Characterization of two types of ribosomal gene transcription in Xenopus laevis oocytes

When the germinal vesicle of Xenopus laevis oocytes is translocated into the vegetal hemisphere by centrifugation, the normally silent ribosomal spacer promoters are strongly induced. This induction correlates with the permeability of the nuclear envelope to dextran of molecular weight 70 kDa, thus raising the possibility that the transcriptional changes are due to mixing of nuclear and cytoplasmic components. This basic observation prompted a thorough investigation of ribosomal gene transcription in centrifuged oocytes which had the germinal vesicle either in the animal half (A-oocytes) or in the vegetal half (V-oocytes). Two types of ribosomal gene transcription were characterized: (1) in A-oocytes, spacer promoters remain silent, transcription initiation is dependent on the upstream terminator T3, and transcription is highly processive and recognizes sites of RNA 3' end formation (like T2 and T3); (2) in V-oocytes, spacer promoters are induced, transcription initiation is independent of T3, but most transcripts terminate prematurely after less than 150 nt. Furthermore, the transcription machinery in V-oocytes does not respond to T2 or T3 signals. The implications of the present observations for our understanding of the regulation of the spacer promoters and of the function of the upstream terminator T3 are discussed.

Mouse Dux is myotoxic and shares partial functional homology with its human paralog DUX4

D4Z4 repeats are present in at least 11 different mammalian species, including humans and mice. Each repeat contains an open reading frame encoding a double homeodomain (DUX) family transcription factor. Aberrant expression of the D4Z4 ORF called DUX4 is associated with the pathogenesis of Facioscapulohumeral muscular dystrophy (FSHD). DUX4 is toxic to numerous cell types of different species, and over-expression caused dysmorphism and developmental arrest in frogs and zebrafish, embryonic lethality in transgenic mice, and lesions in mouse muscle. Because DUX4 is a primate-specific gene, questions have been raised about the biological relevance of over-expressing it in non-primate models, as DUX4 toxicity could be related to non-specific cellular stress induced by over-expressing a DUX family transcription factor in organisms that did not co-evolve its regulated transcriptional networks. We assessed toxic phenotypes of DUX family genes, including DUX4, DUX1, DUX5, DUXA, DUX4-s, Dux-bl and mouse Dux. We found that DUX proteins were not universally toxic, and only the mouse Dux gene caused similar toxic phenotypes as human DUX4. Using RNA-seq, we found that 80% of genes upregulated by Dux were similarly increased in DUX4-expressing cells. Moreover, 43% of Dux-responsive genes contained ChIP-seq binding sites for both Dux and DUX4, and both proteins had similar consensus binding site sequences. These results suggested DUX4 and Dux may regulate some common pathways, and despite diverging from a common progenitor under different selective pressures for millions of years, the two genes maintain partial functional homology.

Antimicrobial peptide LL-37 participates in the transcriptional regulation of melanoma cells

Antimicrobial peptides are an ancient family of molecules that emerged millions of years ago and have been strongly conserved during the evolutionary process of living organisms. Recently, our group described that the human antimicrobial peptide LL-37 migrates to the nucleus, raising the possibility that LL-37 could directly modulate transcription under certain conditions. Here, we showed evidence that LL-37 binds to gene promoter regions, and LL-37 gene silencing changed the transcriptional program of melanoma A375 cells genes associated with histone, metabolism, cellular stress, ubiquitination and mitochondria.

FOXM1 cistrome predicts breast cancer metastatic outcome better than FOXM1 expression levels or tumor proliferation index

FOXM1 is a key transcription factor regulating cell cycle progression, DNA damage response, and a host of other hallmark cancer features, but the role of the FOXM1 cistrome in driving estrogen receptor-positive (ER+) versus estrogen receptor-negative (ER-) breast cancer clinical outcomes remains undefined. Chromatin immunoprecipitation sequencing (ChIP-Seq) coupled with RNA sequencing (RNA-Seq) analyses was used to identify FOXM1 target genes in breast cancer cells (MCF-7) where FOXM1 expression was either induced by cell proliferation or repressed by p53 upregulation. The prognostic performance of these FOXM1 target genes was assessed relative to FOXM transcript levels and a 61-gene proliferation score (PS) for their ability to dichotomize a pooled cohort of 683 adjuvant chemotherapy-naïve, node-negative breast cancer cases (447 ER+, 236 ER-). Differences in distant metastasis-free survival (DMFS) between the dichotomized expression groups were determined by Cox proportional hazard modeling. Proliferation-associated FOXM1 upregulation induced a set of 145 differentially bound and expressed genes (direct targets), and these demonstrated minimal overlap with differentially bound and expressed genes following FOXM1 repression by p53 upregulation. This proliferation-associated FOXM1 cistrome was not only better at significantly predicting metastatic outcome of ER+ breast cancers (HR: 2.8 (2.0-3.8), p = 8.13E-10), but was the only parameter trending toward significance in predicting ER- metastatic outcome (HR: 1.6 (0.9-2.9), p = 0.087). Our findings demonstrate that FOXM1 target genes are highly dependent on the cellular context in which FOXM1 expression is modulated, and a newly identified proliferation-associated FOXM1 cistromic signature best predicts breast cancer metastatic outcome.

Context-specific role of SOX9 in NF-Y mediated gene regulation in colorectal cancer cells

Roles for SOX9 have been extensively studied in development and particular emphasis has been placed on SOX9 roles in cell lineage determination in a number of discrete tissues. Aberrant expression of SOX9 in many cancers, including colorectal cancer, suggests roles in these diseases as well and recent studies have suggested tissue- and context-specific roles of SOX9. Our genome wide approach by chromatin immunoprecipitation sequencing (ChIP-seq) in human colorectal cancer cells identified a number of physiological targets of SOX9, including ubiquitously expressed cell cycle regulatory genes, such as CCNB1 and CCNB2, CDK1, and TOP2A. These novel high affinity-SOX9 binding peaks precisely overlapped with binding sites for histone-fold NF-Y transcription factor. Furthermore, our data showed that SOX9 is recruited by NF-Y to these promoters of cell cycle regulatory genes and that SOX9 is critical for the full function of NF-Y in activation of the cell cycle genes. Mutagenesis analysis and invitro binding assays provided additional evidence to show that SOX9 affinity is through NF-Y and that SOX9 DNA binding domain is not necessary for SOX9 affinity to those target genes. Collectively, our results reveal possibly a context-dependent, non-classical regulatory role for SOX9.

Application of histone modification-specific interaction domains as an alternative to antibodies

Post-translational modifications (PTMs) of histones constitute a major chromatin indexing mechanism, and their proper characterization is of highest biological importance. So far, PTM-specific antibodies have been the standard reagent for studying histone PTMs despite caveats such as lot-to-lot variability of specificity and binding affinity. Herein, we successfully employed naturally occurring and engineered histone modification interacting domains for detection and identification of histone PTMs and ChIP-like enrichment of different types of chromatin. Our results demonstrate that histone interacting domains are robust and highly specific reagents that can replace or complement histone modification antibodies. These domains can be produced recombinantly in Escherichia coli at low cost and constant quality. Protein design of reading domains allows for generation of novel specificities, addition of affinity tags, and preparation of PTM binding pocket variants as matching negative controls, which is not possible with antibodies.

DAF-12 regulates a connected network of genes to ensure robust developmental decisions

The nuclear receptor DAF-12 has roles in normal development, the decision to pursue dauer development in unfavorable conditions, and the modulation of adult aging. Despite the biologic importance of DAF-12, target genes for this receptor are largely unknown. To identify DAF-12 targets, we performed chromatin immunoprecipitation followed by hybridization to whole-genome tiling arrays. We identified 1,175 genomic regions to be bound in vivo by DAF-12, and these regions are enriched in known DAF-12 binding motifs and act as DAF-12 response elements in transfected cells and in transgenic worms. The DAF-12 target genes near these binding sites include an extensive network of interconnected heterochronic and microRNA genes. We also identify the genes encoding components of the miRISC, which is required for the control of target genes by microRNA, as a target of DAF-12 regulation. During reproductive development, many of these target genes are misregulated in daf-12(0) mutants, but this only infrequently results in developmental phenotypes. In contrast, we and others have found that null daf-12 mutations enhance the phenotypes of many miRISC and heterochronic target genes. We also find that environmental fluctuations significantly strengthen the weak heterochronic phenotypes of null daf-12 alleles. During diapause, DAF-12 represses the expression of many heterochronic and miRISC target genes, and prior work has demonstrated that dauer formation can suppress the heterochronic phenotypes of many of these target genes in post-dauer development. Together these data are consistent with daf-12 acting to ensure developmental robustness by committing the animal to adult or dauer developmental programs despite variable internal or external conditions.

Abstract 106: Metastatic outcome of early-stage estrogen receptor-positive (ER+) primary breast cancers predicted by differential expression of a subset of wild-type p53 target genes

The p53 tumor suppressor regulates a plethora of biological processes including cell cycle, apoptosis, DNA repair and cellular senescence. Gene expression signatures associated with loss-of-function p53 mutations have previously been linked to poor prognosis primary breast cancers, even among estrogen receptor (ER)-positive breast cancers the majority of which expresses wildtype (wt) p53. However, the proportion of DNA-bound (direct) or non-bound (indirect) p53 target genes within these gene expression signatures remains unknown. Therefore, we utilized chromatin immunopreciptiation-sequencing (ChIP-seq) (FactorPath, Genpathway) and expression microarrays (Affymetrix U133Av2) to characterize genome-wide direct and indirect p53 target genes associated with transcriptome changes induced in ER+ MCF7 cells after upregulating wt-p53 protein by the selective MDM2 inhibitor MI-63 (Ascenta Therapeutics). ChIP-seq and expression data were mapped together using gene symbols to yield 10653 unique genes for the differential binding and expression analysis. 2239 showed differential p53 binding (MACS; p<1e-10) mapping within +/- 10kb of their UCSC gene coordinates. Of the 1903 unique genes found differentially expressed (SAM; FDR p <0.005), 539 were shown by ChIP-seq to be direct p53-bound targets and 1364 were shown to be indirect p53 target genes. Gene Ontology (GO) analysis was performed to identify enriched functional categories among the direct and indirect p53 target genes, finding 62 GO biological processes significantly enriched among direct p53 target genes (FDR p<0.05) most of which were related to apoptosis, in contrast to the 147 GO biological processes enriched within the indirect p53 target genes including cell cycle, DNA repair, and telomere maintenance. The average expression of these direct and indirect p53 target genes were then computed in a pooled expression microarray dataset of 303 adjuvant naïve, node-negative ER+ breast cancer cases from two independent sources (GSE2034, GSE7390) annotated for distant metastasis-free survival (DMFS), Cox analysis revealed a significant association between overall p53-regulated gene expression (direct + indirect targets) and DMFS (p=0.001), but this prognostic association was significant only for the indirect p53 targets (p < 0.001; with p = 0.08 for direct p53 targets) These findings suggest that even among early-stage primary ER+ breast cancers in which p53 mutations are rare, differentially expressed p53 target genes are prognostic, with those not directly bound but nonetheless transcriptionally linked to critical wt-p53 functions (e.g. cell cycle control, DNA repair) most strongly associated with subsequent metastatic outcome.

Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 101st Annual Meeting of the American Association for Cancer Research; 2010 Apr 17-21; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2010;70(8 Suppl):Abstract nr 106.

Global characterization of transcriptional impact of the SRC-3 coregulator

The nuclear receptor and bona fide oncogene, steroid receptor coactivator-3 (SRC-3, AIB1), acts as a master transcriptional regulator of breast cancer by transducing growth signals via the estrogen receptor alpha (ER). In this resource paper, we present the genome-wide localization analysis of SRC-3 chromatin affinity sites in MCF-7 human breast cancer chromatin and compare the cis binding sites to global cartographies for ER and FoxA1. By correlating their gene proximal binding sites to integrated gene expression signatures, and in combination with gene ontology analyses, we provide a functional classification of estradiol-induced gene regulation that further highlights an intricate transcriptional control of interdependent cellular pathways by SRC-3. Furthermore, by presenting proteomics analyses of in vivo SRC-3- and ER-associated proteins, we give strong evidence to support the idea that the interpretative power of SRC-3 in estrogen signaling is mediated through the formation of distinct, cell state-dependent protein complexes. Altogether, we present the first approach in complementary comparative analyses that converges results obtained by three discovery-driven methods (cistromics, transcriptomics, and proteomics) into testable hypotheses, thus providing a valuable resource for follow-up studies that further our understanding of estrogen signaling in human diseases in general and breast cancer in particular.

Identification of pregnane-X receptor target genes and coactivator and corepressor binding to promoter elements in human hepatocytes

Chromatin immunoprecipitation (ChIP) studies were conducted in human hepatocytes treated with rifampicin in order to identify new pregnane-X receptor (PXR) target genes. Genes, both previously known to be involved and not known to be involved in drug disposition, with PXR response elements (PXREs) located upstream, within or downstream from their potentially associated genes, were identified. Validation experiments identified several new drug disposition genes with PXR binding sites. Of these, only CYP4F12 demonstrated increased binding in the presence of rifampicin. The role of PXR in the basal and inductive response of CYP4F12 was confirmed in hepatocytes in which PXR was silenced. We also assessed the association of PXR-coactivators and -corepressors with known and newly identified PXREs. Both PXR and the steroid receptor coactivator (SRC-1) were found to bind to PXREs in the absence of rifampicin, although binding was stronger after rifampicin treatment. We observed promoter-dependent patterns with respect to the binding of various coactivators and corepressors involved in the regulation of CYP4F12, CYP3A4, CYP2B6, UGT1A1 and P-glycoprotein. In conclusion, our findings indicate that PXR is involved in the regulation of CYP4F12 and that PXR along with SRC1 binds to a broad range of promoters but that many of these are not inducible by rifampicin.

NGF-mediated transcriptional targets of p53 in PC12 neuronal differentiation

BACKGROUND

p53 is recognized as a critical regulator of the cell cycle and apoptosis. Mounting evidence also suggests a role for p53 in differentiation of cells including neuronal precursors. We studied the transcriptional role of p53 during nerve growth factor-induced differentiation of the PC12 line into neuron-like cells. We hypothesized that p53 contributed to PC12 differentiation through the regulation of gene targets distinct from its known transcriptional targets for apoptosis or DNA repair.

RESULTS

Using a genome-wide chromatin immunoprecipitation cloning technique, we identified and validated 14 novel p53-regulated genes following NGF treatment. The data show p53 protein was transcriptionally activated and contributed to NGF-mediated neurite outgrowth during differentiation of PC12 cells. Furthermore, we describe stimulus-specific regulation of a subset of these target genes by p53. The most salient differentiation-relevant target genes included wnt7b involved in dendritic extension and the tfcp2l4/grhl3 grainyhead homolog implicated in ectodermal development. Additional targets included brk, sdk2, sesn3, txnl2, dusp5, pon3, lect1, pkcbpb15 and other genes.

CONCLUSION

Within the PC12 neuronal context, putative p53-occupied genomic loci spanned the entire Rattus norvegicus genome upon NGF treatment. We conclude that receptor-mediated p53 transcriptional activity is involved in PC12 differentiation and may suggest a contributory role for p53 in neuronal development.

Identification of target genes in breast cancer cells directly regulated by the SRC-3/AIB1 coactivator

Steroid receptor coactivator-3 (SRC-3/AIB1) is a coactivator for nuclear receptors and other transcription factors and an oncogene that contributes to growth regulation and development of mammary and other tumor types. Because of its biological functions, it is important to identify genes regulated by SRC-3. However, because coactivators do not bind DNA directly, extensive work is required to determine whether genes identified by RNA profiling approaches are direct or indirect targets. Here, we report the use of chromatin immunoprecipitation (ChIP)-based assays that involve genomic mapping and computational analyses of immunoprecipitated DNA to identify SRC-3-binding target genes in estradiol (E2)-treated MCF-7 breast cancer cells. We identified 18 SRC-3 genomic binding sites and demonstrated estrogen receptor-alpha (ERalpha) binding to all of them. Both E2-dependent and -independent SRC-3/ERalpha-binding sites were identified. RNA polymerase II ChIP assays were used to determine the correlation between SRC-3 and ERalpha binding and recruitment of the transcriptional machinery. These assays, in conjunction with analyses of RNA obtained from E2-treated cells, lead to the identification of SRC-3/ERalpha-associated genes. The ability of SRC family coactivators to regulate the expression of one of these genes, PARD6B/Par6, was confirmed by using cells individually depleted of SRC-1, SRC-2, or SRC-3 by small interfering RNA. The method described herein can be used to identify genes regulated by non-DNA-binding factors, such as other coactivators or corepressors, as well as DNA-binding transcription factors, and provides information on their binding location that can accelerate further gene characterization.

High G/C content of cohesive overhangs renders DNA end joining Ku-independent

Ku plays an important role in the repair of double strand DNA breaks by non-homologous DNA end joining (NHEJ). Ku is thought to exert its function by aligning the two DNA ends. A previous study showed that the joining of certain cohesive DNA ends in cell-free in vitro reactions was independent of Ku [Mol. Cell. Biol. 19 (1999) 2585]. To investigate a possible correlation between Ku-dependence of DNA end joining reactions and the strength of base pair interactions between cohesive ends, we constructed a series of repair substrates with either 3'- or 5'-overhangs, which consisted entirely of either A/T or G/C residues. We found that after Ku-immunodepletion of the extract, the joining of cohesive ends that associate by the formation of four A:T base pairs was reduced, while the joining of ends that associate through four G:C base pairs was unaffected or slightly stimulated. The precision of the repair was not reduced in Ku-independent reactions. Our results indicate that the requirement for Ku is dependent on how stably the two cohesive DNA ends can associate by base-pairing. Two independent assays for protein-DNA interactions did not reveal any differences in Ku binding to substrates with A/T and G/C overhangs, suggesting that in this system Ku is recruited to the repair site regardless of whether it is functionally required or not. The finding that Ku is dispensable for efficient and precise joining of ends with cohesive G/C overhangs also suggests that alignment of DNA ends may be the sole function of Ku during NHEJ.

Amplification and overexpression of oncogene Mdm2 and orphan receptor gene Nr1h4 in immortal PRKDC knockout cells

DNA-dependent protein kinase (DNA-PK) is required for the repair of double strand DNA breaks by nonhomologous DNA end joining. The catalytic subunit of DNA-PK, PRKDC, may also be involved in repair-related or separate cell signaling pathways. To learn more about the cellular function of DNA-PK under normal physiological conditions, we identified genes that are differentially expressed between an immortalized wild-type mouse fibroblast cell line and its DNA-PK-deficient counterpart (Prkdc -/-). The proto-oncogene Mdm2 and the farnesoid X receptor gene Nrlh4 were overexpressed in the DNA-PK-deficient cell line. We show that in the DNA-PK-deficient cell line the genes for both Mdm2 and Nrlh4 are amplified to a degree that could account for most, if not all, of their increased expression. Other genes were strongly downregulated in the DNA-PK-deficient cell line, but this opposite expression pattern was not due to gene amplification in the wild-type cells. None of these genes was differentially expressed in DNA-PK-containing and DNA-PK-deficient primary mouse embryo fibroblasts. Our results suggest a model in which DNA-PK indirectly affects the cellular gene expression profile through its caretaker role and by preventing gene amplification.

Differential gene expression in human glioma cells: correlation with presence or absence of DNA-dependent protein kinase

The human glioma cell line M059J is deficient in DNA-dependent protein kinase (DNA-PK) due to a frame-shift mutation in PRKDC, the gene for its catalytic subunit, while cell line M059K, isolated from the same malignant tumor, has normal DNA-PK activity. DNA-PK is required for double-strand DNA break repair, and its absence is responsible for increased radiosensitivity of M059J. We show that transcripts of several melanoma antigen subfamily A (MAGE-A) genes, the expression of which is restricted to tumor and germ-line cells,are present in M059K, but that their expression is strongly downregulated in M059J. Normal levels of MAGE-A expression are restored in the PRKDC-complemented cell line M059J/Fus1, suggesting that the presence of DNA-PK is required for MAGE-A gene transcription. We also show that the MAGE-A1 promoter is methylated in M059J, while the promoter is demethylated in M059K and M059J/Fus1. Other genes, including all three major histocompatibility class I (HLA) genes, BENE, and an unnamed gene related to CNIL(CORNICHON-like), display an opposite expression profile (i.e., they are upregulated in the DNA-PK-deficient cell line, but show low levels of expression in both M059K and in the PRKDC-complemented cell line). For these genes, differential expression does not correlate with DNA methylation in upstream promoter sequences. Our results suggest that the presence of DNA-PK can exert effects on gene expression by various mechanisms and pathways, thus affecting overall cell physiology even in the absence of DNA damage.

Joining of DNA ends bearing non-matching 3'-overhangs

Using the Xenopus egg extract as an in vitro system for double strand break repair, the joining of DNA ends bearing non-complementary, homopolymeric, 4nt 3'-protruding single strands ("overhangs") was examined. Such 3'-overhangs can not be filled-in and cannot align and anneal by canonical base pair interactions, thus presenting a special challenge to the repair machinery. The results indicate that two such non-matching 3'-overhangs typically overlap by 2nt forming non-canonical base pairs, from which the filling-in of the remaining gaps is primed. The repair reaction is inhibited in Ku-depleted extracts. Unexpectedly, with some of the substrates the predominant repair products were joints with no nucleotide loss, suggesting that the two DNA ends aligned without overlap. However, the additional finding that an activity in the egg extract adds one or a few nucleotides to a fraction of the 3'-ends favors a model in which most or all of the zero-loss joints are the net result of 3'-overhang extension and 2bp overlap formation. The nucleotide addition reaction is stimulated by increasing the concentration of the complementary dNTP or ddNTP in the extract, suggesting a process templated by free nucleotides and the involvement of a DNA polymerase-like activity.

Nonhomologous DNA end joining in cell-free systems

Double strand DNA breaks are usually caused by ionizing radiation and radiomimetic drugs, but can also occur under normal physiological conditions during double strand break-induced recombination, such as the rearrangement of T-cell receptor and immunoglobulin genes during lymphoid development or the mating type switching in yeast. The main repair mechanism for double strand breaks in higher eukaryotes is nonhomologous DNA end joining (NHEJ), which modifies and ligates the two DNA ends without the help of extensive base-pairing interactions for alignment. Defects in double strand break repair are associated with radiosensitivity, predisposition to cancer and immunodeficiency syndromes, and the analysis of the underlying mutations has lead to the identification of several proteins involved in NHEJ. However, these genetic studies have yielded little information on the mechanism of NHEJ, and while some of the protein factors identified possess the expected enzymatic or DNA-binding activities, the precise role of others remains unclear. Systems for cell-free NHEJ have been available for over 10 years, but the biochemical analysis of NHEJ has lagged behind the genetic analysis, and not a single protein factor required for NHEJ has been identified by biochemical purification and reconstitution of NHEJ activity. Here I review the current status of in vitro systems for NHEJ, summarize the results obtained and information gained, and discuss the outlook for biochemical approaches to study NHEJ.

Ku-dependent nonhomologous DNA end joining in Xenopus egg extracts

An extract from activated Xenopus eggs joins both matching and nonmatching ends of exogenous linear DNA substrates with high efficiency and fidelity (P. Pfeiffer and W. Vielmetter, Nucleic Acids Res. 16:907-924, 1988). In mammalian cells, such nonhomologous end joining (NHEJ) is known to require the Ku heterodimer, a component of DNA-dependent protein kinase. Here I investigated whether Ku is also required for the in vitro reaction in the egg extract. Immunological assays indicate that Ku is very abundant in the extract. I found that all NHEJ was inhibited by autoantibodies against Ku and that NHEJ between certain combinations of DNA ends was also decreased after immunodepletion of Ku from the extract. The formation of a joint between a DNA end with a 5'-protruding single strand (PSS) and an end with a 3'-PSS, between two ends with 3'-PSS, and between two blunt ends was most Ku dependent. On the other hand, NHEJ between two DNA ends bearing 5'-PSS was Ku independent. These results show that the Xenopus cell-free system will be useful to biochemically dissect the role of Ku in eukaryotic NHEJ.

Identification of novel genes encoding transcription elongation factor TFIIS (TCEA) in vertebrates: conservation of three distinct TFIIS isoforms in frog, mouse, and human

We report the characterization of cDNA clones that define a new, third isoform of the transcription elongation factor TFIIS in Xenopus, mouse, and human. In Xenopus the mRNA of this isoform, termed TFIIS.h, shows tissue-restricted expression, frequently contains unspliced introns, and is characterized by three near-perfect 150-bp repeats at the 5'-terminus. Although we were unable to isolate full-length cDNAs, it is clear that these repeats contain an open reading frame encoding a region of TFIIS.h that is much more complex than in other isoforms. Identification of ESTs encoding TFIIS.h in mouse and human followed by the sequencing of cognate cDNA clones enabled the complete TFIIS.h coding region to be predicted. The conserved N- and C-terminal domains of mammalian TFIIS.h (TCEA3) are separated by a linker region that is more variable in sequence and that is also 50 amino acids longer than in other isoforms. The repetitive region of Xenopus TFIIS.h apparently corresponds to an even more extended linker. Phylogenetic analysis of TFIIS sequences demonstrates the ancient origins of the three vertebrate isoforms, although they appeared functionally equivalent in in vitro RNA cleavage assays.

mRNA encoding the catalytic subunit of DNA-dependent protein kinase is widely expressed in Xenopus cells

Here, the sequence of a Xenopus laevis cDNA encoding the 640 carboxy-terminal amino acids of the catalytic subunit of DNA-dependent protein kinase (DNA-PKcs) is reported. The predicted Xenopus protein segment is 65% identical to the human counterpart. Northern blot analysis indicates that Xenopus DNA-PKcs is encoded by an approx. 13000 nt transcript. DNA-PKcs mRNA is widely expressed in adult tissues as well as in oocytes and embryos. It is also shown that outside the conserved kinase domain, Xenopus DNA-PKcs bears significant similarities to hypothetical 420.8 and 433.2 kDa proteins in yeast species.

Transcript cleavage in an RNA polymerase I elongation complex. Evidence for a dissociable activity similar to but distinct from TFIIS

Stalled Xenopus RNA polymerase I (pol I) elongation complexes bearing a 52-nucleotide RNA were prepared by promoter-initiated transcription in the absence of UTP. When such complexes were isolated and incubated in the presence of Mg2+, the associated RNA was shortened from the 3'-end, and mono- and dinucleotides were released. Shortened transcripts were still associated with the DNA and were quantitatively reelongated upon addition of NTPs. The cleavage activity could be removed from the pol I-ternary complex with buffers containing 0.25% Sarkosyl. These findings indicate that a factor with characteristics similar to elongation factor TFIIS is associated with the pol I elongation complex. However, addition of recombinant Xenopus TFIIS to Sarkosyl-washed pol I elongation complexes had no effect, whereas it showed the expected effects in control reactions with identically prepared pol II elongation complexes. The results thus suggest the existence of a pol I-specific cleavage/elongation factor. I also report the sequence of a novel type of Xenopus TFIIS. The predicted amino acid sequences of the present and previously identified Xenopus TFIIS are less than 65% conserved. Thus, like mammalian species, Xenopus has at least two highly divergent forms of TFIIS.

Phosphorylation of the N-terminal domain of Xenopus TATA-box binding protein by DNA-dependent protein kinase depends on the C-terminal core domain

DNA-dependent protein kinase (DNA-PK) has been shown to phosphorylate several transcription factors in vitro, suggesting that this nuclear enzyme - in addition to its role in DNA repair and recombination - may be involved in transcriptional regulation. In the typical mechanism the DNA-bound kinase phosphorylates a substrate that is bound to the same DNA molecule. Here I report that the Xenopus TATA-box binding protein (xTBP) is hyperphosphorylated by DNA-PK in vitro. The phosphorylation is in the N-terminal domain of the protein but depends fully on the presence of the C-terminal core domain.

Heteroduplex analysis of the Xenopus RNA polymerase I terminator

Recent results showed that the Xenopus ribosomal terminator, a conserved 9-bp element ("T2/T3 box"), is a pause signal for the RNA polymerase I-elongation complex (Labhart, P. [1995] Nucleic Acids Res. 23, 2252-2258). Since the terminator is known to function only in one orientation, it was of interest to investigate whether the 9-bp pause element had to be present in both DNA-strands to mediate termination of RNA polymerase I-transcription. The present heteroduplex analysis of the terminator shows that only the double-stranded 9-bp element constitutes a functional terminator. Any single-stranded mutation had the same down-effect as the corresponding double-stranded (homoduplex) mutation. Models for termination by Xenopus RNA polymerase I that are supported or eliminated by the present results are discussed.

The Xenopus 9 bp ribosomal terminator (T3 box) is a pause signal for the RNA polymerase I elongation complex

In Xenopus, termination by RNA polymerase I (pol I) is mediated by the 9 bp sequence GACTTGCNC and RNA 3'-ends are formed -15-20 nt upstream of this terminator element. Here I show that this 9 bp element, also called the 'T3 box', is a pause signal for the elongating transcription complex. The two major transcripts in the paused complex have 3'-ends mapping to 15 and 21 nt upstream of the T3 box, remain bound to the template in 0.25% Sarkosyl, are subject to pyrophosphorolysis and can be chased into longer transcripts. Mutations that reduce overall termination also affect pausing, indicating that pausing is a limiting step in the termination process. Oligonucleotide competition experiments, furthermore, suggest that pausing requires a DNA binding factor. The data support a model in which the first step leading to transcription termination by pol I in Xenopus is pausing of the elongation complex upstream of the T3 box.

DNA-dependent protein kinase specifically represses promoter-directed transcription initiation by RNA polymerase I

DNA-dependent protein kinase (DNA-PK) is a nuclear enzyme that phosphorylates several transcription factors, but its cellular function has not been elucidated. Here I show that DNA-PK strongly inhibits promoter-directed transcription initiation by Xenopus RNA polymerase I in vitro. The repression is due to protein phosphorylation, since it is relieved by 6-dimethylaminopurine, an inhibitor of protein kinases. DNA-PK inhibits transcription from both linear and circular templates, but the repression is more efficient on linear templates. DNA-PK has no effect on promoter-directed transcription by RNA polymerases II and III. Partial fractionation of the in vitro transcription system shows that a protein fraction containing transcription factor Rib1, the Xenopus equivalent of human SL1, mediates the repression of transcription by DNA-PK. The present data suggest a role for DNA-PK in down-regulating ribosomal gene transcription.

Negative and positive effects of CpG-methylation on Xenopus ribosomal gene transcription in vitro

Methylation of cytosine-residues in the sequence CpG affects the expression of many genes and generally correlates with reduced transcription. The ribosomal genes of Xenopus laevis were among the first genes to be studied with respect to their DNA methylation, and a loss of methylation during embryonic development correlated with the onset of transcription. Nevertheless, highly methylated ribosomal genes were transcribed at normal levels when injected into oocyte nuclei, and thus transcription of these genes was generally assumed to be insensitive to CpG-methylation. Here I show that Xenopus ribosomal gene transcription can be repressed by cellular factors binding to meCpG, similarly as it has been described for transcription by RNA polymerase II. In the absence of these repressors, however, CpG-methylation has a direct positive effect on RNA polymerase I-promoter activity.

Identification of two steps during Xenopus ribosomal gene transcription that are sensitive to protein phosphorylation

Protein kinase(s) and protein phosphatase(s) present in a Xenopus S-100 transcription extract strongly influence promoter-dependent transcription by RNA polymerase I. The protein kinase inhibitor 6-dimethyl-aminopurine causes transcription to increase, while the protein phosphatase inhibitor okadaic acid causes transcription to decrease. Repression is also observed with inhibitor 2, and the addition of extra protein phosphatase 1 stimulates transcription, indicating that the endogenous phosphatase is a type 1 enzyme. Partial fractionation of the system, single-round transcription reactions, and kinetic experiments show that two different steps during ribosomal gene transcription are sensitive to protein phosphorylation: okadaic acid affects a step before or during transcription initiation, while 6-dimethylaminopurine stimulates a process "late" in the reaction, possibly reinitiation. The present results are a clear demonstration that transcription by RNA polymerase I can be regulated by protein phosphorylation.

Functional difference between the sites of ribosomal 40S precursor 3' end formation in Xenopus laevis and Xenopus borealis

In the ribosomal genes of X. laevis, the sequence GACTTGCNC is found about 60bp upstream of the gene promoter (T3) and is necessary and sufficient to cause termination of RNA polymerase I transcription. At the 3' end of the 40S precursor coding region (T2) a sequence differing by one nucleotide, GACTTGCNG, directs RNA 3' end formation but allows polymerase to transcribe on into the intergenic spacer (Labhart and Reeder, 1989, Genes and Dev. 4: 269-276). Sites corresponding to T2 and T3 are also found in a related species, X. borealis. Inspection of the T2 sequence in X. borealis reveals that it contains two copies of the terminator sequence, GACTTGCNC, located 15 and 96 bp downstream of the 3' end of the 40S precursor coding region. Here we present functional tests of those two T2 elements that show that, as predicted from the sequence, they both show termination activity and are functionally indistinguishable from the T3 site in X. laevis. These results suggest that X. laevis T2 is an example of a naturally occurring point mutation, and the inability to terminate transcription at T2 is an exception to the general pattern of ribosomal gene transcription in higher eukaryotes.

A point mutation uncouples RNA 3'-end formation and termination during ribosomal gene transcription in Xenopus laevis

Two sites, T2 and T3, in the ribosomal gene spacer of Xenopus laevis both direct RNA 3'-end formation 15 bp upstream of the conserved box sequence GACTTGC. Site T2, which defines the 3' end of the 40S precursor, does not terminate transcription whereas site T3 at the 3' end of the spacer does. Here we show that T2 can be converted into a T3-like site with termination activity by a single point mutation 2 bp downstream of the T2 box. RNA 3'-end formation at T2 is unchanged by this mutation. Conversely, a point mutation 2 bp downstream of the T3 box inhibits termination without affecting 3'-end formation. Our results identify two separable events occurring at the 3' end of the ribosomal genes: (1) RNA 3'-end formation by processing and (2) transcription termination. The two processes are directed by two distinct, but overlapping, signals in the DNA sequence. Site T2 in X. laevis is damaged in the second process by a natural mutation.

High initiation rates at the ribosomal gene promoter do not depend upon spacer transcription

We report experiments that test the model that in Xenopus laevis, RNA polymerase I is "handed over" in a conservative fashion from the T3 terminator to the adjacent gene promoter. We have introduced transcription-terminating lesions into the ribosomal DNA repeat by irradiating cultured cells with ultraviolet light. We used isolated nuclei to measure the effect of such lesions on transcription. UV damage sufficient to prevent all elongating RNA polymerase from reaching T3 from upstream had no adverse effect on the density of RNA polymerase at the very 5' end of the gene. We conclude that high rates of transcription initiation at the gene promoter do not depend upon polymerase passing from one repeat to the next or on polymerase initiating at the spacer promoters.

Ribosomal precursor 3' end formation requires a conserved element upstream of the promoter

In Xenopus laevis the 3' end of the longest intact ribosomal RNA precursor is formed by a processing event at site T2, which is located 7860 bp downstream of the site of transcription initiation. Processing at T2 is eliminated by mutations within the T2 box, a 7 nucleotide conserved element, GACTTGC, located 15 bp downstream of the 3' ends. The same conserved box is also present at T3, a site 60 bp upstream of the gene promoter and that is part of a termination site. Surprisingly, mutations within the T3 box also eliminate processing at T2. To obtain proper T2 function, T3 can be at any distance but must be in the correct orientation upstream of a ribosomal gene promoter.

A 12-base-pair sequence is an essential element of the ribosomal gene terminator in Xenopus laevis

rRNA transcription in Xenopus laevis terminates near a 7-base-pair (bp) conserved sequence (T3 box) located 200 bp upstream of the site of transcription initiation for the adjacent gene promoter. We present evidence here that a 12-bp element containing the T3 box is an essential part of the terminator. Using an oocyte injection assay, we found that the 12-bp element (but not the T3 box alone) severely reduced the amount of RNA detectable at sites downstream from itself and that the T3 box within the 12-bp element was required to specify the formation of correct 3' ends. This requirement for the 12-bp element was also seen in pulse-label experiments by using a homogenate of oocyte nuclei, but the present data did not allow us to determine the exact mechanism by which the 12-bp element acts. Removal of the T3 region from its normal location allowed a significant amount of readthrough transcripts to accumulate, indicating that additional sequences may be required for complete terminator function.

Heat shock stabilizes highly unstable transcripts of the Xenopus ribosomal gene spacer

We have shown recently that, in Xenopus laevis oocytes, the 3' end of the longest detectable ribosomal precursor RNA is not formed by transcription termination but by RNA processing and that RNA polymerase I continues to transcribe through the intergenic spacer region. In oocytes, these spacer transcripts are turned over rapidly, and the only apparent transcription termination site is located 215 base pairs upstream of the 5' end of the next transcription unit. In this paper we show that, at heat shock temperature (34 degrees C), processing at the 3' end of the precursor, rapid turnover of spacer transcripts, and termination are all severely impaired. In contrast, transcription initiation and chain elongation are not significantly affected by heat shock. This results in the appearance of large RNA in the range of 10-20 kilobases and longer.

Characterization of three sites of RNA 3' end formation in the Xenopus ribosomal gene spacer

We have studied three sites of 3' end formation on the Xenopus laevis ribosomal genes, designated T1, T2, and T3. Site T1 coincides with the unique HindIII site at the 3' end of the 28S sequence and is shown to be a site of rapid RNA processing. Transcription continues another 235 bp past T1 to site T2, which marks a boundary between relatively stable and highly unstable transcripts. However, T2 does not cause polymerase release. In nuclear run-off experiments transcription is detected across the entire spacer until site T3, 215 bp upstream of the gene promoter. T3 shares some sequence homology with T2 but appears to cause polymerase release and is presently the best candidate for a true terminator of transcription on these genes.

Xenopus ribosomal gene enhancers function when inserted inside the gene they enhance

The ribosomal DNA of Xenopus laevis contains repeated sequence elements in the intergenic spacer region that enhance transcription from the adjacent gene promoter (1,2). Previous work has shown that these RNA polymerase I enhancers influence the target promoter when they are in either orientation, at a distance of several kilobases, and only when they are in cis (3-5). In this work, we further show that enhancer activity is unaffected by inserting the enhancers within the transcription unit whose promoter is being enhanced. In addition, enhancer activity does not interfere with transcription through its sequences. The results suggest that the enhancers act at a point prior to the initiation of transcription and that they are likely to be dispensable once transcription has begun.

Enhancer-like properties of the 60/81 bp elements in the ribosomal gene spacer of Xenopus laevis

The spacer region of the Xenopus laevis ribosomal gene contains blocks of repetitive sequence elements that are 60 or 81 bp long. These 60/81 bp elements function as enhancer elements for the RNA polymerase I promoter at the 5' end of the gene. An RNA polymerase I promoter adjacent to a block of 60/81 bp elements is always dominant over a promoter on a second plasmid when both are coinjected into oocyte nuclei. If two promoters are placed on the same plasmid containing enhancers, both promoters come under their influence and are codominant. The influence of the enhancers can be transmitted through several kilobases of plasmid sequence, through a potentially active promoter, and is independent of the orientation of the enhancers. The enhancers appear to compete with promoters for the same transcription factor(s); however, the enhancers can only compete when they are on a circular plasmid.

A structural concept for nucleoli of Dictyostelium discoideum deduced from dissociation studies

We aimed to establish whether there is a matrix structure in the nucleolus to which the ribosomal DNA (rDNA) is strongly attached. To detect artifacts that might occur during the harsh histone extraction procedures frequently used for matrix preparation, we dissociated nucleoli of Dictyostelium discoideum with a range of NaCl or heparin concentrations. With heparin treatment significant amounts of rDNA were solubilized into the dissociating solution. When the residual nucleoli were digested with Eco RI, none of the Eco RI fragments of the rDNA remained preferentially bound to the residual nucleoli, indicating that there is no matrix attached to a specific site on the rDNA. When residual nucleoli were examined by electron microscopy, a correlation was found between the extent of solubilization of rDNA, the loss of nucleosomes, and, in heparin-treated nucleoli, the loss of ribonucleoprotein-bound components. These results suggest that the rDNA is released from the nucleoli as soon as nucleosomes have been dissociated and transcription complexes disrupted. Electron microscopy also showed that the NaCl concentration required for dissociation of nucleosomes was higher when divalent cations (Ca2+, Mg2+, Cu2+) were used during the isolation or the treatment of the nucleoli prior to dissociation in high salt. Furthermore, the residual, high-salt-resistant structures were much larger when nucleoli were pretreated with divalent cations or when they were purified in the presence of Ca2+ than when they were purified in its absence. Hence divalent cations, which induce chromatin condensation, prevented nucleolar dissociation whereas treatment with chelating agents, which loosen chromatin compaction, led to much smaller residual matrixlike structures. Nucleoli could be dissociated with heparin to a larger extent than with NaCl so that in Ca2+-free preparations no residual nucleolar matrixlike structures could be detected. Our results suggest that the nucleolar "matrix" seen in the electron microscope is due to incomplete dissociation of the nucleolar material. We propose that in nucleoli of Dictyostelium the rDNA is not attached to a tightly binding matrix structure, but that nucleoli are stabilized by side-to-side contacts between chromatin fibers and transcription complexes.

Comparative studies on the structural organization of membrane-depleted nuclei and metaphase chromosomes

Interphase membrane-depleted nuclei and metaphase chromosomes were prepared in parallel with a nonionic detergent lysis procedure at low ionic strength. By flow microfluorometry we showed for the first time that cell lysates contain all stages of the cell cycle in the same proportions as the starting cell population. Morphologically intact membrane-depleted nuclei and metaphase chromosomes were isolated as non-aggregated structures on sucrose gradients. When analysed in the electron microscope, membrane-depleted nuclei that had been treated with 2M NaCl appeared as residual structures containing the pore complex-lamina layer attached to a halo of DNA filaments. In contrast, no distinct high salt-resistant structure was found with metaphase chromosomes. They formed a highly fragile network which disintegrated easily into small complexes connected with DNA filaments. High salt-resistant DNA-protein complexes were purified by Metrizamide density gradient centrifugation. The main difference in the protein composition of interphase and metaphase residual complexes was the presence in interphase of a protein triplet in the 60-75 kilodalton molecular weight range and its absence in metaphase. This protein triplet most likely corresponds to the lamins A, B, and C of the nuclear lamina. The combined results suggest that the main difference in the structural organization of interphase nuclei and metaphase chromosomes is the presence or absence of the pore complex-lamina layer.

Chromatin structure along the ribosomal DNA of Dictyostelium. Regional differences and changes accompanying cell differentiation

The ribosomal genes of Dictyostelium discoideum are extrachromosomal palindromic DNA molecules situated in the nucleolus. Each molecule comprises ribosomal RNA coding regions and non-transcribed spacer regions. We used both biochemical and electron microscopic approaches to investigate the structure of transcribing and non-transcribing chromatin. Nucleoli from exponentially growing cells were digested with micrococcal nuclease, and the resulting DNA fragments were separated by gel electrophoresis and transferred to DBM paper. They were hybridized with cloned EcoRI fragments derived from different parts of the ribosomal gene. Probes of the coding region showed a smear, while probes of the non-transcribed regions gave pronounced banding patterns more complex than typical nucleosome repeats, but not due solely to sequence-specific cutting by micrococcal nuclease. The DNA of the coding region was digested more quickly than that of the non-transcribed ones. When nucleoli were digested with restriction enzymes, sites within the coding region were accessible and sites in the non-transcribed region were protected. The structure of ribosomal chromatin in differentiating cells, in which the rate of ribosomal RNA synthesis is reduced, was examined using essentially the same methods. The coding region, probed by hybridization to micrococcal digests, then showed a typical DNA repeat pattern indicating that this region had become condensed into nucleosomes, and its accessibility to restriction enzymes was very much reduced. On electron micrographs of lysed nucleoli from exponentially growing cells, two types of chromatin were observed, one with a beaded nucleosomal appearance, the other with putative RNA polymerase molecules attached to fibres indistinguishable from free DNA adsorbed to the same grid. The combined results suggest that whereas regions that are not transcribed are packaged with proteins that protect them from nuclease digestion, actively transcribing ribosomal genes are associated with few macromolecular constituents apart from those required for transcription and its regulation.

Involvement of higher order chromatin structures in metaphase chromosome organization

Using electron microscopy we show that the metaphase chromatin fibers of Chinese hamster ovary cells form the same ionic strength-dependent higher order structures as the corresponding interphase chromatin fibers. We present evidence that such intact chromatin fibers are a prerequisite for the maintenance of the characteristic shape of metaphase chromosomes. The evidence is based on the finding that treatment of chromosomes with 0.5 M NaCl, a condition which is known to remove histone H1 and which destroys the higher order structure of chromatin fibers, also leads to a disintegration of the metaphase chromosome structure, whereas treatment with 0.3 M (or less) NaCl has no effect on the integrity of the chromosomes and their chromatin fibers. These data support a model in which the metaphase chromosome is maintained by a tight assembly of the 25-30 nm thick chromatin fibers containing all the histones.

Structure of the active nucleolar chromatin of Xenopus laevis Oocytes

Active nucleolar chromatin of Xenopus laevis oocytes was prepared for electron microscopy by a step gradient method, which separates the chromatin from proteins and other constituents that might nonspecifically bind at low ionic strength. Between putative RNA polymerases and within the nontranscribed spacer region, the chromatin appears as smooth, thin filaments. For the first time, it is shown here that these filaments are indistinguishable from pure DNA absorbed to the same specimen, even when the ionic strength is raised up to 100 mM NaCl. Bulk rat liver chromatin, however, which was coprepared as a biochemically well-characterized standard with the active nucleolar chromatin, shows nucleosomes containing fibers, which condense into supranucleosomal structures with increasing ionic strength. Since the appearance and the behavior of active nucleolar chromatin at different ionic strengths and pHs resembles tht of pure DNA, but not of any known type of chromatin, it is suggested that, except for the transcription apparatus, very few macromolecular constituents are associated with ribosomal DNA during transcription. The observations described in this paper explain most of the published and partly conflicting results obtained by electron microscopy of nucleolar chromatin.

Structural changes of soluble rat liver chromatin induced by the shift in pH from 7 to 9

Soluble rat liver chromatin was studied at pH 7 and at pH 9. In order to remove selectively non-histone components or non-histone components and histone H1, fractionation of chromatin was performed at pH 7 and pH 9 at different ionic strengths. The salt-dependent condensation of the fractionated chromatin was analysed in the electron microscope. There is no difference between the appearance of H1-depleted chromatin at poH 7 and pH 9. In H1-containing chromatin the shift from pH 7 to pH 9 leads to the following morphological changes: a) at very low ionic strength the nucleosomes unravel partially or totally and the zigzag-shaped fibres disappear in favour of beads-on-a-string; b) with increasing ionic strength the filaments condense into fibres, however, these fibres appear distorted and clearly less ordered than at pH 7. There is no indication of a release or displacement of histone H1. The pH-effect is completely reversible. The data suggest a pH-induced change in the mode of action of histone H1 in the formation of nucleosome beads and higher order chromatin structures.

Electron microscope specimen preparation of rat liver chromatin by a modified Miller spreading technique

We describe a modification of the spreading method of Miller and Bakken [17]. Prior to mounting the samples, the carbon supports used for electron microscopy are coated with Alcian blue. By this method the chromatin fibres stick firmly to the supporting film such that the shape of the fibres is independent of the washing and drying procedures used during specimen preparation. Using this technique we show an ionic strength-dependent condensation of rat liver chromatin protruding from lysed nuclei which is fully compatible with that reported previously [34] for soluble chromatin.