Activation of p53 or loss of the Cockayne syndrome group B repair protein causes metaphase fragility of human U1, U2, and 5S genes.

Infection by adenovirus 12, transfection with the Ad12 E1B 55 kDa gene, or activation of p53 cause metaphase fragility of four loci (RNU1, PSU1, RNU2, and RN5S) each containing tandemly repeated genes for an abundant small RNA (U1, U2, and 5S RNA). We now show that loss of the Cockayne syndrome group B protein (CSB) or overexpression of the p53 carboxy-terminal domain induces fragility of the same loci; moreover, p53 interacts with CSB in vivo and in vitro. We propose that CSB functions as an elongation factor for transcription of structured RNAs, including some mRNAs. Activation of p53 would inhibit CSB, stalling transcription complexes and locally blocking chromatin condensation. Impaired transcription elongation may also explain the diverse clinical features of Cockayne syndrome.

Association of snRNA genes with coiled bodies is mediated by nascent snRNA transcripts.

BACKGROUND: Coiled bodies are nuclear organelles that are highly enriched in small nuclear ribonucleoproteins (snRNPs) and certain basal transcription factors. Surprisingly, coiled bodies not only contain mature U snRNPs but also associate with specific chromosomal loci, including gene clusters that encode U snRNAs and histone messenger RNAs. The mechanism(s) by which coiled bodies associate with these genes is completely unknown. RESULTS: Using stable cell lines, we show that artificial tandem arrays of human U1 and U2 snRNA genes colocalize with coiled bodies and that the frequency of the colocalization depends directly on the transcriptional activity of the array. Association of the genes with coiled bodies was abolished when the artificial U2 arrays contained promoter mutations that prevent transcription or when RNA polymerase II transcription was globally inhibited by alpha-amanitin. Remarkably, the association was also abolished when the U2 snRNA coding regions were replaced by heterologous sequences. CONCLUSIONS: The requirement for the U2 snRNA coding region indicates that association of snRNA genes with coiled bodies is mediated by the nascent U2 RNA itself, not by DNA or DNA-bound proteins. Our data provide the first evidence that association of genes with a nuclear organelle can be directed by an RNA and suggest an autogenous feedback regulation model.

Metaphase fragility of the human RNU1 and RNU2 loci is induced by actinomycin D through a p53-dependent pathway.

Infection of human cells with adenovirus 12 (Ad12), but not Ad2 or 5, induces four specific sites of metaphase chromosome fragility: the U1 small nuclear RNA (snRNA) genes (the RNU1 locus), the U2 snRNA genes (RNU2), the U1 snRNA pseudogenes (PSU1) and the 5S rRNA genes (RN5S). Significantly, each of these sites corresponds to a multigene family encoding a small, abundant structural RNA. We and others have shown previously that Ad12-induced fragility of the RNU2 locus requires U2 snRNA promoter elements, viral early functions and p53 function, but not viral replication or integration, Rb function or chromosomal sequences flanking the RNU2 locus. Remarkably, we now find that very low doses of actinomycin D (5-50 ng/ml) can phenocopy Ad12 infection: metaphase fragility of the RNU1 and RNU2 loci is induced specifically in the absence of virus, and induction also requires U2 promoter elements and p53 function. Concurrently, it has been found by others that treatment with cytosine arabinoside (araC), but not aphidicolin, can also phenocopy Ad12 infection. We propose that Ad12 infection, actinomycin D and araC all induce a similar or identical global damage arrest signal (perhaps a modification or altered conformation of p53) that preferentially interferes with metaphase condensation of the RNU1 and RNU2 loci. The RNU1 and RNU2 loci could be especially sensitive to this global signal either because specialized U snRNA transcription factors interact uniquely with the signal, or because the high concentration of short, active transcription units hinders chromatin condensation.

A tandem array of minimal U1 small nuclear RNA genes is sufficient to generate a new adenovirus type 12-inducible chromosome fragile site.

Infection of human cells with adenovirus serotype 12 (Ad12) induces metaphase fragility of four, and apparently only four, chromosomal loci. Surprisingly, each of these four loci corresponds to a cluster of genes encoding a small abundant structural RNA: the RNU1 and RNU2 loci contain tandemly repeated genes encoding U1 and U2 small nuclear RNAs (snRNAs), respectively; the PSU1 locus is a cluster of degenerate U1 genes; and the RN5S locus contains the tandemly repeated genes encoding 5S rRNA. These observations suggested that high local levels of transcription, in combination with Ad12 early functions, can interfere with metaphase chromatin packing. In support of this hypothesis, we and others found that an artificial tandem array of transcriptionally active, but not inactive, U2 snRNA genes would generate a novel Ad12-inducible fragile site. Although U1 and U2 snRNA are both transcribed by RNA polymerase II and share similar enhancer, promoter, and terminator signals, the human U1 promoter is clearly more complex than that of U2. In addition, the natural U1 tandem repeat unit exceeds 45 kb, whereas the U2 tandem repeat unit is only 6.1 kb. We therefore asked whether an artificial array of minimal U1 genes would also generate a novel Ad12-inducible fragile site. The exogenous U1 genes were marked by an innocuous U72C point mutation within the U1 coding region so that steady-state levels of U1 snRNA derived from the artificial array could be quantified by a simple primer extension assay. We found that the minimal U1 genes were efficiently expressed and were as effective as minimal U2 genes in generating a novel Ad12-inducible fragile site. Thus, despite significant differences in promoter architecture and overall gene organization, the active U1 transcription units suffice to generate a new virally inducible fragile site.

The microsatellite sequence (CT)n x (GA)n promotes stable chromosomal integration of large tandem arrays of functional human U2 small nuclear RNA genes.

The multigene family encoding human U2 small nuclear RNA (snRNA) is organized as a single large tandem array containing 5 to 25 copies of a 6.1-kb repeat unit (the RNU2 locus). Remarkably, each of the repeat units within an individual U2 tandem array appears to be identical except for an irregular dinucleotide tract, known as the CT microsatellite, which exhibits minor length and sequence polymorphism. Using a somatic cell genetic assay, we previously noticed that the CT microsatellite appeared to stabilize artificial tandem arrays of U2 snRNA genes. We now demonstrate that the CT microsatellite is required to establish large tandem arrays of transcriptionally active U2 genes, increasing both the average and maximum size of the resulting arrays. In contrast, the CT microsatellite has no effect on the average or maximal size of artificial arrays containing transcriptionally inactive U2 genes that lack key promoter elements. Our data reinforce the connection between recombination and transcription. Active U2 transcription interferes with establishment or maintenance of the U2 tandem array, and the CT microsatellite opposes these effects, perhaps by binding GAGA or GAGA-related factors which alter local chromatin structure. We speculate that the mechanisms responsible for maintenance of tandem arrays containing active promoters may differ from those that maintain tandem arrays of transcriptionally inactive sequences.

Molecular origin of the mosaic sequence arrangements of higher primate alpha-globin duplication units.

The human adult alpha-globin locus consists of three pairs of homology blocks (X, Y, and Z) interspersed with three nonhomology blocks (I, II, and III), and three Alu family repeats, Alu1, Alu2, and Alu3. It has been suggested that an ancient primate alpha-globin-containing unit was ancestral to the X, Y, and Z and the Alu1/Alu2 repeats. However, the evolutionary origin of the three nonhomologous blocks has remained obscure. We have now analyzed the sequence organization of the entire adult alpha-globin locus of gibbon (Hylobates lar). DNA segments homologous to human block I occur in both duplication units of the gibbon alpha-globin locus. Detailed interspecies sequence comparisons suggest that nonhomologous blocks I and II, as well as another sequence, IV, were all part of the ancestral alpha-globin-containing unit prior to its tandem duplication. However, sometime thereafter, block I was deleted from the human alpha1-globin-containing unit, and block II was also deleted from the alpha2-globin-containing unit in both human and gibbon. These were probably independent events both mediated by independent illegitimate recombination processes. Interestingly, the end points of these deletions coincide with potential insertion sites of Alu family repeats. These results suggest that the shaping of DNA segments in eukaryotic genomes involved the retroposition of repetitive DNA elements in conjunction with simple DNA recombination processes.

Adenovirus type 12-induced fragility of the human RNU2 locus requires U2 small nuclear RNA transcriptional regulatory elements.

Infection of human cells with oncogenic adenovirus type 12 (Ad12) induces four specific chromosome fragile sites. Remarkably, three of these sites appear to colocalize with tandem arrays of genes encoding small, abundant, ubiquitously expressed structural RNAs--the RNU1 locus encoding U1 small nuclear RNA (snRNA), the RNU2 locus encoding U2 snRNA, and the RN5S locus encoding 5S rRNA. Recently, an artificial tandem array of the natural 5.8-kb U2 repeat unit has been shown to generate a new Ad12-inducible fragile site (Y.-P. Li, R. Tomanin, J. R. Smiley, and S. Bacchetti, Mol. Cell. Biol. 13:6064-6070, 1993), demonstrating that the U2 repeat unit alone is sufficient for virally induced fragility. To identify elements within the U2 repeat unit that are required for virally induced fragility, we generated cell lines containing artificial tandem arrays of the entire 5.8-kb repeat unit, an 834-bp fragment spanning the U2 gene alone, or the same 834-bp fragment from which key U2 transcriptional regulatory elements had been deleted. The U2 snRNA coding regions within each artificial array were marked by an innocuous single base change (U to C at position 87) so that the relative expression of supernumerary and endogenous U2 genes could be monitored by a primer extension assay. We find that artificial arrays of both the 5.8- and the 0.8-kb U2 repeat units are fragile but that arrays lacking either the distal sequence element or both the distal and the proximal sequence elements of the promoter are not. Surprisingly, variations in repeat copy number and/or transcriptional activity of the artificial arrays do not appear to correlate with the degree of Ad12-inducible fragility. We conclude that U2 transcriptional regulatory elements are required for virally induced fragility but not necessarily U2 snRNA transcription per se.

Factors affecting bio-oxidation of sulfide minerals at high concentrations of solids: a review.

Bio-oxidation has proved to be a viable process for the oxidative pretreatment of refractory gold-bearing sulfides. Generally, the oxidation rate is maximal at 20% solids for high sulfide content materials [ca. 30% sulfur]. Low grade ores [1% sulfur] have been successfully oxidized at 55% solids, indicating a link between the sulfide grade of the material and the optimal solids concentration for operation. Concentrations of high solids have been reported to lower oxidation rates, increase lag times, and decrease the ultimate extent of oxidation. This review discusses the various factors that have been proposed as causes of these phenomena. The factors include oxygen and carbon dioxide availability, low bacteria-solids ratio; mechanical damage or inhibition of the bacteria, inhibition of bacterial attachment, and the buildup of toxic leach products or other detrimental substances such as some flotation reagents.

Sequential insertion of Alu family repeats into specific genomic sites of higher primates.

The presence of Alu family repeats is closely associated with interspecies length polymorphisms of certain genomic regions among different higher primates. By sequence analysis of cloned DNA, we show that one major cause for the length difference between the gibbon adult alpha-globin locus and those of human, orangutan, and Old World monkeys is the existence of multimeric Alu family repeats. Triplet Alu family repeats exist at two genomic sites of gibbon. Instead, singleton or doublet Alu family repeats are present at the orthologous positions in other higher primates. Sequence comparisons suggest that these doublet and triplet Alu repeats have been created by successive insertion of different singleton Alu repeat sequences, of approximately 300 bp, into the same genomic spot(s) during primate evolution. The approximate dates of insertion of these singleton Alu repeats support the concept of overlapping periods of active transposition or retroposition of Alu repeat subfamilies. This dynamic flow of Alu repeat sequences during primate evolution into the adult alpha-globin loci, but not beta-globin-like loci, is consistent with the previous finding that R-banding regions of the primate chromosomes are enriched in Alu repeats.

Tandemly duplicated alpha globin genes of gibbon.

The alpha globin gene locus of the common gibbon (Hylobates lar) was isolated, and it contains two closely linked alpha globin genes that share the same arrangement as that found for the homologous genes of other catarrhine primates. The nucleotide sequences of the gibbon alpha globin genes were determined and compared with the alpha globin gene sequences from other primate species (human, chimpanzee, orangutan, baboon, and rhesus); the prosimian primate, galago, alpha A and alpha B globin genes provided the out-group for this analysis. The degree of divergence for both synonymous and nonsynonymous substitutions among the alpha globin genes are generally smaller for intraspecies than interspecies comparisons, which is indicative of concerted evolution between the paired alpha globin genes of each catarrhine species. The pattern of differences is suggestive of gene conversions. This possibility is supported by both site-by-site and branch-swapping parsimony analyses. The site-by-site parsimony analysis was also used to determine the 3' boundary of each catarrhine species-specific conversion. These alpha globin gene conversion events encompass most of the transcriptional region, including the promoter, exons, introns, and about one-half of the 3'-untranslated region. However, the paired gibbon alpha globin genes show the highest degree of divergence, differing by five nucleotides in their coding regions, three of which encode amino acid replacement substitutions. It appears that the last convergence event between the paired gibbon alpha globin genes is relatively ancient, having occurred approximately 11 million years ago. The remaining 3'-untranslated region and flanking DNAs show no evidence of involvement in any recent conversion event as the parsimony analysis of these sequences group all the alpha 1 globin genes of the different catarrhine species into one clade and all the alpha 2 globin gene of these species into a separate clade. The sequence comparison among the alpha globin genes of different primate species also provides interesting implications regarding the evolution and functional domains of the 3'-untranslated regions.

The CACC box upstream of human embryonic epsilon globin gene binds Sp1 and is a functional promoter element in vitro and in vivo.

DNA sequences 179 base pairs upstream and 23 base pairs downstream of the cap site of human embryonic epsilon globin gene exhibit promoter activity in transfected cell cultures. The nuclear factor binding in vitro of this epsilon promoter region was studied by DNase I foot-printing, methylation interference, and gel mobility shift assay. Four major nuclear factor-binding sites are detected in complexes formed with unfractionated nuclear extracts: NF-E1 at -163, epsilon F1 at -143, CACC box at -111, and CBF at -81, respectively. Of these, NF-E1 is an erythroid-specific factor. epsilon F1 is probably a ubiquitous factor because it is present in both erythroid K562 cells and nonerythroid HeLa cells. The epsilon F1-binding site exhibits sequence similarity to that of the cAMP response element-binding protein family of transcription factors. Finally, the CCAAT box-binding protein (CBF)-binding site centers around the CCAAT promoter box. Comparative binding studies with unfractionated nuclear extracts and affinity purified HeLa Sp1 demonstrated that the epsilon-globin CACC box at -111 is a binding site of Sp1. The spatial arrangements of the NF-E1-binding site, the CACC box, and CCAAT box, with respect to their mutual separations by approximately integral numbers of helical turns, is well conserved in all mammalian embryonic epsilon globin promoters. Transient expression assay, using human growth hormone gene as the receptor, demonstrated that similar to the other two human beta-like globin genes (beta and gamma), the CACC box of epsilon globin gene is an essential promoter element for epsilon globin gene expression in vivo in K562 cells. This CACC promoter box also functions in vitro in nuclear extracts prepared from K562 cells. These data, together with Sp1-binding studies of the human beta and gamma globin CACC boxes, suggest that the general transcription factor Sp1, through its differential interactions with different forms of CACC promoter boxes, is an essential component of the machinery that controls the developmental program of mammalian globin gene regulation.

Can clinicians accurately assess esophageal dilation without fluoroscopy?

This study questioned whether clinicians could determine the success of esophageal dilation accurately without the aid of fluoroscopy. Twenty patients were enrolled with the diagnosis of distal esophageal stenosis, including benign peptic stricture (17), Schatski's ring (2), and squamous cell carcinoma of the esophagus (1). Dilation attempts using only Maloney dilators were monitored fluoroscopically by the principle investigator, the physician and patient being unaware of the findings. Physicians then predicted whether or not their dilations were successful, and they examined various features to determine their usefulness in predicting successful dilation. They were able to predict successful dilation accurately in 97% of the cases studied; however, their predictions of unsuccessful dilation were correct only 60% of the time. Features helpful in predicting passage included easy passage of the dilator (98%) and the patient feeling the dilator in the stomach (95%). Excessive resistance suggesting unsuccessful passage was an unreliable feature and was often due to the dilator curling in the stomach. When Maloney dilators are used to dilate simple distal strictures, if the physician predicts successful passage, he is reliably accurate without the use of fluoroscopy; however, if unsuccessful passage is suspected, fluoroscopy must be used for confirmation.

Appendicitis as an unusual cause of progressive sigmoid narrowing.

Although the presentation of appendicitis is usually straight-forward, unusual manifestations can delay diagnosis. To emphasize this, we describe a patient who developed progressive sigmoid narrowing with only nonspecific abdominal complaints over a period of months. Eventually, we came upon a pelvic abscess from a ruptured appendix. Clinicians must be ever vigilant for appendicitis and its complications.