Locations of chromosomal proteins in polytene chromosomes

Lysine 27 dimethylation of Drosophila linker histone dH1 contributes to heterochromatin organization independently of H3K9 methylation

Post-translational modifications (PTMs) of core histones are important epigenetic determinants that correlate with functional chromatin states. However, despite multiple linker histone H1s PTMs have been identified, little is known about their genomic distribution and contribution to the epigenetic regulation of chromatin. Here, we address this question in Drosophila that encodes a single somatic linker histone, dH1. We previously reported that dH1 is dimethylated at K27 (dH1K27me2). Here, we show that dH1K27me2 is a major PTM of Drosophila heterochromatin. At mitosis, dH1K27me2 accumulates at pericentromeric heterochromatin, while, in interphase, it is also detected at intercalary heterochromatin. ChIPseq experiments show that >98% of dH1K27me2 enriched regions map to heterochromatic repetitive DNA elements, including transposable elements, simple DNA repeats and satellite DNAs. Moreover, expression of a mutated dH1K27A form, which impairs dH1K27me2, alters heterochromatin organization, upregulates expression of heterochromatic transposable elements and results in the accumulation of RNA:DNA hybrids (R-loops) in heterochromatin, without affecting H3K9 methylation and HP1a binding. The pattern of dH1K27me2 is H3K9 methylation independent, as it is equally detected in flies carrying a H3K9R mutation, and is not affected by depletion of Su(var)3-9, HP1a or Su(var)4-20. Altogether these results suggest that dH1K27me2 contributes to heterochromatin organization independently of H3K9 methylation.

Concanavalin A binds to puffs in polytene chromosomes

CHANGES in transcriptional activity at defined loci are often correlated with significant local structural changes in the genome(1), and in polytene chromosomes, such changes are thought to be associated with compositional or conformational changes in the protein complement at these particular bands(2,3). Thus, various studies on Balfoiani rings and specific 'puffs' in such chromosomes are useful for elucidating the role of defined chromosomal components in both chromosome structure and gene activity. Such studies require specific probes which will allow in situ localisation of a chromosomal component during the various stages of puffing. Antibodies specific to purified histone fractions(4-7), HMG proteins(8), RNA polymerase(9) and non-histone protein subfractions(10) have been used in studies on chromatin and chromosome structure. We reported previously that concanavalin A (Con A) specifically binds to three types of non-histone proteins present in chromatin purified from rat liver nuclei and suggested that derivatives of Con A might serve as specific probes to study the in situ organisation of these non-histone proteins(11). We have now reacted fluorescein-labelled Con A with polytene chromosomes isolated from different developmental stages of Chironomus thummi and visualised the location of the bound Con A by fluorescence microscopy. We observed that the fluorescent lectin, which has an affinity for glucose- and mannose-containing molecules, specifically bound to the transcriptionally active regions of chromosome IV. The extent of binding of Con A to the Balbiani rings present in regions b and c of chromosome IV is proportional to the size of the respective ring. Our results indicate that glucose- or mannose-containing molecules are present in these Balbiani rings and that the availability of these sugars to interact with Con A can be correlated with the developmental stage of a puff. We suggest that lectins can be useful cytological tools with which to study the in situ organisation of defined chromosomal components during various functional states of the genome.

Drosophila D1 overexpression induces ectopic pairing of polytene chromosomes and is deleterious to development

Eukaryotic genomes function in the context of chromatin, but the roles of most nonhistone chromosomal proteins are far from understood. The D1 protein of Drosophila is an example of a chromosomal protein that has been fairly well characterized biochemically, but has nevertheless eluded functional description. To this end, we have undertaken a gain-of-function genetical analysis of D1, utilizing the GAL4-UAS system. We determined that ubiquitous overexpression of D1 using the Act5C- or tubP-GAL4 drivers was lethal to the organism during larval growth. We also ectopically expressed D1 in a tissue-limited manner using other GAL4 drivers. In general, ectopic D1 was observed to inhibit differentiation and/or development. We observed effects on pattern formation of the adult eye, bristle morphogenesis, and spermatogenesis. These phenotypes may be the consequence of misregulation of D1 target genes. A surprising result was obtained when D1 was overexpressed in the third instar salivary gland. The polytene chromosomes exhibited numerous ectopic associations such that spreading of the chromosome arms was precluded. We mapped the sites of ectopic pairing along the polytene chromosome arms, and found a correlation with sites of intercalary heterochromatin. We speculate that these sites comprise the natural targets of D1 protein activity and that D1 is involved in the ectopic pairing observed for wild-type chromosomes. Together, our data suggest that D1 may influence multiple biochemical activities within the nucleus.

The multi-AT-hook chromosomal protein of Drosophila melanogaster, D1, is dispensable for viability

The D1 protein is a high mobility group A (HMGA)-like nonhistone chromosomal protein with primary localization to certain AT-rich satellite DNA sequences within heterochromatin. The binding of D1 to euchromatic sequences is less studied and the functional significance of its chromosomal associations is unclear. By taking advantage of existing P-insertion alleles of the D1 gene, I generated D1 null mutations to investigate the phenotypic effect of loss of the D1 gene. In contrast to a previous report, I determined that the D1 gene is not essential for viability of Drosophila melanogaster, and moreover, that loss of D1 has no obvious phenotypic effects. My tests for an effect of D1 mutations on PEV revealed that it is not a suppressor of variegation, as concluded by other investigators. In fact, the consequence of loss of D1 on one of six variegating rearrangements tested, T(2;3)Sb(V), was dominant enhancement of PEV, suggesting a role for the protein in euchromatic chromatin structure and/or transcription. A study of D1 protein sequence conservation highlighted features shared with mammalian HMGA proteins, which function as architectural transcription factors.

Drosophila PIWI associates with chromatin and interacts directly with HP1a

The interface between cellular systems involving small noncoding RNAs and epigenetic change remains largely unexplored in metazoans. RNA-induced silencing systems have the potential to target particular regions of the genome for epigenetic change by locating specific sequences and recruiting chromatin modifiers. Noting that several genes encoding RNA silencing components have been implicated in epigenetic regulation in Drosophila, we sought a direct link between the RNA silencing system and heterochromatin components. Here we show that PIWI, an ARGONAUTE/PIWI protein family member that binds to Piwi-interacting RNAs (piRNAs), strongly and specifically interacts with heterochromatin protein 1a (HP1a), a central player in heterochromatic gene silencing. The HP1a dimer binds a PxVxL-type motif in the N-terminal domain of PIWI. This motif is required in fruit flies for normal silencing of transgenes embedded in heterochromatin. We also demonstrate that PIWI, like HP1a, is itself a chromatin-associated protein whose distribution in polytene chromosomes overlaps with HP1a and appears to be RNA dependent. These findings implicate a direct interaction between the PIWI-mediated small RNA mechanism and heterochromatin-forming pathways in determining the epigenetic state of the fly genome.

The AT-hook protein D1 is essential for Drosophila melanogaster development and is implicated in position-effect variegation

We have analyzed the expression pattern of the D1 gene and the localization of its product, the AT hook-bearing nonhistone chromosomal protein D1, during Drosophila melanogaster development. D1 mRNAs and protein are maternally contributed, and the protein localizes to discrete foci on the chromosomes of early embryos. These foci correspond to 1.672- and 1.688-g/cm(3) AT-rich satellite repeats found in the centromeric heterochromatin of the X and Y chromosomes and on chromosomes 3 and 4. D1 mRNA levels subsequently decrease throughout later development, followed by the accumulation of the D1 protein in adult gonads, where two distributions of D1 can be correlated to different states of gene activity. We show that the EP473 mutation, a P-element insertion upstream of D1 coding sequences, affects the expression of the D1 gene and results in an embryonic homozygous lethal phenotype correlated with the depletion of D1 protein during embryogenesis. Remarkably, decreased levels of D1 mRNA and protein in heterozygous flies lead to the suppression of position-effect variegation (PEV) of the white gene in the white-mottled (w(m4h)) X-chromosome inversion. Our results identify D1 as a DNA-binding protein of known sequence specificity implicated in PEV. D1 is the primary factor that binds the centromeric 1.688-g/cm(3) satellite repeats which are likely involved in white-mottled variegation. We propose that the AT-hook D1 protein nucleates heterochromatin assembly by recruiting specialized transcriptional repressors and/or proteins involved in chromosome condensation.

Association of individual hnRNP proteins and snRNPs with nascent transcripts

As they are transcribed, RNA polymerase II transcripts (hnRNAs or pre-mRNAs) associate with hnRNP proteins and snRNP particles, and the processing of pre-mRNA occurs within these ribonucleoprotein complexes. To better understand the relationship between hnRNP proteins and snRNP particles and their roles in mRNA formation, we have visualized them as they associate with nascent transcripts on the polytene chromosomes of Drosophila melanogaster salivary glands. Simultaneous pairwise detection of the abundant hnRNP proteins hrp36, hrp40, and hrp48 by direct double-label immunofluorescence microscopy reveals all of these proteins are bound to most transcripts, but their relative amounts on different transcripts are not fixed. Numerous differences in the relative amounts of snRNP particles and hnRNP proteins on nascent transcripts are also observed. These observations directly demonstrate that individual hnRNP proteins and snRNP particles are differentially associated with nascent transcripts and suggest that different pre-mRNAs bind different combinations of these factors to form transcript-specific, rather than a single type of, hnRNA-hnRNP-snRNP complexes. The distinct and specific constellation of hnRNP proteins and snRNP particles that assembles on different pre-mRNAs is likely to affect the fate and pathway of processing of these transcripts.

Immunochemical approaches to the study of histone H1 and high mobility group chromatin proteins

This review is an attempt to summarize all existing data on histone H1 and high mobility group proteins obtained with immunochemical methods. The following issues are treated consecutively: production of specific antisera to these protein groups, antigenic structure of the polypeptide chains, use of antibodies for the identification, the quantitative estimation and the study of the tissue- and species-specificity of the proteins. Special attention is devoted to the studies of the localization of the respective antigens in the cell, the nucleus, the chromosomes and the interphase chromatin. The use of specific antibodies for the elucidation of the role these proteins play in such basic cellular processes as proliferation and differentiation, replication and transcription is also discussed. It becomes clear that the use of immunochemical approaches in the study of specific chromatin proteins both at the level of the protein molecule and at the level of chromatin can be a powerful tool for the resolution of a number of specific problems. The field is very promising and will undoubtedly develop intensely in the nearest future.

Isolation and distribution of a Drosophila protein preferentially associated with active regions of the genome

A non-histone chromosomal protein of Mr = 75,000 was isolated from Drosophila embryos. The distribution pattern of this protein was determined by indirect immunofluorescence on salivary gland chromosomes of Drosophila melanogaster third instar larvae and compared with the distribution pattern of RNA polymerase II. Despite its preferential association with transcriptionally active regions of the chromosomes there was in many cases an almost inverse correlation with the RNA polymerase II content of a given locus. We postulate a function of the Mr = 75,000 protein in posttranscriptional regulation of gene expression by storing the newly synthesized RNA.

In situ detection of early replication phases of a gemini virus in legume protoplasts

Protoplasts of Phaseolus vulgaris L. (Top Crop), infected with bean golden mosaic virus, were isolated and fixed by various methods for in situ hybridization. An iodine-125 labeled probe was made from the replicative form of the virus. The localization and quantitation was done by autoradiography. Cell wall removal lowered the background and allowed a more accurate analysis. RNase was used to eliminate the possibility of hybrids to RNA. The evidence suggests a sequence of virus movements starting from rough endoplasm reticulum, moving to the nuclear membrane, and finally with the highest concentration inside the nucleus.

Isolation and distribution of a Drosophila protein preferentially associated with inactive regions of the genome

The distribution patterns of chromosomal proteins from Drosophila can be observed by immunofluorescent staining of the polytene chromosomes from larval salivary glands. We have purified a non-histone chromosomal protein of Mr = 69,000 molecular weight which has a high affinity for DNA with little sequence specificity. Immunofluorescent staining indicates that this protein is preferentially associated with the inactive portions of the genome, including the centric heterochromatin and the condensed bands within the euchromatic arms of the chromosomes. Observation of both the heat shock loci 87A and 87C and the developmentally regulated loci 74EF and 75B shows an inverse correlation between immunofluorescent staining for the Mr = 69,000 protein and for RNA polymerase. The presence of this protein appears to be correlated with the packaging of the chromatin in an inactive form.

Interactions of the high-mobility-group-like Ceratitis capitata C1 proteins with DNA

We have studied the interactions of the high-mobility-group-like proteins (C1a1, C1a2 and C1b) from the fruit fly Ceratitis capitata with DNA. Nitrocellulose filter binding assays, thermal denaturation studies and spectrofluorimetry of the complexes revealed the existence of specific and nonspecific interactions. Thermal denaturation curves showed that the three proteins stabilized the DNA, thus suggesting a preferential binding to double-stranded DNA. The calculation of the thermodynamic parameters of the interactions showed that the nonspecific bindings were characterized by low association constants (Ka) with values ranging from 2.7 X 10(4) M-1 to 2.0 X 10(6) M-1. Also, the cooperativity of these interactions was relatively high (cooperativity factor, w, values ranging over 20-35), and the number of nucleotides involved was low (1-3 base pairs). On the other hand, the existence of specific interactions between C1 proteins and DNA was suggested by two facts: the retention of C. capitata [3H]DNA in nitrocellulose filters was only a low percentage of total input DNA and there was a marked size dependence of the binding (25% retention of a 40-kb DNA and only 3% retention with a DNA of 1 kb). The specific bindings had higher Ka values than the nonspecific ones, and they also were cooperative. Some differences were observed between C1b and the C1a proteins about the way they interact with C. capitata DNA.

N-band proteins of nucleolar organizers: chromosomal mapping, subnucleolar localization and rDNA binding

The ribosomal DNA(rDNA)-containing chromatin in eukaryotes forms a unique architecture called the "secondary constriction" or "nucleolus organiser region (NOR)" on mitotic chromosomes. To gain more insight into non-histone chromosomal proteins (NHCP), termed "N-band proteins", that are specifically associated with the NOR in a wide variety of eukaryotes, we attempted to: identify the NHCP responsible for N-band staining; determine their stoichiometry; map them on metaphase chromosomes; determine their subnucleolar localization and examine their possible ability to bind rDNA. Based on several criteria, including chromosomal localization, solubility, association with chromatin, and intra-nuclear localization, two of the nucleolus-rich NHCP, termed component B of mol.wt 55,000 and component C of mol.wt. 41,000, were tentatively identified as N-band proteins. Immunological studies using a polyclonal, monospecific antibody raised against component C show that this protein is in fact associated with the chromosomal telomeres where NORs are located. In nucleoli, N-band proteins appear to be compartmentalized into a structure that probably corresponds to fibrillar components. Both components B and C are among several NHCPs that showed, under in vitro conditions, a strong affinity for rDNA cloned in lambda phage but not for calf thymus genomic DNA or phage vector DNA. The antibody against component C effectively suppressed in vitro transcription by RNA polymerase I in nucleoli and nucleolar chromatin. Component C appears to exist in the nucleus at 3.75-5.13 X 10(3) copies per rDNA unit or 0.09-0.13 copy per nucleotide. These findings support the hypothesis that the NOR is a chromosomal site, architecturally not only unique but also different from other chromatin regions in that constituent DNA, i.e., rDNA, is organized in a specific manner by interacting with specific NHCP, i.e., N-band proteins.

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.

Drosophila DNA topoisomerase I is associated with transcriptionally active regions of the genome

The distribution of DNA topoisomerase I within Drosophila polytene chromosomes was observed by immunofluorescent staining with affinity-purified antibodies. The enzyme is preferentially associated with active loci, as shown by prominent staining of puffs. The heat shock loci 87A-87C are stained after, but not before, heat shock induction. A detailed comparison of the distribution of topoisomerase I with that of RNA polymerase II reveals a similar, although not identical, pattern of association. Topoisomerase I is also found in association with the nucleolus, the site of transcription by RNA polymerase I.

A cytological approach to the ordering of events in gene activation using the Sgs-4 locus of Drosophila melanogaster

The polytene chromosomes of Drosophila strains that differ in the synthesis of the major salivary gland glue protein sgs-4 were examined by indirect immunofluorescence using antisera to several nonhistone chromosomal proteins. The Oregon-R X chromosome, which produces sgs-4 messenger RNA, showed a strong fluorescent band at locus 3C11-12 when stained with anti-RNA polymerase II, whereas the null mutant Berkeley 1 failed to exhibit fluorescence at that locus. The presence of another antigen (Band 2), normally associated with developmentally active loci, was clearly evident at locus 3C11-12 of both transcriptionally competent and null strains, indicating that the association of Band 2 antigen with the chromatin is an event independent of RNA polymerase II binding. Antibodies directed against Drosophila topoisomerase I stained 3C11-12 in the Sgs-4+ (wild-type) strain brightly, but gave significantly less staining in the null strain. This indicates that the high concentrations of topoisomerase I seen at active loci are closely associated with the transcriptional event. In some of these analyses, we have made use of flies heterozygous for the wild-type and null alleles in order to make internally controlled comparisons. The results suggest that this type of analysis will enable conclusions to be drawn concerning the interdependence and order of action of chromosomal proteins involved in developmental gene activation.

Putative high mobility group (HMG) non-histone chromosomal proteins from wheat germ. Isolation, characterisation and partial sequence analysis

Four proteins have been isolated from wheat germ by methods analogous to those used to isolate HMG proteins from animal tissue. All four proteins have been shown to be chromosomal in origin. Although amino acid analyses show that three of these proteins have compositions similar to those of the mammalian HMG proteins, N-terminal sequence analyses of these proteins show an absence of sequence homology with any of the mammalian HMG proteins.

Differential distribution of nonhistone proteins from polytene chromosomes of Drosophila melanogaster after heat shock

Nine monoclonal antibodies directed against chromosomal proteins of D. melanogaster were used to study, by indirect immunofluorescence, the distribution of their respective antigens on polytene chromosomes following heat shock. This treatment is known to induce a specific set of transcriptionally active puffs with concomitant reduction of transcriptional activity in previously active loci. Our studies revealed wide differences in the distribution of the individual chromosomal proteins under heat shock conditions with regard to pattern and rate of both elimination from the inactivated loci and accumulation in the activated loci.

Protein D1 preferentially binds A + T-rich DNA in vitro and is a component of Drosophila melanogaster nucleosomes containing A + T-rich satellite DNA

Our previous work [Levinger, L. & Varshavsky, A. (1982) Cell 28, 375-385] has shown that D1, a 50-kilodalton chromosomal protein of Drosophila melanogaster, is specifically associated with isolated nucleosomes that contain a complex A + T-rich satellite DNA with buoyant density of 1.688 g/ml. We show here that D1 is also a component of nucleosomes containing a simple-sequence, pure A + T satellite DNA, buoyant density 1.672 g/ml. Furthermore, using a modification of a protein blotting technique in which proteins are not exposed to dodecyl sulfate denaturation, we have found that D1 preferentially binds to A + T-rich double-stranded DNA in vitro, and it is apparently the only abundant nuclear protein in cultured D. melanogaster cells that possesses this property. Synthetic poly[d(A-T)].poly[d(A-T)] and poly(dA).poly(dT) duplexes effectively compete in vitro with A + T-rich D. melanogaster satellite DNAs for binding to D1, whereas total Escherichia coli DNA is an extremely poor competitor. These findings strongly suggest that D1 is a specific component of A + T-rich, tandemly repeated, heterochromatic regions, which constitute up to 15-20% of the total D. melanogaster genome. Possible functions of D1 protein include compaction of A + T-rich heterochromatin and participation in microtubule-centromere interactions in mitosis. In addition, D1 may prevent nonspecific binding to A + T-rich satellite DNA of other nuclear proteins that have a preference for AT-DNA, such as RNA polymerase or regulatory proteins, and may also participate in the higher-order chromatin organization outside tandemly repetitive regions by binding to nonrandomly positioned stretches of A + T-rich DNA.

Interbands of polytene chromosomes: binding sites and start points for RNA polymerase B (II)

Polytene chromosomes of different chironomids, i.e., Chironomus tentans, C. melanotus and Glyptotendipes barbipes were isolated from salivary glands in a native state. These chromosomes were treated in vitro either mechanically or with different ionic strengths to modify them structurally as to yield different degrees of decondensation of the compact bands. Treated and untreated polytene chromosomes were lightly fixed with formaldehyde and stained by indirect immunofluorescence for RNA polymerase B. The distribution of this enzyme in bands, interbands, puffs and centromeric heterochromatin was scored and compared with that of histone H2B. The results indicate that failure to observe an antigen in condensed regions of chromatin does not necessarily imply its absence. Decondensation of bands, for example, leads to massive uncovering of histone H2B antigen, which appears to be masked in the bands of untreated polytene chromosomes. No evidence, however, of a corresponding unmasking of RNA polymerase B molecules was observed, indicating that few if any enzyme molecules are trapped in bands. Thus binding sites for RNA polymerase B and start points for transcriptional activity of the enzyme appear always to be the interband regions.

Immunoelectron microscopic localization of RNA polymerase B on isolated polytene chromosomes of Chironomus tentans

RNA polymerase B (or II) was localized by immunoelectron microscopy in ultrathin sections of polytene chromosomes isolated from larval salivary glands of Chironomus tentans. The enzyme was found at decondensed sites (puffs and interbands), whereas no detectable RNA polymerase B was present in condensed loci (bands). Within each of the large puffs the highest enzyme concentration was observed wherever the chromatin was in the most decondensed state. Otherwise the enzyme appeared homogeneously distributed within puffs and interbands. This immunoelectron microscopic study, along with the recently published immunofluorescent and autoradiographic analysis of isolated Chironomus chromosomes (Sass, 1982) unequivocally demonstrates that RNA polymerase B is present in most, if not all interbands.

Detection of monoclonal antibody to high-mobility-group protein 17 from chick oviduct

Total chromosomal HMG (high-mobility-group) proteins have been isolated from oestrogen-stimulated chick oviduct. The antibodies against these proteins were induced in mice and subsequently their spleen cells were fused with myeloma cells to form hybridomas. A highly purified HMG protein, 17, was used to select for the hybridomas that produce antibody against HMG protein 17. The hybridomas were cultured and injected into mice to produce ascites. The antibody against HMG protein 17 in the IgG (immunoglobulin G) fraction of the ascites fluid was obtained by Protein A-Sepharose column chromatography. We have devised a solid-phase radioimmunoassay and enzyme-linked serological assay for the detection and characterization of this antibody directed against HMG protein 17. This anti-(HMG protein 17) IgG interacted only with HMG protein 17, but not with other chromosomal proteins, e.g. histone H1, "95K protein' (a chick oviduct-specific chromosomal protein) and HMG proteins 1, 2 and 14. The monospecific nature of this anti-(HMG protein 17) IgG fraction is confirmed.

C1 proteins: a class of high-mobility-group non-histone chromosomal proteins from the fruit fly Ceratitis capitata

1. CM-cellulose chromatography of a fraction soluble in 5% perchloric acid from Ceratitis capitata chromatin yields three proteins, C1a1, C1a2 and C1b, which have been purified to electrophoretical homogeneity. 2. C1a1, C1a2 and C1b analyse like high mobility group (HMG) non-histone chromosomal proteins, although they do not exactly correspond with those from vertebrates. It is proposed that C1 proteins, as well as Drosophila D1 [Rodríguez Alfageme et al. (1980) Chromosoma, 78, 1-31] are representative of a class of insect-specific HMG proteins. Tryptic fingerprints show that C1a1 and C1a2 are very similar, but C1b is a somewhat distinct protein. Circular dichroism studies have shown that these preparations do not appreciably fold on increasing ionic strength. 3. The interactions between DNA and C1 proteins have been studied. These proteins precipitate DNA in 0.15 M NaCl, 0.015 M sodium citrate and the precipitation curves are cooperative. Soluble complexes between C1 proteins and DNA could be prepared in low ionic strength media and their thermal denaturation profiles obtained. C1 proteins do not destabilize DNA under the conditions used to prepare the complexes but the three proteins stabilize DNA to a different degree. From these studies it has been concluded that the association constant of C1b to DNA is smaller than that of C1a1 and C1a2.

Changes in quantities of high-mobility-group protein 1 in oviduct cellular fractions after oestrogen stimulation

Antiserum against chick oviduct high-mobility-group protein 1 (HMG 1) has been induced in the rabbit. With this antiserum, immunobiochemical techniques have been used to probe the quantitative change of HMG 1 in the cellular fractions of chick oviduct before or after oestrogen stimulation. HMG 1 is detectable in the cytosol, microsomal and nuclear fraction of the chick oviduct cell. After administration of oestrogen to young chicks in vivo for 5 days, the quantity of HMG 1 is increased 4-fold in the cytosol, 3.5-fold in the microsomal fraction and 1.6-fold in the nuclear fraction. The finding of large amounts of HMG 1 in cytoplasm of oviduct cell is not likely due to its leakage from the nucleus. We anticipate that HMG 1 is synthesized in the cytoplasm and then transported into the nucleus. The synthesis and transportation of HMG proteins is probably regulated by oestrogen.

Distribution studies on polytene chromosomes using antibodies directed against hnRNP

The distribution of nuclear ribonucleoprotein (hnRNP) particles in Drosophila polytene chromosomes has been investigated using anti-B-36 serum as a probe. The use of polytene chromosomes allows resolution at the level of the chromomere, and provides the opportunity to look for both positive and negative correlations with transcriptional activity. The antiserum was obtained using the nuclear protein B-36 from Physarum polycephalum as the immunogen. It has been shown to precipitate hnRNP particles from HeLa cells through a cross-reaction with the major 32,000- and 34,000-dalton hnRNP particle proteins. The antiserum cross-reacts with a Drosophila nuclear protein of approximately 34,000 daltons. By indirect immunofluorescence, we observed that the antiserum reacts preferentially with transcriptionally active loci of the polytene chromosomes, whereas loci previously or subsequently active do not show significant fluorescence. The overall pattern of fluorescence is very similar to that generated with anti-RNA polymerase B serum. The correlation of fluorescence and transcriptional activity observed suggests that the anti-B-36 serum is recognizing hnRNP proteins which have combined with nascent RNA molecules at the sites of transcription.

The distribution of two highly repeated DNA sequences within Drosophila melanogaster chromosomes

In situ hybridization using 3H-RNA probes has been used to localize the sequences found in two satellites of density 1.705 g/cc and 1.672 g/cc to specific sites within the chromosomal complement. A detailed analysis of the sites on the S chromosome was carried out using the acute series of inversions to relate the heterochromatic breakpoint relative to the location of the sequence on this chromosome. It has also been possible to establish the order of arrangement of 1.705 and 1.672 DNA at the heterochromatic-euchromatic junction on chromosome 3(R). A mitotic map is provided. The Tm of hybrids formed in situ showed that the hybrids were representative of the sequences being analyzed. The two satellites also were traced through a number of purification procedures to show that a covalent linkage may be likely between the 1.705 g/cc and 1.672 g/cc satellite as predicted from in situ hybridization analyses.

Localization of RNA polymerase B and histones in the nucleus of primary spermatocytes of Drosophila hydei, studied by immunofluorescence microscopy

By means of indirect immunofluorescence microscopy, we have studied the distribution of RNA polymerase B, of the nucleosomal histones H2b, H3, and H4 and of histone H1, in nuclei of primary spermatocytes of Drosophila hydei. RNA polymerase B and histones, including H1, are found to be present on the loop structures of the Y chromosome. The nucleolus stains only for the histones, but not for RNA polymerase B. Various mutants deficient for some of the loops or altering their morphology, were used to identify the individual chromosomal segments. In growing spermatocytes of the genetic constitution X/0, autosomes and the chromosome X react strongly with antibodies against RNA polymerase B, but not with antibodies against histones. The results suggest that the autosomes, the chromosome X and the Y chromosomal loop structures, with the exception of the nucleolus, are transcribed mostly by RNA polymerase B.

Localization of chromosomal protein HMG-1 in polytene chromosomes of Chironomus thummi

The distribution of accessible antigenic sites in the chromosomal protein high mobility group one (HMG-1) in Chironomus thummi polytene chromosomes is visualized by immunofluorescence. The results indicate that (a) HMG-1 is distributed in a distinct banding pattern along the entire length of the chromosomes; (b) the banding pattern obtained with fluorescent antibody does not strictly correspond to that observed by phase-contrast microscopy; and (c) the amount of HMG-1 increases, and the fluorescent banding pattern changes, during the development of the organism. Our findings suggest that the protein may be involved in the modulation of the structure of selected loci in the chromosome.

Monoclonal antibodies against a specific nonhistone chromosomal protein of Drosophila associated with active genes

Hybridomas secreting monoclonal antibodies have been produced by fusion of NS-1 mouse myeloma cells with the spleen cells of mice inoculated with a 60-65,000-mol wt fraction of proteins released from Drosophila embryo nuclei treated with DNase I. The antibodies secreted by the hybridomas were examined with polytene chromosomes of formaldehyde-fixed salivary gland squashes by an immunofluorescence assay. Most of the clonal antibodies obtained resulted in specific staining of the chromosomes relative to the cytoplasmic debris. In the case of clone 28, the antibodies showed a preferential association with sites of gene activity, both puffs and loci identified as puffing at some time during the third instar and prepupal period. In larvae that were heat shocked (exposed to 35 degrees C for 15 min before removal and fixation of the glands), the antibodies of clone 28 stained preferentially the induced heat-shock loci while continuing to stain most of the normal set of loci. The antigen for clone 28 was identified as a single protein of approximately 62,000 mol wt by using the antibodies followed by 125I-rabbit anti-mouse Ig to stain nitrocellulose replicas of SDS polyacrylamide gels of total chromosomal proteins. This study demonstrates that monoclonal antibodies can be used successfully in immunofluorescence staining of formaldehyde-fixed polytene chromosomes. The results verify the hypothesis that a specific nonhistone chromosomal protein is preferentially associated with the set of loci that includes both active sites and those scheduled to be active at some time in this developmental program. Such proteins may play a general role in the mechanisms of cell determination and gene activation.

Selective release of HMG nonhistone proteins during DNase digestion of Tetrahymena chromatin at different stages of the cell cycle

The possible role of LG-1, a Tetrahymena specific HMG protein found in the macronuclear chromatin (Hamana, K. and Iwai, K. (1979) J. Biochem. 86, 789-794), was examined in relation to the chromatin structure. The chromatin isolated from cells synchronized at different stages of the cell cycle contained about one molecule of LG-1 per nucleosome. Limited digestion of the chromatin with DNase I or micrococcal nuclease selectively released LG-1 with the nucleosomal core histones and H1 remained insoluble, bound to the resistant DNA. Depending on the cell stages several types of chromatin structure were distinguished by their nuclease sensitivity. However, the chromatin at different stages exhibited the similar behavior of the LG-1 release with the nucleases as a function of the degree of chromatin solubilization. The results suggest that LG-1 proteins play a role in the chromatin organization which is rather independent of the cell stages.

Immunoreactive helix-destabilizing protein localized in transcriptionally active regions of Drosophila polytene chromosomes

A highly purified helix-destabilizing protein (HDP) obtained from rat liver has been used to elicit specific, high-titer anti-HDP sera in rabbits. These antisera show immunological crossreaction with single-stranded DNA binding proteins from several very diverse eukaryotic sources, including Drosophila embryos. The use of such antisera in the labeling of Drosophila salivary gland chromosomes by indirect immunofluorescence shows concentrations of immunoreactive HDP in many regions, but especially in chromosome puffs. There is a striking localization of HDP in heat shock puffs known to be sites of new transcription. The pattern of HDP distribution seems to implicate a transcriptional role, with some specificities independent of puffing itself.

Monoclonal antibodies against chromosomal proteins of Drosophila melanogaster: establishment of antibody producing cell lines and partial characterization of corresponding antigens

Total nuclear protein from the embryonic D. melanogaster cell line Kc and crude hydroxyapatite fractions thereof were used for immunization of mice. From the spleen cells of these mice we established 755 permanent lymphoid cell lines using the hybridoma technique originally developed by Köhler and Milstein (1975). Radioimmunoassay showed 455 of these cell lines secreted antibodies which bound to component(s) contained in the antigen mixtures used for immunization. Screening of 311 cell lines using indirect immunofluorescence revealed 58 lines whose antibodies showed a highly selective staining pattern on polytene chromosomes from the salivary glands of D. melanogaster third instar larvae. Eight of these cell lines were cloned and further characterized. We were able to order the staining patterns into three distinct classes based on the staining behaviour of the monoclonal antibodies: staining of active regions, staining of phase dark bands or staining of most interbands. The molecular weight of those antigens against which the monoclonal antibodies were directed was determined in SDS polyacrylamide gels.

Characterization of Drosophila DNA-binding protein DB-2: demonstration of its sequence-specific interaction with DNA

A DNA-binding protein (DB-2) was isolated from unfertilized Drosophila eggs by DNA-cellulose chromatogrphy. In competition assays with DNA from other species, DB-2 preferentially binds to Drosophila DNA. This binding protein can also be isolated from pupal nuclei and comprises only a small fraction ( < 0.01%) of the total nonhistone chromosomal proteins. In order to investigate the specificity of the interaction between DB-2 and the DNA, we attempted to isolate the DNA sequences to which DB-2 binds. DB-2 was used as a probe to screen our gene bank established by inserting randomly sheared fragments of Drosophila DNA into bacterial plasmids. Groups of plasmids were tested for binding to DB-2 by a filter binding assay. The plasmids bound to the nitrocellulose filter were eluted and used for bacterial transformation. After several cycles of transformation and cloning, two plasmids, A17 and B10, were isolated that bind DB-2 specifically, as measured by filter binding and competition assays. In plasmid A17, binding of DB-2 protects two short DNA segments of approximately 13 and 30 base pairs from digestion by DNase I. By filter hybridization according to Southern, these sequences were mapped to a defined restriction fragment. Further evidence for the binding specificity was obtained by visualizing the protein-DNA complex in the electron microscope. In salivary gland giant chromosomes, A17 DNA hybridizes to a single site (95A/B) on chromosome 3.

Contrasting response of euchromatin and heterochromatin to translocation in polytene chromosomes of Drosophila melanogaster

Studies on Feulgen-DNA content in the polytene chromosomes of D. melanogaster T(1:4)wm258-21 heterozygotes showed that when the euchromatic region 3D1-E2 is located next to the heterochromatic breakpoint it contains less DNA than in the non-translocated homologue (Hartmann-Goldstein and Cowell, 1976). In contrast to the region adjacent to the breakpoint, region 3C1-10, which contains intercalary heterochromatin, shows more DNA in the translocated than in the non-translocated chromosome. Transposition may induce morphologically euchromatic regions containing putatively underreplicated sequences to undergo additional replication cycles. Region 2E1-3A4, distal to 3C1 and at some distance from the heterochromatic breakpoint is apparently unaffected. Extended replication and reduced DNA content in regions which have undergone chromosomal rearrangement could be accounted for by varying degrees of blockage of replication in individual strands of the polytene chromosome.

Drosophila nucleosomes contain an unusual histone-like protein

Mononucleosomes prepared from Drosophila melanogaster nuclei contain the four core histones H2A, H2B, H3, and H4 plus an additional histone-like, acid-soluble, chromosomal protein. It is probably the protein designated D2 by Alfageme et al. [Alfageme, C.R., Zweidler, A., Mahowald, A. & Cohen, L.H. (1974) J. Biol. Chem. 249, 3729-3736]. D2 elutes with histone H2A from a Bio-Gel P-100 column, but can be distinguished electrophoretically from H2A and from the other standard Drosophila core histones. The amino acid composition of D2 resembles the compositions of H2A and H2B. However, peptide mapping reveals that D2 is not a simple sequence variant of either H2A or H2B. D2 is present in nuclei from embryos and adult heads, and thus is not restricted to a narrowly defined developmental period. It is present in D. melanogaster and D. virilis, and thus appears to be conserved during the evolution of Drosophila. D2 is present in D. melanogaster chromatin with an approximate frequency of one molecule per five nucleosomes, and must therefore be associated with a subset of nucleosomes. The function of this protein is not known. Its presence in nucleosomes, evolutionary conservation, and comparatively large abundance all suggest that it is an important nucleosomal element. It will be interesting to learn whether this histone-like protein is encoded in a subset of the Drosophila histone gene cluster or is encoded separately.

Isolation, properties and cellular distribution of D1, a chromosomal protein of Drosophila

The protein D1 was obtained from nuclei of Drosophila melanogaster embryos and purified by perchloric acid fractionation and preparative gel electrophoresis. In nuclei its amount is approximately 1% of the amount of DNA by weight. D1 is soluble in 5% perchloric acid and extractable from nuclei by solutions of moderate ionic strength (0.35 M NaCl). Amino acid analysis shows that it is rich in both basic (20%) and acidic (27%) aminoacids. In all these properties D1 resembles HMG proteins (high mobility group; Johns et al., 1975) of vertebrates; however, its apparent molecular weight (approximately 50,000) is much higher. The distribution of D1 in salivary gland polytene chromosomes was investigated by immunofluorescence. Two levels of fluorescence intensity were observed: 1) Very bright fluorescence at chromosomal positions 81F, 83E, 101F, 102C and 102F; these sites are shown, by double labeling techniques, to coincide with quinacrine bright sites. 2) Medium to low fluorescence at many sites widely distributed throughout all chromosomes. In order to interpret these results and to relate them to the in vivo distribution of D1, we have investigated the pattern of immunofluorescence staining as a function of the methods of chromosome preparation and salivary gland fixation. The immunological specificity of the anti-D1 serum was studied by comparing its reactivity with D. melanogaster and D. virilis chromosome spreads and whole salivary glands, and by using reagents that minimize non-specific antibody interactions. We conclude that D1 is widely distributed throughout cytoplasm and nucleus, present in many chromomeres but most abundant in chromosomal sites that contain the AT-rich satellite DNA of density 1.672. This distribution, together with available evidence about the nucleotide sequences present in this satellite, suggests that D1 binds preferentially to chromatin containing sequences AATAT and/or AATATAT.

Localization of ecdysterone on polytene chromosomes of Drosophila melanogaster

Ecdysterone has been crosslinked in situ to polytene chromosomes of salivary glands of Drosophila melanogaster by photoactivation. The crosslinked hormone has been localized on the chromosomes by indirect immunofluorescence microscopy. At different developmental stages the hormone was detected at different chromosomal loci. These chromosomal sites correspond to ecdysterone-inducible puff sites. Thus, the hormone binds directly to chromosomal loci, whose transcription depends on the presence of the hormone. Ecdysterone was also crosslinked to one puff site that regresses during larval development. This indicates that (i) hormone binding to polytene chromosomes activates transcription at specific loci, and (ii) hormone-dependent regression of intermolt puff 68C is mediated by direct binding of ecdysterone. Ecdysterone was not detected on puff sites that are independent of hormone action or in chromosomal interbands. After heat shock, no ecdysterone became crosslinked to polytene chromosomes.

A new method for the purification of DNA-binding proteins with sequence specificity

We describe a technique for a rapid and efficient isolation and purification of proteins binding to defined DNA sequences. Cloned double-stranded DNA was covalently coupled to m-aminobenzyloximethylcellulose in order to purify proteins which recognize and bind to specific sequences on the DNA. The purification of two DNA-binding proteins from Drosophila melanogaster is demonstrated using the respective cloned DNA sequences.