RNA polymerases are highly regulated molecular machines. We present a method (GRO-seq) that maps the position, amount, and orientation of transcriptionally engaged RNA polymerases genome-wide. In this method, nuclear run-on RNAs are subjected to large-scale parallel sequencing and mapped to the genome. Here, we show that peaks of promoter-proximal polymerase reside on ~30% of human genes, transcription extends beyond pre-mRNA 3’ cleavage, and antisense transcription is prevalent. Additionally, most promoters have an engaged polymerase upstream and in an orientation opposite to the annotated gene. This divergent polymerase is associated with active genes, but does not elongate effectively beyond the promoter. These results imply that the interplay between polymerases and regulators over broad promoter regions dictates the orientation and efficiency of productive transcription.

Published Online December 4, 2008
Science DOI: 10.1126/science.1162228

Studies have shown that the bulk of eukaryotic genomes is transcribed. Transcriptome maps are frequently updated, but low-abundant transcripts have likely gone unnoticed. To eliminate RNA degradation, we depleted the exonucleolytic RNA exosome from human cells and then subjected the RNA to tiling microarray analysis. This revealed a class of short, polyadenylated and highly unstable RNAs. These promoter upstream transcripts (PROMPTs) are produced about 0.5 to 2.5 kb upstream of active transcription start sites (TSSs). PROMPT transcription occurs in both sense and antisense directions with respect to the downstream gene. In addition, it requires the presence of the gene promoter, and is positively correlated with gene activity. We propose that PROMPT transcription is a common characteristic of RNA polymerase II (RNAPII) transcribed genes with a possible regulatory potential.

Published Online December 4, 2008
Science DOI: 10.1126/science.1164096

Transcription initiation by RNA polymerase II (RNAPII) is thought to occur unidirectionally from most genes. Here, we present evidence of widespread divergent transcription at protein-encoding gene promoters. Transcription start site–associated RNAs (TSSa-RNAs) nonrandomly flank active promoters, with peaks of antisense and sense short RNAs at 250 nucleotides upstream and 50 nucleotides downstream of TSSs, respectively. Northern analysis shows that TSSa-RNAs are subsets of an RNA population 20 to 90 nucleotides in length. Promoter associated RNAPII and H3K4-trimethylated histones, transcription initiation hallmarks, colocalize at sense and antisense TSSa-RNA positions; however, H3K79-dimethylated histones, characteristic of elongating RNAPII, are only present downstream of TSSs. These results suggest that divergent transcription over short distances is common for active promoters and may help promoter regions maintain a state poised for subsequent regulation.

Published Online December 4, 2008
Science DOI: 10.1126/science.1162253

Microscopy studies have suggested that chromosomal DNA is composed of multiple, megabase-sized segments, each replicated at different times during S-phase of the cell cycle. However, a molecular definition of these coordinately replicated sequences and the stability of the boundaries between them has not been established. We constructed genome-wide replication-timing maps in mouse embryonic stem cells, identifying multimegabase coordinately replicated chromosome segments—“replication domains”—separated by remarkably distinct temporal boundaries. These domain boundaries were shared between several unrelated embryonic stem cell lines, including somatic cells reprogrammed to pluripotency (so-called induced pluripotent stem cells). However, upon differentiation to neural precursor cells, domains encompassing approximately 20% of the genome changed their replication timing, temporally consolidating into fewer, larger replication domains that were conserved between different neural precursor cell lines. Domains that changed replication timing showed a unique sequence composition, a strongly biased directionality for changes in resident gene expression, and altered radial positioning within the three-dimensional space in the cell nucleus, suggesting that changes in replication timing are related to the reorganization of higher-order chromosome structure and function during differentiation. Moreover, the property of smaller discordantly replicating domains may define a novel characteristic of pluripotency.

PLoS Biol 6(10): e245 doi:10.1371/journal.pbio.0060245

In the simplest view of transcriptional regulation, the expression of a gene is turned on or off by changes in the concentration of a transcription factor (TF). We use recent data on noise levels in gene expression to show that it should be possible to transmit much more than just one regulatory bit. Realizing this optimal information capacity would require that the dynamic range of TF concentrations used by the cell, the input/output relation of the regulatory module, and the noise in gene expression satisfy certain matching relations, which we derive. These results provide parameter-free, quantitative predictions connecting independently measurable quantities. Although we have considered only the simplified problem of a single gene responding to a single TF, we find that these predictions are in surprisingly good agreement with recent experiments on the Bicoid/Hunchback system in the early Drosophila embryo and that this system achieves ∼90% of its theoretical maximum information transmission.


PNAS 2008 105:12265-12270; published ahead of print August 21, 2008, doi:10.1073/pnas.0806077105

Blood and endothelium arise in close association during development, possibly from a common precursor, the hemangioblast [1], [2], [3] and [4]. Genes essential for blood and endothelial development contain functional ETS binding sites, and binding and expression data implicate the transcription factor, friend leukaemia integration 1 (Fli1) [5], [6], [7], [8], [9] and [10]. However, loss-of-function phenotypes in mice, although suffering both blood and endothelial defects, have thus far precluded the conclusion that Fli1 is essential for these two lineages [11] and [12]. By using Xenopus and zebrafish embryos, we show that loss of Fli1 function results in a substantial reduction or absence of hemangioblasts, revealing an absolute requirement. TUNEL assays show that the cells are eventually lost by apoptosis, but only after the regulatory circuit has been disrupted by loss of Fli1. In addition, a constitutively active form of Fli1 is sufficient to induce expression of key hemangioblast genes, such as Scl/Tal1, Lmo2, Gata2, Etsrp, and Flk1. Epistasis assays show that Fli1 expression is induced by Bmp signaling or Cloche, depending on the hemangioblast population, and in both cases Fli1 acts upstream of Gata2, Scl, Lmo2, and Etsrp. Taken together, these results place Fli1 at the top of the transcriptional regulatory hierarchy for hemangioblast specification in vertebrate embryos.

Current Biology, Volume 18, Issue 16, 26 August 2008, Pages 1234-1240

Adenovirus e1a induces quiescent human cells to replicate. We found that e1a causes global relocalization of the RB (retinoblastoma) proteins (RB, p130, and p107) and p300/CBP histone acetyltransferases on promoters, the effect of which is to restrict the acetylation of histone 3 lysine-18 (H3K18ac) to a limited set of genes, thereby stimulating cell cycling and inhibiting antiviral responses and cellular differentiation. Soon after expression, e1a binds transiently to promoters of cell cycle and growth genes, causing enrichment of p300/CBP, PCAF (p300/CBP-associated factor), and H3K18ac; depletion of RB proteins; and transcriptional activation. e1a also associates transiently with promoters of antiviral genes, causing enrichment for RB, p130, and H4K16ac; increased nucleosome density; and transcriptional repression. At later times, e1a and p107 bind mainly to promoters of development and differentiation genes, repressing transcription. The temporal order of e1a binding requires its interactions with p300/CBP and RB proteins. Our data uncover a defined epigenetic reprogramming leading to cellular transformation.

Science 22 August 2008: Vol. 321. no. 5892, pp. 1086 - 1088, DOI: 10.1126/science.1155546