen

The carboxy-terminal tail of nucleoplasmin, which specifies entry into the cell nucleus, contains four short sequences that are similar to previously identified nuclear location sequences. We show that none of these is able to locate chicken muscle pyruvate kinase to the cell nucleus. Deletion analysis was used to determine the limits of a nuclear location sequence and indicated that a 14-amino acid segment (RPAATKKAGQAKKK) should function as a minimal nuclear location sequence. When tested directly, however, this sequence was unable to locate pyruvate kinase to the cell nucleus. Restoration of three amino acids of nucleoplasmin sequence at either end of this sequence generated sequences that were able to locate pyruvate kinase to the cell nucleus. The 14-amino acid proposed minimal nuclear location sequence is present in the functional sequences, AVKRPAATKKAGQAKKK, RPAATKKAGQAKKKKLD, and the sequence AVKRPAATKKAGQAKKKKLD, which has additional amino acids at both ends. The minimal sequence element is therefore necessary but not sufficient for transport into the cell nucleus. This unusual feature of the nucleoplasmin nuclear location sequence suggests ways in which it could interact with the nuclear transport mechanism.

Retropseudogenes for human chromosomal protein HMG-17

The human genome contains multiple copies of sequences homologous to the cDNA coding for non-histone chromosomal protein HMG-17. To study the mechanism of generation and dispersion of the HMG-17 multigene family a human genomic library was screened and 70 clones isolated and studied by Southern transfer and restriction site analysis. The results suggest that most of the clones contain unique sequences. Sequence analysis of two genomic clones indicates that they contain elements typical of processed retropseudogenes. Even though both sequences contained open reading frames the sequences lacked introns, were flanked by short, direct repeats and lacked elements associated with functional genes. The sequences of the two pseudogenes were 85% homologous to each other and each was 90% homologous to the human cDNA. Based on the sequence difference in the open reading frame between the pseudogenes and the cDNA it can be estimated that the sequences arose approximately ten million years ago from a common precursor. The present paper, which is the first study on genes coding for this nucleosomal binding protein, indicates that the HMG-17 multigene family is the largest known human retropseudogene family.

Characterization of cDNA sequences corresponding to three distinct HMG-1 mRNA species in line CHO Chinese hamster cells and cell cycle expression of the HMG-1 gene

We have isolated cDNA clones encoding the high mobility group (HMG) protein HMG-1 in line CHO Chinese hamster cells. The cDNA clones correspond to the three HMG-1 mRNA species detected on Northern blots. Three different polyadenylation sites are found to be used. The three mRNA species of sizes 1.05, 1.45 and 2.45 kb are generated by differential polyadenylation at sites 115 nucleotides, 513 nucleotides and 1515 nucleotides downstream from the stop codon. A perfectly conserved putative poly(A) signal AAUAAA is present upstream of only one of the three poly(A) sites. Two homologous but imperfect sequences exist upstream from the other two poly(A) sites. All three HMG-1 mRNA species maintain significant levels throughout the M, G1 and S phases of the cell cycle and the rate of large HMG protein (HMG-1 and HMG-2) synthesis increases approximately two-fold from G1 to S phase.

Nucleolin, the major nucleolar protein of growing eukaryotic cells: an unusual protein structure revealed by the nucleotide sequence

Nucleolin (also called C23) is the major nucleolar protein of exponentially growing eukaryotic cells. It is found associated with intranucleolar chromatin and preribosomal particles. Through use of a polyclonal antiserum, nucleolin cDNA clones were isolated from a Chinese hamster ovary cell library constructed in the expression vector lambda gt11. The isolated cDNAs encoded a polypeptide containing 679 residues of the 713 amino acids of nucleolin. The amino acid sequence presents several unusual features: in particular, repetitive sequences are found at both ends of the molecule. A repeat, Hy-Thr-Pro-Hy-Lys-Lys-Hy-Hy, in which Hy is a nonpolar residue, is found six times in the NH2-end proximal portion, followed by three acidic stretches containing 25, 25, and 33 glutamic acid or aspartic acid residues. Four potential phosphorylation sites (serines) are also observed in this region. The COOH-terminal proximal portion of the protein carries a glycine-rich region with fairly regularly interspersed phenylalanine and dimethylarginine residues. The two terminal portions of the molecule exhibit unique potential secondary structures: alpha-helix (NH2 terminus) and extended (COOH terminus). The central region exhibits alternating hydrophobic and hydrophilic stretches. Five potential N glycosylation sites are detected. The structure of this protein may reflect two functions in preribosome biogenesis: interaction with chromatin (NH2 terminus) and with preribosomes (COOH terminus).

The occurrence of extended acidic sequences in nonhistone chromosomal proteins

Nonhistone chromosomal proteins and soluble cytoplasmic proteins from rat liver were treated with a combination of proteases and chemical reagents which split a variety of peptide bonds but do not attack sequences consisting predominantly or exclusively of acidic amino acid residues. Analysis of the resulting digests by gel filtration chromatography and column electrophoresis demonstrated that, relative to cytoplasmic proteins, nonhistone chromosomal proteins are rich in highly charged, acidic peptides up to 12 residues in length, but rarely contain very long peptides consisting exclusively of acidic residues such as are found in the nonhistone chromosomal proteins HMG1 and HMG2.

Microheterogeneity of the mammalian high mobility group (HMG) proteins 1 and 2 investigated by reverse-phase high performance liquid chromatography

Microheterogeneity within the high mobility group (HMG)-1 and HMG-2 groups of nonhistone chromatin proteins has been investigated using reverse-phase high-performance liquid chromatography (RP-HPLC) under conditions (acetonitrile elution with 0.1% trifluoroacetic acid (TFA) as the counter ion) which separate proteins primarily on the basis of differences in their overall hydrophobicity. RP-HPLC proved to be a fast and efficient means for separating multiple subspecies of both the HMG-1 and HMG-2 proteins from both crude nuclear extracts and from ion-exchange column "purified" protein samples obtained from different types of mammalian cell nuclei. In crude nuclear extracts at least eight different HMG-2 protein species (two major and six minor), but only one major HMG-1 species, could be resolved by RP-HPLC. Three of the minor HMG-2 protein species could be isolated in "pure" form from crude extracts in one RP-HPLC step whereas under the same conditions the two major HMG-2 peaks (as well as the other minor species) were contaminated with either HMG-1 or HMG-3 (a degradation product of HMG-1). In crude extracts the major HMG-1 fraction always seems to be contaminated with one of the HMG-2 subfractions. RP-HPLC analysis of apparently "pure" protein preparations isolated by ion-exchange chromatography techniques revealed that "pure" HMG-1 can be resolved into at least three different protein species and "pure" HMG-2 into at least four different species. Amino acid analyses of different resolvable forms of the HMG proteins were not inconsistent with the suggestion that at least some of these may be primary sequence variants of the individual proteins, but other possibilities also exist.

Conformation and domain structure of the non-histone chromosomal proteins HMG 1 and 2. Domain interactions

The sequence of the 224 residues of HMG 1 suggests it consists of three domains. We have previously proposed [Cary et al. (1980 Eur. J. Biochem. 131, 367-374] that the A and B domains can fold autonomously and that there is also a small N domain. Several proteases are now found to cut at the end of the B domain (at or close to residue 184). It is shown that the A + B-domain fragment also folds and probably contains all the helix of intact HMG 1. The stability of the B domain is enhanced by the presence of the A domain. The acidic C domain undergoes a coil----helix transition on lowering the pH. Several peptides have been prepared by cleavage at tryptophan. Peptide 57--C-terminus contains complete B and C domains but does not fold. In the absence of the A domain the C domain is thus able to destabilise the B domain. It is concluded that the stability of the B domain in HMG 1 is due to interaction with the A domain and the C domain has a separate function from the other domains.