Nonhistone Chromosomal Proteins Research Articles

Analysis of centromere structure in the fly Megaselia scalaris (Phoridae, Diptera) using CREST sera, anti‐histone antibodies, and a repetitive DNA probe

We have used CREST anti-centromere sera, rabbit anti-histone antibodies, and repetitive DNA analysis to study centromere structure in the fly Megaselia scalaris (Phoridae). In a panel of eight CREST sera, four were positive in immunofluorescence experiments for prekinetochores, ie centromeres in interphase nuclei. The access of the antibodies to CREST antigens may be compromised in the condensed state, since centromeres of prometaphase and metaphase chromosomes remained unstained. When Western blots of embryonic nuclei were probed with these four CREST sera, three of them showed a 17 kDa band. Human CENP-A, likewise recognized by the CREST sera, is a 17 kDa protein. The remaining sera were negative for centromeres although some detected centrosomes and non-histone chromosomal proteins not confined to the centromeres. The use of antibodies generated against histone H4 acetylated at four different sites of the N-terminal domain revealed that heterochromatic regions of M scalaris mitotic chromosomes, ie pericentric and NOR-associated segments, are hyperacetylated. This is at variance with a variety of other systems, where transcriptionally active chromatin is hyperacetylated. Finally, a repetitive 165 base pair fragment was isolated from genomic DNA of the fly and sequenced. An oligonucleotide from this sequence mapped to the centromere region of interphase nuclei and the pericentric regions of condensed chromosomes.

Mutational and Functional Analysis of Dominant SPT2 (SIN1) Suppressor Alleles in Saccharomyces cerevisiae

The Saccharomyces cerevisiae SPT2 gene was identified by genetic screens for mutations which are suppressors of Ty and delta insertional mutations at the HIS4 locus. The ability of spt2 mutations to suppress the transcriptional interference caused by the delta promoter insertion his-4-912 delta correlates with an increase in wild-type HIS4 mRNA levels. The SPT2 gene is identical to SIN1, which codes for a factor genetically defined as a negative regulator of HO transcription. Mutations in SPT2/SIN1 suppress the effects of trans-acting mutations in SWI genes and of partial deletions in the C-terminal domain of the largest subunit of RNA polymerase II. Nuclear localization and protein sequence similarities suggested that the SPT2/SIN1 protein may be related to the nonhistone chromosomal protein HMG1. To assess the significance of this structural similarity and identify domains of SPT2 functionally important in the regulation of his4-912 delta, we have studied recessive and dominant spt2 mutations created by in vitro mutagenesis. We show here that several alleles carrying C-terminal deletions as well as point mutations in the C-terminal domain of the SPT2 protein exhibit a dominant suppressor phenotype. C-terminal basic residues necessary for wild-type SPT2 protein function which are absent from HMG1 have been identified. The competence of these mutant SPT2 proteins to interfere with the maintenance of the His- (Spt+) phenotype of a his4-912 delta SPT2+ strain is lost by deletion of internal HMG1-like sequences and is sensitive to the wild-type SPT2+ gene dosage. Using cross-reacting antipeptide polyclonal antibodies, we demonstrate that the intracellular level of the wild-type SPT2 protein is not affected in presence of dominant mutations and furthermore that the reversion of the dominance by internal deletion of HMG1-like sequences is not mediated by altered production or stability of the mutant polypeptides. Our results suggest that the products of dominant alleles directly compete with the wild-type protein. On the basis of primary sequence similarities, we propose that an HMG-box-like motif is required for SPT2 function in vivo and that this motif also is necessary for the dominant suppressor phenotype exhibited by some mutant SPT2 alleles.

Increased ADP-ribosylation of histones in oral cancer

The involvement of ADP-ribosylation has been investigated by comparing the extent of ADP-ribosylation in two different stages of oral cancer with that of the corresponding normal oral tissue. Poly(ADP-ribose) synthetase(PADPRS), the enzyme that is responsible for this type of posttranslational covalent modification, was assayed first by measuring 14C-ADP-ribose incorporation into different acceptor proteins of the tissue homogenate. The results clearly indicate an increase in PADPRS activity during oral carcinogenesis. After observing this increased pattern in total tissue, further experiments were conducted to check the extent of ADP-ribosylation in purified nuclei. The data of this experiment also indicates a progressive increase in the extent of ADP-ribosylation with increase in malignancy of oral tissue. Further analysis of an ADP-ribosylation of chromosomal proteins indicates that the increased pattern of ADP-ribosylation is mainly attributed to histones and not to non-histone chromosomal proteins. Our investigation suggests that ADP-ribosylation may play a role in oral cancer and may be used as a potential tumour marker.

A heat shock-activated cDNA rescues the recessive lethality of mutations in the heterochromatin-associated protein HP1 of Drosophila melanogaster.

HP1 is a small nonhistone chromosomal protein of Drosophila melanogaster predominantly localized to the pericentric heterochromatin. We have shown previously that mutations in the HP1 coding sequences are associated with dominant suppression of heterochromatic position-effect variegation, and with recessive lethality. When fused to an Hsp70 heat shock gene promoter, the cDNA encoding HP1 supports the heat shock-inducible accumulation of HP1 protein in transgenic flies; this cDNA construct complements the dominant suppression of position-effect variegation associated with mutations in the HP1 gene. Here, we report experiments demonstrating that the heat shock-driven HP1 cDNA is capable of fully rescuing the recessive lethality associated with HP1 mutations in a heat shock-dependent fashion. If heat shock-induced HP1 expression is delayed for as long as 5 days, more than half of the mutant flies still survive until adulthood, consistent with a substantial maternal contribution to embryonic and larval viability. Elevating HP1 levels as late as 7-8 days of development is sufficient to enhance variegation three-fold, suggesting that the extent of heterochromatic position effect can be modified subsequent to the initial appearance of HP1 in the nuclei of syncytial blastoderm embryos.

Mutational and functional analysis of dominant SPT2 (SIN1) suppressor alleles in Saccharomyces cerevisiae.

The Saccharomyces cerevisiae SPT2 gene was identified by genetic screens for mutations which are suppressors of Ty and delta insertional mutations at the HIS4 locus. The ability of spt2 mutations to suppress the transcriptional interference caused by the delta promoter insertion his-4-912 delta correlates with an increase in wild-type HIS4 mRNA levels. The SPT2 gene is identical to SIN1, which codes for a factor genetically defined as a negative regulator of HO transcription. Mutations in SPT2/SIN1 suppress the effects of trans-acting mutations in SWI genes and of partial deletions in the C-terminal domain of the largest subunit of RNA polymerase II. Nuclear localization and protein sequence similarities suggested that the SPT2/SIN1 protein may be related to the nonhistone chromosomal protein HMG1. To assess the significance of this structural similarity and identify domains of SPT2 functionally important in the regulation of his4-912 delta, we have studied recessive and dominant spt2 mutations created by in vitro mutagenesis. We show here that several alleles carrying C-terminal deletions as well as point mutations in the C-terminal domain of the SPT2 protein exhibit a dominant suppressor phenotype. C-terminal basic residues necessary for wild-type SPT2 protein function which are absent from HMG1 have been identified. The competence of these mutant SPT2 proteins to interfere with the maintenance of the His- (Spt+) phenotype of a his4-912 delta SPT2+ strain is lost by deletion of internal HMG1-like sequences and is sensitive to the wild-type SPT2+ gene dosage. Using cross-reacting antipeptide polyclonal antibodies, we demonstrate that the intracellular level of the wild-type SPT2 protein is not affected in presence of dominant mutations and furthermore that the reversion of the dominance by internal deletion of HMG1-like sequences is not mediated by altered production or stability of the mutant polypeptides. Our results suggest that the products of dominant alleles directly compete with the wild-type protein. On the basis of primary sequence similarities, we propose that an HMG-box-like motif is required for SPT2 function in vivo and that this motif also is necessary for the dominant suppressor phenotype exhibited by some mutant SPT2 alleles.

Stimulatory effect of the maize HMGa protein on reporter gene expression in maize protoplasts

The high mobility group (HMG) proteins represent a class of chromosomal non-histone proteins with an assumed influence on transcription. In this context, the effect of the maize HMGa protein on reporter gene expression was examined. Transient co-transformation experiments in maize protoplasts with plasmid constructs directing the synthesis of the maize HMGa protein and with a luciferase reporter plasmid demonstrated a stimulatory effect of the HMGa protein on the reporter gene expression. Additional experiments with HMGa deletion constructs indicated that the HMG-Box DNA-binding motif is important for the observed effect, while the acidic carboxy-terminal domain of the HMGa protein appears to be dispensable.

Chromosome structure inside the nucleus

Recent in situ three-dimensional structural studies have provided a new model for the 30 nm chromatin fiber. In addition, research during the past year has revealed some of the molecular complexity of non-histone chromosomal proteins. Still to come is the unification of molecular insights with chromosomal architecture.

Isolation by a New Method and Sequence Analysis of Chromosomal HMG-17 Protein from Porcine Thymus

Nonhistone chromosomal protein HMG-17 from porcine thymus has been isolated by extraction in boiling water, gel filtration and HPLC, and its complete primary structure (89 residues) has been determined. Peptides derived from enzymatic hydrolysis with trypsin, Staphylococcus aureus V-8 protease, Arg-C, and Glu-C proteinases were purified by HPLC and sequenced by the 4-(N,N-dimethylamino)azobenzene-4′- isothiocyanate/phenylisothiocyanate double coupling method. Porcine HMG-17 has a molecular mass of 9248 Da and a pI > 9.8. No glycosylation or methylation has been detected. The primary structure of this protein is almost identical to the sequence deduced from a cDNA clone derived from a human cell line. Porcine thymus HMG-17 differs from the human protein by only a single conservative substitution at position 64 (aspartic acid instead of glutamic acid). As in other HMG-17 proteins, the sequence is characterized by a lysine- and proline-rich central region, which has been implicated in DNA binding.

A cytogenetic analysis of chromosomal region 31 of Drosophila melanogaster.

Cytogenetic region 31 of the second chromosome of Drosophila melanogaster was screened for recessive lethal mutations. One hundred and thirty nine new recessive lethal alleles were isolated that fail to complement Df(2L)J2 (31A-32A). These new alleles, combined with preexisting mutations in the region, define 52 complementation groups, 35 of which have not previously been described. Among the new mutations were alleles of the cdc2 and mfs(2)31 genes. Six new deficiencies were also isolated and characterized identifying 16 deficiency subintervals within region 31. The new deficiencies were used to further localize three loci believed to encode non-histone chromosomal proteins. Suvar(2)1/Su(var)214, a dominant suppressor of position-effect variegation (PEV), maps to 31A-B, while the recessive suppressors of PEV mfs(2)31 and wdl were localized to regions 31E and 31F-32A, respectively. In addition, the cytological position of several mutations that interact with heterochromatin were more precisely defined.

Purification and properties of a cruciform DNA binding protein fromUstilago maydis

A DNA binding protein with an M(r) of 11,000 was purified from Ustilago maydis. Its solubility in acid, amino acid composition, and mobility during gel electrophoresis are reminiscent of properties observed for the high mobility group nonhistone chromosomal proteins. The protein recognizes cruciform DNA made from oligonucleotides and also binds preferentially to a plasmid containing an extruded cruciform.

The gene encoding chicken chromosomal protein HMG-14a is transcribed into multiple mRNAs

The sequence and structure of the chicken HMG14a gene encoding HMG-14a non-histone chromosomal protein suggest that it may be a unique member of the HMG (high mobility group) gene family with properties intermediate to those of the typical HMG-14 and HMG-17 genes. Genomic clones were isolated which together contain the complete chicken HMG-14a gene. The gene covers about 10kb while coding for an mRNA of about 1000 nt in size. Primer extension, S1 mapping and further cDNA clone analysis suggest that HMG-14a codes for multiple mRNAs arising from two or more transcription start points with alternative splicing and utilization of two or more polyadenylation sites. However, no variation in the coding portion of the mRNA has been observed. The sequence of the promoter region of HMG-14a is similar to that of chicken HMG-14b and human HMG-14 in that it is very G + C rich, contains several putative Spl-binding sequences and has an unusually high density of CpG dinucleotides. Expression studies confirm earlier results suggesting that the gene is expressed at low levels in most tissue types.

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.

Identification and genetic mapping of the murine gene and 20 related sequences encoding chromosomal protein HMG-17

HMG-17 is an abundant, nonhistone chromosomal protein that binds preferentially to nucleosomal core particles of mammalian chromatin. The human gene for HMG-17 has been localized to Chromosome (Chr) 1p, but the murine gene has not been previously mapped. Here we identify the murine functional gene, Hmg17, from among more than 25 related sequences (probably processed pseudogenes) and show that it is located on mouse Chr 4, in a region known to have conserved linkage relationships with human Chr 1p. We also report the map locations of 20 additional Hmg17-related sequences on mouse Chrs 1, 2, 3, 5, 7, 8, 9, 13, 15, 16, 17, 18, and X. The multiple, dispersed members of the Hmg17 multigene family can be detected efficiently with a single cDNA probe and provide useful markers for genetic mapping studies in mice.

Cooperative binding of the Xenopus RNA polymerase I transcription factor xUBF to repetitive ribosomal gene enhancers.

Upstream binding factor (UBF) is a DNA-binding transcription factor implicated in ribosomal gene promoter and enhancer function in vertebrates. UBF is unusual in that it has multiple DNA-binding domains with homology to high-mobility-group (HMG) nonhistone chromosomal proteins 1 and 2. However, a recognizable DNA consensus sequence for UBF binding is lacking. In this study, we have used gel retardation and DNase I footprinting to examine Xenopus UBF (xUBF) binding to Xenopus laevis ribosomal gene enhancers. We show that UBF has a minimum requirement for about 60 bp of DNA, the size of the short enhancer variant in X. laevis. Stronger UBF binding occurs on the longer enhancer variant (81 bp) and on multiple enhancers linked head to tail. In vivo, Xenopus ribosomal gene enhancers exist in blocks of 10 alternating 60- and 81-bp repeats within the intergenic spacer. In vitro, UBF binds cooperatively to probes with 10 enhancers, with five intermediate complexes observed in titration experiments. This suggests that, on average, one UBF dimer binds every two enhancers. A single UBF dimer can produce a DNase I footprint ranging in size from approximately 30 to about 115 bp on enhancer probes of different lengths. This observation is consistent with the hypothesis that multiple DNA-binding domains or subdomains within UBF bind independently, forming more-stable interactions on longer probes.

Cooperative binding of the Xenopus RNA polymerase I transcription factor xUBF to repetitive ribosomal gene enhancers.

Upstream binding factor (UBF) is a DNA-binding transcription factor implicated in ribosomal gene promoter and enhancer function in vertebrates. UBF is unusual in that it has multiple DNA-binding domains with homology to high-mobility-group (HMG) nonhistone chromosomal proteins 1 and 2. However, a recognizable DNA consensus sequence for UBF binding is lacking. In this study, we have used gel retardation and DNase I footprinting to examine Xenopus UBF (xUBF) binding to Xenopus laevis ribosomal gene enhancers. We show that UBF has a minimum requirement for about 60 bp of DNA, the size of the short enhancer variant in X. laevis. Stronger UBF binding occurs on the longer enhancer variant (81 bp) and on multiple enhancers linked head to tail. In vivo, Xenopus ribosomal gene enhancers exist in blocks of 10 alternating 60- and 81-bp repeats within the intergenic spacer. In vitro, UBF binds cooperatively to probes with 10 enhancers, with five intermediate complexes observed in titration experiments. This suggests that, on average, one UBF dimer binds every two enhancers. A single UBF dimer can produce a DNase I footprint ranging in size from approximately 30 to about 115 bp on enhancer probes of different lengths. This observation is consistent with the hypothesis that multiple DNA-binding domains or subdomains within UBF bind independently, forming more-stable interactions on longer probes.

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.

Growth factor-induced delayed early response genes.

Growth factors induce the sequential expression of cellular genes whose products are thought to mediate long-term responses to the growth factors. In mouse 3T3 fibroblastic cells, the first genes to be expressed (immediate-early genes) are activated within minutes after the addition of platelet-derived growth factor, fibroblast growth factor, or serum. By cDNA cloning, we have identified genes that are activated after a delay of a few hours and several hours prior to serum-induced DNA replication. Activation of these delayed early response genes requires new protein synthesis, presumably the synthesis of immediate-early transcription factors described previously. Partial or complete sequencing of 13 different delayed early cDNAs, representing about 40% of the 650 primary cDNA isolates, revealed that 8 were related to known gene sequences and 5 were not. Among the former are cDNAs encoding nonhistone chromosomal proteins [HMGI(Y) and HMGI-C], adenine phosphoribosyltransferase (APRT), a protein related to human macrophage migration inhibitory factor (MIF), a protein of the major intrinsic protein (MIP) family homologous to the integral membrane protein of human erythrocytes, and cyclin CYL1. In 3T3 cells, the delayed early gene response to growth factors appears to be at least as complex as the immediate-early gene response previously described.

Growth factor-induced delayed early response genes.

Growth factors induce the sequential expression of cellular genes whose products are thought to mediate long-term responses to the growth factors. In mouse 3T3 fibroblastic cells, the first genes to be expressed (immediate-early genes) are activated within minutes after the addition of platelet-derived growth factor, fibroblast growth factor, or serum. By cDNA cloning, we have identified genes that are activated after a delay of a few hours and several hours prior to serum-induced DNA replication. Activation of these delayed early response genes requires new protein synthesis, presumably the synthesis of immediate-early transcription factors described previously. Partial or complete sequencing of 13 different delayed early cDNAs, representing about 40% of the 650 primary cDNA isolates, revealed that 8 were related to known gene sequences and 5 were not. Among the former are cDNAs encoding nonhistone chromosomal proteins [HMGI(Y) and HMGI-C], adenine phosphoribosyltransferase (APRT), a protein related to human macrophage migration inhibitory factor (MIF), a protein of the major intrinsic protein (MIP) family homologous to the integral membrane protein of human erythrocytes, and cyclin CYL1. In 3T3 cells, the delayed early gene response to growth factors appears to be at least as complex as the immediate-early gene response previously described.

Analysis of Polypeptides Associated with Shoot Formation in Tobacco Callus Cultures

Callus lines of Nicotiana tabacum were selected for competence and lack of competence in shoot formation. Changes in total and chromosomal polypeptides in these shoot-forming and nonshoot-forming tobacco cultures were examined by twodimensional polyacrylamide gel electrophoresis. Qualitative and quantitative differences in total, nonhistone chromosomal, and basic chromosomal polypeptides were evident throughout the 7-d test period. The analysis of total proteins identified polypeptides specific to shoot-forming and nonshoot-forming tissue during the 7-d sampling period. A small number of basic chromosomal proteins were found solely in shoot-forming or nonshoot-forming tissue. One basic chromosomal protein was detected in only nonshoot-forming tissue at all sampling times. Two proteins, although present in shoot-forming tissue, were present at elevated levels in the nonshoot-forming cultures. No temporal changes in basic proteins over the 7-d incubation period were observed. Qualitative differences in total nonhistone chromosomal polypeptides in the shoot-forming and nonshoot-forming tissue were also observed. Differences in chromosomal polypeptides were observed. In contrast to the basic chromosomal proteins, temporal variation in the nonhistone chromosomal polypeptides was demonstrated. Throughout the 7-d sampling period, 29 and 12 nonhistone chromosomal polypeptides varied qualitatively in shoot-forming and nonshoot-forming callus cultures, respectively. In vitro labeling with 32P-orthophosphate indicated that approximately 1.0% and 0.3% of the nonhistone chromosomal proteins were phosphorylated in the shoot-forming and nonshoot-forming cultures. Of these phosphorylated polypeptides, one was present in nonshoot-forming tissue and three were detected only in the shoot-forming tissue. Phosphorylation occurred at serine or threonine residues.

ANALYSIS OF POLYPEPTIDES ASSOCIATED WITH SHOOT FORMATION IN TOBACCO CALLUS CULTURES

Callus lines of Nicotiana tabacum were selected for competence and lack of competence in shoot formation. Changes in total and chromosomal polypeptides in these shoot-forming and nonshoot-forming tobacco cultures were examined by twodimensional polyacrylamide gel electrophoresis. Qualitative and quantitative differences in total, nonhistone chromosomal, and basic chromosomal polypeptides were evident throughout the 7-d test period. The analysis of total proteins identified polypeptides specific to shoot-forming and nonshoot-forming tissue during the 7-d sampling period. A small number of basic chromosomal proteins were found solely in shoot-forming or nonshoot-forming tissue. One basic chromosomal protein was detected in only nonshoot-forming tissue at all sampling times. Two proteins, although present in shoot-forming tissue, were present at elevated levels in the nonshoot-forming cultures. No temporal changes in basic proteins over the 7-d incubation period were observed. Qualitative differences in total nonhistone chromosomal polypeptides in the shoot-forming and nonshoot-forming tissue were also observed. Differences in chromosomal polypeptides were observed. In contrast to the basic chromosomal proteins, temporal variation in the nonhistone chromosomal polypeptides was demonstrated. Throughout the 7-d sampling period, 29 and 12 nonhistone chromosomal polypeptides varied qualitatively in shoot-forming and nonshoot-forming callus cultures, respectively. In vitro labeling with 32P-orthophosphate indicated that approximately 1.0% and 0.3% of the nonhistone chromosomal proteins were phosphorylated in the shoot-forming and nonshoot-forming cultures. Of these phosphorylated polypeptides, one was present in nonshoot-forming tissue and three were detected only in the shoot-forming tissue. Phosphorylation occurred at serine or threonine residues.