Dihydrotestosterone as a selective cellular/nuclear localization vector for anti-gene peptide nucleic acid in prostatic carcinoma cells.

Peptide nucleic acids (PNAs) are synthetic structural analogues of DNA and RNA that, if allowed to enter the cell, bind to the complementary polynucleotide sequence and inhibit DNA transcription and mRNA translation. Although PNAs have a very limited ability in penetrating nuclei of living cells, there are indications that covalent linkage of the PNA to appropriate vectors, e.g., a nuclear localization signal, permits access to the genome. Here we test the ability of dihydrotestosterone (T) covalently linked to PNA to act as a vector for targeting c-myc DNA to prostatic cancer cell nuclei. LNCaP cells, which express the androgen receptor gene, and DU145 cells, in which the androgen receptor gene is silent, offer a model to test this biologically active hormone as a cell-specific vector. T vector was covalently linked to the NH2-terminal position of a PNA complementary to a unique sequence of c-myc oncogene (PNAmyc-T). To localize PNAmyc-T and vector-free PNA within the cells, a rhodamine (R) group was attached at the COOH-terminal position (PNAmyc-R, PNAmyc-TR); cellular uptake was monitored by confocal fluorescence microscopy. PNAmyc-R was detected only in the cytoplasm of both prostatic cell lines, whereas PNAmyc-TR was localized in nuclei as well as in cytoplasm of LNCaP cells. In contrast, PNAmyc-TR uptake in DU145 cells was minimal and exclusively cytoplasmic. In LNCaP cells, MYC protein remained unchanged by exposure to vector-free PNAmyc, whereas a significant and persistent decrease was induced by PNAmyc-T. In DU145 cells, MYC expression was unaltered by PNAmyc with or without the T vector. Our data show that the T vector facilitates cell-selective nuclear localization of PNA and its consequent inhibition of c-myc expression. These findings suggest a strategy for targeting of cell-specific anti-gene therapy in prostatic carcinoma.

Contrasting effects of PNA invasion of the chimeric DMMYC gene on transcription of its myc and PVT domains.

A peptide nucleic acid (PNA) complementary to a unique DNA sequence in the second exon of the human myc proto-oncogene was tested for its effects on transcription in colonic adenocarcinoma cells in which myc had been amplified and rearranged. A prominent rearrangement in this human cell line (COLO320-DM) involves the insertion of exon 1 of the PVT gene, which is normally located 57 kb downstream, into the first myc intron. We compared the effects of PNA invasion of the resulting chimeric gene (DMMYC) on sense and antisense transcription of its myc and PVT domains. Run-on transcription experiments showed that PNA binding to the unique myc sequence was highly specific and strongly inhibited sense transcription of four unique myc sequences downstream of the PNA.DNA hybridization site, the extent of inhibition at each sequence depending on the duration of exposure to PNA, and the distance between the downstream myc sequence and the PNA block. The same PNA also inhibited antisense transcription of unique myc sequences upstream of the binding site, confirming that transit of the RNA polymerase II complexes was impaired in both directions. The inhibitory effect of PNA on upstream antisense transcription extended beyond the recombination site into the contiguous PVT domain of the chimeric DMMYC gene. In contrast, the same PNA did not inhibit PVT transcription in a cell line (Raji lymphoma) in which PVT rearrangement did not involve the myc locus.

High resolution microanalysis and three-dimensional nucleosome structure associated with transcribing chromatin.

The nucleosome is the ubiquitous and fundamental DNA-protein complex of the eukaryotic chromosome, participating in the packaging of DNA and in the regulation of gene expression. Biophysical studies have implicated changes in nucleosome structure from chromatin that is quiescent to active in transcription. Since DNA within the nucleosome contains a high concentration of phosphorus whereas histone proteins do not, the nucleosome structure is amenable to microanalytical electron energy loss mapping of phosphorus to delineate the DNA within the protein-nucleic acid particle. Nucleosomes associated with transcriptionally active genes were separated from nucleosomes associated with quiescent genes using mercury-affinity chromatography. The three-dimensional image reconstruction methods for the total nucleosome structure and for the 3D DNA-phosphorus distribution combined quaternion-assisted angular reconstitution of sets of single particles at random orientations and electron spectroscopic imaging. The structure of the active nucleosome has the conformation of an open clam-shell, C- or U-shaped in one view, elongated in another, and exhibits a protein asymmetry. A three-dimensional phosphorus map reveals a conformational change in nucleosomal DNA compared to DNA in the canonical nucleosome structure. It indicates an altered superhelicity and is consistent with unfolding of the particle. The results address conformational changes of the nucleosome and provide a direct structural linkage to biochemical and physiological changes which parallel gene expression.

Invasion of the CAG triplet repeats by a complementary peptide nucleic acid inhibits transcription of the androgen receptor and TATA-binding protein genes and correlates with refolding of an active nucleosome containing a unique AR gene sequence.

The DNA sequence of the genes for the androgen receptor (AR) and TATA-binding protein (TBP), like many other genes encoding transcription factors, contains a series of tandem CAG repeats. Here we explore the capacity of complementary peptide nucleic acids (PNAs) to invade the CAG triplets of the AR and TBP genes in human prostatic cancer cells and show that the PNAs readily entered the nuclei of lysolecithin-permeabilized cells and effectively inhibited sense transcription of unique AR and TBP DNA sequences downstream of the site of PNA.DNA hybridization, but not upstream of that site. These PNAs had little or no effect on transcription of the c-myc gene, which lacks a CAG triplet domain. Conversely, a PNA complementary to a unique sequence of the c-myc gene did not inhibit transcription of the AR or TBP genes but did inhibit c-myc transcription. Comparisons of PNA effects on sense and antisense transcription of the AR, TBP, and c-myc genes confirm that progression of the RNA polymerase complex beyond the site of PNA.DNA hybridization is impaired in both directions. Suppression of the AR gene results in refolding of a transcriptionally active nucleosome containing a unique 17-mer AR DNA sequence.

Visualization and analysis of unfolded nucleosomes associated with transcribing chromatin.

We have characterized the structure of transcriptionally active nucleosome subunits using electron spectroscopic imaging. Individual nucleosomes were analyzed in terms of total mass, DNA and protein content, while the ensemble of images of active nucleosomes was used to calculate a three-dimensional reconstruction. Transcriptionally active nucleosomes were separated from inactive nucleosomes by mercury-affinity chromatography thus making it possible to compare their structures. The chromatographic results combined with electron spectroscopic imaging confirm that active nucleosomes unfold to form extended U-shaped particles. Phosphorus mapping indicated that the nucleosomal DNA also underwent a conformational change consistent with particle unfolding. The three-dimensional structure of the Hg-affinity purified nucleosomes determined using quaternion-assisted angular reconstitution methods unites and resolves the different electron microscopic views of the particle and is concordant with a sulphydryl-exposing disruption of the H3-H4 tetramer.

Isolation of active genes containing CAG repeats by DNA strand invasion by a peptide nucleic acid.

An amplification of tandem CAG trinucleotide sequences in DNA due to errors in DNA replication is involved in at least four hereditary neurodegenerative diseases. The CAG triplet repeats when translated into protein give rise to tracts of glutamine residues, which are a prominent feature of many transcription factors, including the TATA-binding protein of transcription factor TFIID. We have used a biotin-labeled, complementary peptide nucleic acid (PNA) to invade the CAG repeats in intact chromatin and then employed a method for the selective isolation of transcriptionally active chromatin restriction fragments containing the PNA.DNA hybrids. The PNA-containing chromatin fragments were captured on streptavidin-agarose magnetic beads and shown to contain all the CAG.PNA hybrids of the active chromatin fraction. DNA hybridization experiments using a DNA probe specific for unique sequences downstream of the CAG-tandem repeats confirmed that the PNA.DNA hybrids contained the transcribed gene for the TATA-binding protein. In contrast, no hybridization signal was detected with a DNA probe specific for the c-myc protooncogene, which is amplified and transcriptionally active in COLO 320DM cells but lacks CAG tandem repeats.

Recovery of transcriptionally active chromatin restriction fragments by binding to organomercurial-agarose magnetic beads. A rapid and sensitive method for monitoring changes in higher order chromatin structure during gene activation and repression.

The unfolding of nucleosomes along transcriptionally active DNA sequences uncovers previously shielded cysteinyl-thiol groups of histone H3 molecules located at the center of the nucleosome core. This change in conformation and SH reactivity of nucleosomes along transcribed DNA sequences makes it possible to separate active from inactive nucleosomes by mercury affinity chromatography. The binding of thiol-reactive nucleosomes to an organomercurial-agarose column has been shown previously to reflect, with accuracy, both the timing and extent of transcription of the associated DNA sequences (Chen, T. A., and Allfrey, V. G. (1987) Proc. Natl. Acad. Sci. U. S. A. 84, 5252-5256). Here, we extend this experimental approach to the analysis of higher order chromatin structures. Large chromatin fragments released by treating isolated nuclei with restriction endonucleases are fractionated on mercurated agarose magnetic beads that capture nucleosomes with accessible histone H3 thiols, but do not react with the hidden H3 thiols of the compactly beaded nucleosomes of inactive genes. The SH-reactive domains of c-myc and other genes are rapidly separated from the non-SH-reactive restriction fragments by the magnetic bead technique. The new method also overcomes a major limitation of mercurated agarose column chromatography, which is not suitable for studies of higher order chromatin structure because large chromatin fragments occlude the mercury column; occlusion is not a problem in magnetic separations using suspended mercurated agarose beads. Here, we describe the synthesis of mercurated agarose magnetic beads with high capacity for SH groups and test their application to the recovery of chromatin restriction fragments of c-myc and the growth arrest gene gas1.

Nucleosome structural changes during derepression of silent mating-type loci in yeast.

Mutant a and alpha yeast cells were created with histone H3 containing cysteine in place of alanine 110. Because transcriptionally active nucleosomes "unfold" to reveal the histone H3-thiol groups at the center of the core, the active nucleosomes of the mutant strain can be isolated by mercury-affinity chromatography. We compared the unbound and mercury-bound nucleosomes of haploid H3-mutant strains expressing either the MAT alpha or the MATa mating-type locus. In a MAT alpha strain, the Hg-bound nucleosomes are enriched in MAT alpha DNA but lack the DNA of the transcriptionally silent HMRa mating-type locus. Conversely, in a MATa strain, the Hg-bound nucleosomes are enriched in MATa DNA sequences but deficient in HML alpha DNA. When the SIR3 gene, known to be required for silencing of the repressed mating-type loci, is mutated in the MAT alpha strain, transcription of the HMRa ensues, and its nucleosomes, as well as those of the MAT alpha locus, are retained by the organomercurial column. It follows that derepression of the silent mating-type locus, caused by the sir3 null mutation, is accompanied by an unfolding of its nucleosomes to reveal the histone H3 SH groups at their centers. Nucleosomes of the pheromone-encoding gene MFA2, a gene that is expressed in MATa cells but not in MAT alpha cells, are bound to the organomercurial column when isolated from MATa cells but not from MAT alpha cells. Thus, there is a good correlation between nucleosome unfolding and the renewed transcriptional activity at mating-type loci, and at MFA2, which had been silenced for prolonged periods. A close temporal correlation between nucleosome refolding and the cessation of transcription is not always observed in yeast, however, in contrast to observations in mammalian cells. For example, nucleosomes of the GAL1 gene are maintained in a "poised" or "primed" thiol-reactive state even when the gene is not being transcribed (Chen, T. A., Smith, M. M., Le, S., Sternglanz, R., and Allfrey, V. G. (1991) J. Biol. Chem. 266, 6489-6498). It follows that the unfolding of the nucleosome cores of the yeast H3 mutant is regulated by factors that are not temporally linked to the recruitment or traverse of the RNA polymerase complex, but which may determine the rate at which different domains of chromatin adapt to the need for transcription of the associated DNA sequences.

Nucleosome fractionation by mercury affinity chromatography. Contrasting distribution of transcriptionally active DNA sequences and acetylated histones in nucleosome fractions of wild-type yeast cells and cells expressing a histone H3 gene altered to encode a cysteine 110 residue.

A technique for the separation of transcriptionally active and inactive nucleosomes by mercury affinity chromatography has been applied to study the nucleosomal distribution of DNA sequences from the GAL1, ACT1, HIS4, MAT alpha, and HMRa genes of yeast. In mammalian cells, the method has been shown to separate active from inactive nucleosomes and to fractionate the active nucleosomes into two classes, one retained on the mercury column because of salt-labile associations with certain thiol-reactive non-histone proteins, and the other bound by covalent linkage of the cysteine 110 thiol groups of histone H3 molecules to the mercurated support. The first class of nucleosomes is elutable in 0.5 M NaCl; the second is displaced by 10 mM dithiothreitol (DTT) (Walker, J., Chen, T. A., Sterner, R., Berger, M., Winston, F., and Allfrey, V.G. (1990) J. Biol. Chem. 265, 5736-5746). We show that, in wild-type yeast cells, in which histone H3 lacks cysteinyl residues, very little DNA and a negligible complement of nucleosomes appear in the DTT-eluate, confirming the requirement for the H3-thiols in the mercury-binding reaction. Moreover, the DTT-eluted fraction is seriously deficient in the actively transcribed GAL1, ACT1, HIS4, and MAT alpha DNA sequences. Site-directed mutagenesis was employed to create an H3 gene containing a cysteine codon in place of the alanine codon at position 110 of the yeast H3 amino acid sequence. A strain was constructed containing the mutant histone H3 gene instead of the normal H3 gene. Subsequent fractionations of the mutant nucleosomes by mercury-affinity chromatography revealed a characteristic nucleosome peak in the DTT-eluted fraction. Its content of transcribed GAL1, ACT1, and HIS4 DNA sequences was 20- to 500-fold higher than that of the corresponding DTT-eluted fraction of wild-type yeast. Although this result is in accord with the finding that, in mammalian cells, the thiol groups of histone H3 become accessible when nucleosomes "unfold" during transcription, we find that nucleosomes containing the GAL1 DNA sequences of the yeast H3-mutant also bind to the mercury column when that gene is not being expressed. We conclude that many yeast nucleosomes are maintained in a "primed," potentially active state, possibly due to the very high constitutive levels of acetylation of the core histones. However, the nucleosomes of the HMRa gene, which is not expressed in a MAT alpha yeast strain, are virtually absent from the DTT-eluted nucleosome fractions of the H3-mutant cells, indicating that prolonged silencing of the gene is accompanied by compaction and loss of H3-thiol reactivity of its nucleosomes.

Factors affecting nucleosome structure in transcriptionally active chromatin. Histone acetylation, nascent RNA and inhibitors of RNA synthesis.

The nucleosomes of transcriptionally active genes can be separated from those of inactive genes by affinity chromatography on organomercury-agarose (Hg-agarose) columns. The basis for this separation is the difference in accessibility of the sulfhydryl groups of histone H3 and certain non-histone proteins in active and inactive chromatin. A new procedure distinguishing between different modes of binding of transcriptionally active nucleosomes to the Hg-agarose column has been applied to study several factors which might influence the binding reaction. Nucleosomes that bind to the column because of salt-labile associations with SH-reactive non-histone proteins, such as the high-mobility-group proteins, HMG-1 and HMG-2, were released by adding 0.5 M NaCl to the eluting buffer. The remaining nucleosomes, in which reactive histone H3 thiol groups can bind covalently to the organomercury, were then displaced from the column by 10 mM dithiothreitol. Both Hg-agarose-bound fractions contain the transcriptionally active DNA sequences of the cell, but inactive nucleosomes, such as those containing alpha-globin DNA, pass through the column. The histones of both Hg-agarose-bound fractions have significantly higher levels of acetylation than do histones of the unbound fraction, but the content of tri- and tetra-acetylated H3 and H4 is significantly higher in the nucleosomes with reactive H3 thiols. The rate of turnover of histone N-acetyl groups is also far greater in the Hg-agarose-bound nucleosomes than in the unbound nucleosomes. Although the overall levels of histone acetylation can be increased significantly by incubating HeLa cells in the presence of the deacetylase inhibitor, 5 mM sodium butyrate, this treatment has little if any effect on the total number of nucleosomes retained on the Hg-agarose column. However, the ability of Hg-agarose chromatography to detect localized changes in chromatin structure is evidenced by an 11-fold increase in the Hg-agarose binding of nucleosomes containing the DNA of the butyrate-inducible alkaline phosphatase gene, compared to the Hg-agarose-bound nucleosomes of control cells. Although nascent RNA chains are present in the Hg-agarose-bound nucleosomes released by dithiothreitol, binding of the SH-reactive nucleosomes to the Hg-agarose column is not dependent on the presence of proteins associated with nascent RNA chains, since binding does not decrease following removal of the nascent transcripts by ribonuclease treatment.(ABSTRACT TRUNCATED AT 400 WORDS)

Affinity chromatography of mammalian and yeast nucleosomes. Two modes of binding of transcriptionally active mammalian nucleosomes to organomercurial-agarose columns, and contrasting behavior of the active nucleosomes of yeast.

The reasons for the selective binding of nucleosomes from transcriptionally active genes to the organomercurial-agarose columns have been investigated. At least two modes of binding are identified by a new two-stage elution procedure that discriminates between nucleosomes which are retained by the Hg-column because of their salt-labile associations with SH-reactive non-histone proteins, and nucleosomes in which a conformational change has made the thiol groups of histone H3 accessible to SH-reagents. The first class is released from the column in 0.5 M NaCl; the second class is eluted in 10 mM dithiothreitol which displaces the bound H3-thiols. In mammalian cells, both classes of Hg-bound nucleosomes are enriched in the DNA sequences being transcribed at the time, and their histones H3 and H4 are hyperacetylated. In yeast cells, in which histone H3 lacks cysteinyl residues, only a small fraction of nucleosomes binds to the mercury column, and it has no enrichment of DNA sequences derived from the actively transcribed GAL, HIS4, and ACT1 genes. Since few nucleosomes remain on the column after elution in 0.5 M NaCl, the bound nucleosomes of yeast are retained primarily because of salt-labile associations with thiol-reactive nonhistone proteins. Thus, the presence of histone H3-thiol groups appears to be essential for the mercury binding of the second class of nucleosomes which, in mammalian cells, is derived from the transcriptionally active genes. The results support models of reversible nucleosome unfolding during transcription in mammalian cells to reveal previously inaccessible H3-SH groups, and they also indicate that other thiol-containing proteins, including high mobility group 1 and 2, become closely but transiently associated with the chromatin subunits during their transcription.

Reversible and irreversible changes in nucleosome structure along the c-fos and c-myc oncogenes following inhibition of transcription.

A new affinity chromatographic procedure for the separation of transcriptionally active nucleosomes has been used to study the changes that take place in chromatin structure along the c-fos and c-myc genes when RNA synthesis is inhibited. Mercury-affinity chromatography separates the sulfhydryl-reactive nucleosomes of transcriptionally active genes from the compactly beaded, non-reactive nucleosomes of transcriptionally inert DNA sequences. The new procedure also discriminates between nucleosomes that have "unfolded" to reveal the previously shielded SH groups of histone H3 and nucleosomes that bind to the mercury column because of their association with thiol-containing non-histone proteins located in the transcription unit. Both classes of Hg-bound nucleosomes contain the c-fos and c-myc sequences, but only when they are being transcribed. We compared the effects of alpha-amanitin and actinomycin D on the transcription of c-fos and c-myc with the effects of each inhibitor on the distribution of the corresponding oncogenic DNA sequences in the chromatographically separated nucleosome fractions. It was found that the inhibition of RNA polymerase II by alpha-amanitin (added at the peaks of c-fos or c-myc expression in serum-stimulated BALB/c 3T3 cells) resulted in a rapid loss of affinity of the oncogene-containing nucleosomes for the mercury column. There was no corresponding effect on the mercury-binding properties of nucleosomes containing 28 S ribosomal gene sequences, which continue to be transcribed by amanitin-resistant RNA polymerase I. Therefore, the binding of the c-fos and c-myc nucleosomes to the mercury column seems to depend upon reversible structural changes associated with their transcription. Surprisingly, there was no corresponding loss of affinity of the c-fos and c-myc nucleosomes for the mercury column when actinomycin D was employed to inhibit RNA synthesis, despite the fact that transcription of both genes had been arrested abruptly. Measurements of [3H]actinomycin D binding show its preferential intercalation into the transcriptionally active nucleosomes. We suggest that the intercalation of actinomycin D into the DNA of active nucleosomes can lock the transcription complex into an "unfolded" but potentially active configuration. This was confirmed by run-off transcription assays showing a restoration of c-fos and c-myc RNA synthesis when actinomycin D was displaced by proflavine.

Estradiol enhanced acetylation of nuclear high mobility group proteins of the uterus of newborn guinea pigs.

The effect of estradiol on the acetylation of nuclear high mobility group (HMG) proteins in the uterus of newborn (3 days old) guinea pigs was studied "in vivo" and in tissue slices. In the "in vivo" studies after subcutaneous injection of 5 mCi [3H]-acetate there is a rapid (20 min) uptake of radioactive acetate in the HMG-1, HMG-2, HMG-14 and HMG-17 high mobility group proteins. In parallel studies, after administration of the same quantity of [3H]-acetate plus 20 micrograms of estradiol (E2), a selective increase in the acetylation of HMG-14 protein is observed. The preferential acetylation of HMG-14 can also be demonstrated in uterine tissue slices 20 minutes after exposure to the hormone (5 x 10(-8)M). In conclusion, the present data suggest that the acetylation of HMG proteins, in particular HMG-14, and like that of nucleosomal "core" histones, is an early event in gene activation by estradiol.

Rapid and reversible changes in nucleosome structure accompany the activation, repression, and superinduction of murine fibroblast protooncogenes c-fos and c-myc.

A procedure for the isolation of transcriptionally active nucleosomes was used to monitor changes in chromatin structure during the activation, repression, and superinduction of the protooncogenes c-fos and c-myc. Nuclei were isolated from murine fibroblasts at successive times after stimulation of quiescent cell cultures with serum or platelet-derived growth factor. The nucleosomes released by a brief micrococcal nuclease digestion were fractionated by HgII-affinity chromatography to separate the unfolded nucleosomes of transcriptionally active genes (in which the sulfhydryl groups of histone H3 are accessible for binding to HgII) from the compactly beaded nucleosomes of transcriptionally inert DNA sequences (in which the H3 sulfhydryl groups are not accessible). The DNA sequence contents of the HgII-bound and unbound nucleosome fractions were compared by slot-blot hybridizations to 32P-labeled cloned probes for c-fos and c-myc. The binding of the c-fos and c-myc nucleosomes to the HgII column accurately reflected both the timing and the degree of their expression, as determined by run-off transcription assays with the isolated nuclei. The superinduction of c-fos and c-myc expression by an inhibitor of protein synthesis (cycloheximide) was reflected in the persistence of the unfolded, transcriptionally active state of their component nucleosomes. These results provide direct evidence that rapid and reversible changes in nucleosome topography accompany the program of oncogene expression, and they suggest a way to monitor aberrant gene activity during malignant transformation.

Affinity chromatographic purification of nucleosomes containing transcriptionally active DNA sequences.

The unfolding of nucleosome cores in transcriptionally active chromatin uncovers the sulfhydryl groups of histone H3, making them accessible to SH-reagents. This has suggested that nucleosomes from active genes could be retained selectively on organomercurial/agarose columns. When nucleosomes released from rat liver nuclei by limited digestion with micrococcal nuclease were passed through an Hg affinity column, a run-off fraction of compact, beaded nucleosomes was separated from a retained nucleosome fraction. Although both contained monomer-length DNA and a full complement of core histones, histones in the retained fraction were hyperacetylated. Dot blot hybridizations showed the Hg-bound nucleosome fraction to be enriched in DNA sequences transcribed by hepatocytes (serum albumin and transferrin genes), while a brain-specific gene (preproenkephalin) was not retained, but appeared in the nucleosomes of the run-off fraction. The results are discussed in light of other evidence linking hyperacetylation of histones H3 and H4 to conformational changes at the middle of the nucleosome core.

Cell cycle-dependent changes in conformation and composition of nucleosomes containing human histone gene sequences.

Unfolding of the nucleosomes in transcriptionally active chromatin uncovers the sulfhydryl groups of histone H3 and permits the selective recovery of the unfolded nucleosomes by mercury-affinity chromatography. This new technique has been used to compare the nucleosomal proteins and their postsynthetic modifications in the unfolded and the compactly beaded nucleosomes of HeLa cells in logarithmic growth, and at different stages of the growth cycle. The Hg-bound nucleosomes are shown to be deficient in replicating DNA sequences, but to remain associated with fragments of nascent RNA chains (or RNP particles) during gradient centrifugations. Both nucleosome fractions contain a full complement of "core" histones but differ with respect to postsynthetic modifications. The Hg-bound nucleosomes contain high levels of the tri- and tetra-acetylated forms of histones H3 and H4. The unbound nucleosomes are deficient in acetylated histones but enriched in phosphorylated H2A. In synchronized HeLa cells, histone H2A and H4 gene sequences occur in the Hg-bound nucleosomes during the S-phase when their transcription takes place, but not in the G2-phase when the genes are repressed.

Altered nucleosomes of active nucleolar chromatin contain accessible histone H3 in its hyperacetylated forms.

Chromatin of the organism Physarum polycephalum contains a class of conformationally altered nucleosomes previously localized to the transcribing regions of ribosomal genes in nucleoli. When nuclei are treated with 2-iodo[2-tritium]acetate, the histone H3 sulfhydryl group of the altered nucleosomes is derivatized while that of folded nucleosomes is not, and the labeled histones can then be identified by autoradiography of gels that separate H3 isoforms. The H3 derivatized is predominantly of tri- and tetraacetylated forms. In contrast, total free histone reacted with iodoacetate shows no preferential labeling of isoforms. Selective reaction of acetylated H3 is prevalent in both nucleolar and non-nucleolar chromatin. The results link specific patterns of H3 acetylation to changes in nucleosome conformation that occur during transcription.

Phase-I clinical trial of sodium cyanate in patients with advanced colorectal carcinoma.

Sodium cyanate, a drug that selectively suppresses amino acid incorporation for protein synthesis in tumor tissue, was given to patients with advanced colorectal carcinoma who had failed to conventional therapy, with the purpose of assessing a maximum tolerable oral dose. At 35 mg/kg p.o. daily, the drug had to be stopped in approximately half (4) of the patients because of gastrointestinal toxicity (nausea, vomiting) and neurologic toxicity (hallucinations, disorientation). However, in 5 other patients, at the same dose, the drug was well tolerated for up to 147 days and for a total cumulative dose of 308 g. In this group of patients, sodium cyanate was stopped because of evidence of tumor progression. No hematologic toxicity was observed. We observed no therapeutic effects. We therefore recommend a starting dose of 30 mg/kg p.o. if a phase-II study is considered.

Microinjection studies of protein transit across the nuclear envelope of human cells.

Proteins of various molecular weights were conjugated with rhodamine and microinjected into the cytoplasm or nucleus of HeLa cells. The injected proteins were then localized within the cells at various times thereafter with fluorescence microscopy. Proteins below approx. 60 kD rapidly crossed the HeLa nuclear envelope. Some larger proteins also were able to pass into or out of the nucleus, while others were unable to do so, indicating the selective permeability of the HeLa nuclear envelope to large proteins. The nuclear protein HMG17 accumulated within the nucleus shortly after cytoplasmic microinjection.