Histone H1 genes and histone gene clusters in the genus Drosophila.

Whereas the genomes of many organisms contain several nonallelic types of linker histone genes, one single histone H1 type is known in Drosophila melanogaster that occurs in about 100 copies per genome. Amplification of H1 gene sequences from genomic DNA of wild type strains of D. melanogaster from Oregon, Australia, and central Africa yielded numerous clones that all exhibited restriction patterns identical to each other and to those of the known H1 gene sequence. Nucleotide sequences encoding the evolutionarily variable domains of H1 were determined in two gene copies of strain Niamey from central Africa and were found to be identical to the known H1 sequence. Most likely therefore, the translated sequences of D. melanogaster H1 genes do not exhibit intragenomic or intergenomic variations. In contrast, three different histone H1 genes were isolated from D. virilis and found to encode proteins that differ remarkably from each other and from the H1 of D. melanogaster and D. hydei. About 40 copies of H1 genes are organized in the D. virilis genome with copies of core histone genes in gene quintets that were found to be located in band 25F of chromosome 2. Another type of histone gene cluster is present in about 15 copies per genome and contains a variable intergenic sequence instead of an H1 gene. The H1 heterogeneity in D. virilis may have arisen from higher recombination rates than occur near the H1 locus in D. melanogaster and might provide a basis for formation of different chromatin subtypes.

The histone H1 genes of the dipteran insect, Chironomus thummi, fall under two divergent classes and encode proteins with distinct intranuclear distribution and potentially different functions.

Four histone H1 genes of the midge, Chironomus thummi piger, and three H1 genes of the subspecies C. thummi thummi have been cloned and assigned to the four different H1 proteins from C. thummi larvae. Together with an earlier cloned H1 gene from C. thummi thummi [Hankeln, T. & Schmidt, E. R. (1991) Chromosoma 101, 25-31], these genes probably constitute the complete complement of H1 genes in both subspecies. They were found to fall under two classes that differ remarkably in their gene copy numbers, genomic organization, structure of flanking sequences, codon usage, and expression during embryonic development, and that encode H1 proteins of divergent structure. Histone H1 I-1 contains an inserted sequence, KAPKAPKAPKSPKAE in C. thummi piger, and KAPKAPKSPKAE in C. thummi thummi, that is lacking in the other H1 variants, H1 II-1, H1 II-2, and H1 III-1. In the immediate neighbourhood to the inserted sequence, a substitution in the H1 I-1 protein sequence dramatically enhances the potential to form a reversed turn. In early development, H1 I-1 is expressed at a higher rate than the other H1 genes. The transcripts have a size of about 1 kb; in addition, the H1 I-1 gene exhibited two minor transcripts of about 2.5 and > 3 kb size in middle blastoderm that are possibly polyadenylated. Together with our earlier finding that histone H1 I-1 is found in a limited number of polytene chromosome bands whereas the other H1 histones are uniformly distributed in chromatin, these results intimate functional differences between the two classes of H1 genes and their products.

Structural and functional properties of linker histones and high mobility group proteins in polytene chromosomes.

Variants of histone H1 and high mobility group (HMG) proteins and their genes in Dipteran insects are being studied in our laboratory and have revealed different properties of DNA binding and intrachromosomal distribution. One of the H1 variants of Chironomus is found only in a minority of polytene chromosome bands and differs from the other H1 proteins of the same organism by genomic organization and by an inserted structural motif, the KAPKAP repeat, that is present also in single H1 variants of other, evolutionarily remote organisms. NH2-terminal peptides containing the KAPKAP repeat were found in vitro to interact with DNA, whereas no DNA interaction was observed with the homologous peptide of another H1 variant that does not contain the inserted KAPKAP repeat. We assume that H1 variants containing the KAP motif may interact with a stretch of linker DNA and package chromatin more tightly than other H1 variants. A large series of antibodies directed against different sites in all regions of the H1 molecule is being applied in studying the sites of interaction of the H1 molecule with other molecules in interphase chromatin in terms of antibody epitope accessibility. A search for insect proteins that share properties of the mammalian HMG proteins resulted in isolation and sequencing of two different HMG1 proteins and an HMGI protein. The HMG1 protein of the midge, Chironomus tentans, show a differential distribution in chromosomes. The more abundant cHMG1a protein appears uniformly distributed, whereas the less abundant cHMG1b protein could be localized only in chromosomal puffs. This strongly indicates that these highly similar proteins have different functions in chromatin. The Chironomus HMGI protein and the intron/exon organization of its gene were found to be very similar to human HMGI/Y proteins that are highly abundant in rapidly proliferating cells. Common properties of HMG1 and HMGI proteins include high affinity interaction with AT-rich DNA, irregular DNA structures, and the capacity to bend DNA. These properties suggest that the HMG proteins may have an architectural role in assembling different types of chromatin.

Selective distribution of histone H1 variants and high mobility group proteins in chromosomes.

Recent results on the differential distribution of sequence variants of histone H1, of proteins of the HMG 1/2 family, and of HMG1 in polytene chromosomes are reviewed. Several organisms are known to contain two different HMG 1/2 proteins. In Chironomus, one of them is restricted to decondensed puffs and may have a specific function. One of the H1 variants of Chironomus is found only in a minority of chromosome bands and differs from the other H1 proteins of the organism by genomic organization and by an inserted structural motif that is also present in single H1 variants of other organisms.

Structurally divergent histone H1 variants in chromosomes containing highly condensed interphase chromatin.

Condensed and late-replicating interphase chromatin in the Dipertan insect Chironomus contains a divergent type of histone H1 with an inserted KAP-KAP repeat that is conserved in single H1 variants of Caenorhabditis elegans and Volvox carteri. H1 peptides comprising the insertion interact specifically with DNA. The Chironomid Glyptotendipes exhibits a corresponding correlation between the presence of condensed chromosome sections and the appearance of a divergent H1 subtype. The centromere regions and other sections of Glyptotendipes barbipes chromosomes are inaccessible to immunodecoration by anti-H2B and anti-H1 antibodies one of which is known to recognize nine different epitopes in all domains of the H1 molecule. Microelectrophoresis of the histones from manually isolated unfixed centromeres revealed the presence of H1 and core histones. H1 genes of G. barpipes were sequenced and found to belong to two groups. H1 II and H1 III are rather similar but differ remarkably from H1 I. About 30% of the deduced amino acid residues were found to be unique to H1 I. Most conspicuous is the insertion, SPAKSPGR, in H1 I that is lacking in H1 II and H1 III and at its position gives rise to the sequence repeat SPAKSPAKSPGR. The homologous H1 I gene in Glyptotendipes salinus encodes the very similar repeat TPAKSPAKSPGR. Both sequences are structurally related to the KAPKAP repeat in H1 I-1 specific for condensed chromosome sites in Chironomus and to the SPKKSPKK repeat in sea urchin sperm H1, lie at almost the same distance from the central globular domain, and could interact with linker DNA in packaging condensed chromatin.

Structural and functional differences between histone H1 sequence variants with differential intranuclear distribution.

The chromatin of most cell types contains several different sequence variants of histone H1. The functional role of this heterogeneity is not known. In the larval tissues of the midge, Chironomus thummi, there are H1 variants of two types. H1 II-1, H1 II-2, and H1 III-1 have similar amino acid sequences and appear uniformly distributed in polytene interphase chromosomes. The total number of gene copies per genome for this type of H1 histones is about 40 in C. th. thummi and 50-60 in C. th. piger. In contrast, histone H1 I-1 is encoded by a single copy gene in C. th. thummi and by two to four genes in C. th. piger. It has a divergent structure and is found only in a limited number of condensed chromosome sites. The N-terminal domain of H1 I-1 contains an insertion that is lacking in the other H1 variants and that is part of a variant-specific bipartite sequence Lys-Ala-Pro-Lys-Ala-Pro-Xaa10-Lys-Val-Ala in front of the conserved central domain. N-terminal peptides of H1 I-1 including this motif, in contrast to the homologous peptide from H1 II-1, competed with the drug Hoechst 33258 for binding to the minor groove of the DNA double helix. Repeats of the sequence Lys-Ala-Pro are also present at the same distance from the conserved central domain, in a single H1 variant of a nematode and of a green alga. The motif could interact with linker DNA in intranuclear targeting or packaging a condensed subtype of chromatin, or both.

Presence of histone H1 on an active Balbiani ring gene.

We have investigated whether histone H1 is present on active Balbiani ring genes in the salivary glands of Chironomus tentans using immunoelectron microscopy. The genes were studied in two activity states: maximally activated genes with a fully extended template and repressed genes in a 30 nm fiber conformation. Histone H1 was recorded on the gene in both conformations; the immunosignal was considerably stronger in the transcriptionally active state, probably reflecting the increased accessibility of histone H1 to the antibody in unfolded versus compacted chromatin. We conclude that during transcription the DNA template is extended and the nucleosomes are disrupted at the RNA polymerases, but histone H1, and most likely also the core histones, remains bound to the template.

Histone H1 in two subspecies of Chironomus thummi with different genome sizes: homologous chromosome sites differ largely in their content of a specific H1 variant.

Chromatin of Chironomus thummi (Diptera) contains seven sequence variants of histone H1. A structurally divergent H1, variant I-1, accounts for about 20% of the total H1 in C. th. piger and for about 30% in C. th. thummi. Monoclonal antibodies against this protein have been induced and have revealed its restriction to the centromeres and to a limited number of other bands in the salivary gland chromosomes. Indirect immunofluorescence of the somatically paired homologous chromosomes of F1 hybrids indicates that the difference between the two subspecies in H1 I-1 content largely depends on differences situated at a number of distinct homologous chromosome bands. These bands were intensely decorated by antibodies against H1 I-1 in C. th. thummi but appeared virtually black in C. th. piger. The same bands, however, were decorated equally in both subspecies by an antibody that reacts with other H1 variants but does not recognize H1 I-1 and by a polyclonal anti-H1 antibody. The results suggest that H1 variant I-1 is characteristic of a specific type of chromatin that is confined to distinct chromosome segments and that is more frequent in the subspecies C. th. thummi, which has a 27% larger genome.

Histone H1 heterogeneity in the midge, Chironomus thummi. Structural comparison of the H1 variants in an organism where their intrachromosomal localization is possible.

1. Seven subfractions of histone H1 have been isolated and purified from larvae of Chironomus thummi (Diptera). They have been denominated I-1, II-1, II-2, II-3, III-1, III-2, and III-3, according to the order of migration in two steps of preparative electrophoresis. 2. The amino acid compositions are similar to those of other H1 histones. Subfractions I-1 and II-1 were found to contain one methionine and two tyrosine residues, II-2 contained two methionine and three tyrosine residues, and III-1 one methionine and three tyrosine residues. The other subfractions contained one or two methionine and two or three tyrosine residues. For subfractions I-1 and II-1 a chain length of about 252 amino acids was estimated. 3. Peptide pattern analyses after chemical cleavage at the methionine and tyrosine residues, and enzymatic cleavage with thrombin and chymotrypsin, respectively, showed that all subfractions have different individual primary structures. A comparison of peptide sizes and of the positions in the peptide patterns of epitopes recognized by monoclonal antibodies was made to check whether some of the subfractions could arise by proteolytic degradation of others. This possibility can be excluded for five of the subfractions and is very improbable for the two others. Treatment of C. thummi H1 with alkaline phosphatase did not change the pattern of subfractions, while the phosphorylated subfraction of histone H2A disappeared after this treatment. Most and very probably all subfractions are thus H1 sequence variants. 4. Inbred strains and individual larvae of C. thummi were found to comprise all seven variants. The H1 heterogeneity can therefore not be due to allelic polymorphism. Salivary gland nuclei were found to contain variant I-1 and at least some of the other variants. 5. H1 from Drosophila melanogaster and from calf thymus were used as reference molecules in all cleavage experiments and yielded the peptide patterns expected from the sequence. The comparison discriminates the group of C. thummi H1 histones clearly from Drosophila and calf thymus H1. Limited trypsin digestion yielded a protected peptide of uniform size in six of the seven variants which was considerably smaller than the protected central domain of calf thymus H1. 6. Two other species of Chironomidae, C. pallidivittatus and Glyptotendipes barbipes were found to contain five and three H1 subfractions, respectively.(ABSTRACT TRUNCATED AT 400 WORDS)

A blotting procedure which preserves specific protein-DNA interactions.

A quick, quantitative, and nonselective electrophoretic transfer of proteins from acetic acid-urea gels onto nitrocellulose, which preserves their ability to interact specifically with DNA, is achieved when exposure to dodecyl sulfate ions is avoided and a special type of nitrocellulose is used which contains cellulose phosphate ester. Filter-adsorbed histone H1 and other nuclear proteins from an insect, Chironomus thummi, were tested for binding of an AT-rich DNA sequence from the heterochromatin of the same organism under competitive conditions. On the blots, histone H1 exhibited the dependency of DNA binding on NaCl concentration and the preference for AT-rich DNA or poly[d(A-T)] found in quantitative filter-binding studies. By stepwise alteration of the NaCl molarity and competing Escherichia coli DNA concentration, respectively, in the binding buffer, two minor protein fractions could be identified in the heterogeneous extracts, one of which bound preferentially to AT-rich DNA, and the other bound to this sequence at up to 500 mM NaCl. Exposure to dodecyl sulfate led to a disappearance of the ability of these proteins to interact specifically with DNA. While nondenaturing transfer by diffusion (L. Levinger and A. Varshavsky (1982) Proc. Natl. Acad. Sci. USA 79, 7152) is a procedure that requires about 2 days, the present technique of gentle protein transfer for DNA binding studies requires only 2 to 3 h.

Localization of nuclear proteins related to high mobility group protein 14 (HMG 14) in polytene chromosomes.

An antibody was raised against "high mobility group" nuclear protein 14 (HMG 14) from calf thymus, known to be associated with actively transcribed chromatin. By means of indirect immunofluorescence, it was shown to react with the nuclei of mouse fibroblasts and of brain cells from Xenopus and Drosophila, but not of Xenopus erythrocytes. The antibody was used to detect immunologically related proteins in giant chromosomes of the midge, Chironomus pallidivittatus. Indirect immunofluorescence with anti-HMG 14 antibody in polytene nuclei was restricted to the active puffs. Giant puffs (Balbiani rings) exhibited especially intense fluorescence in their peripheral regions. An inducible puff site, the Balbiani ring 6 locus, showed no reaction with the antibody prior to induction. When puff formation began, the chromosome site assumed a very intense fluorescence, which disappeared again when the Balbiani ring was recondensed. - Protein extracts of salivary gland nuclei were found on immunoblots to contain one major protein fraction that reacted with the anti-HMG 14 antibody. The electrophoretic mobility of this fraction was similar to that of calf thymus HMG 17. - It is concluded that actively transcribed puffs in polytene chromosomes contain HMG 14-related protein(s) that are not present in potentially active gene loci prior to induction.

Transplantation of insect giant chromosome nuclei into amphibian oocytes.

Polytene salivary gland nuclei of Chironomus pallidivittatus were transplanted into oocytes of Xenopus laevis which were then cultured in vitro for 18 h. The giant chromosomes and nucleoli as well as the entire nuclei enlarged considerably in volume during this time. The polyteny and specific chromomere pattern of the chromosomes were maintained, and the puffing of the salivary gland-specific Balbiani rings was not noticeably changed. - Polytene nuclei from differentiated insect cells transplanted into Xenopus oocytes thus appear suited for exposing giant chromosomes in vivo to purified factors such as regulatory molecules.