Project description:The high level of human genome structural variation among individuals suggests that there must be portions of the genome that have yet to be discovered, annotated and characterized at the sequence level. Using clone resources developed as part of the Human Genome Structural Variation Sequencing Project, we focused on the characterization of 2,363 novel sequence contigs not present in the human reference genome. We determined that these contigs corresponded to 720 distinct loci of which 400 now have an anchored position in the reference genome. We investigated the sequence properties of these loci and determined that 37% of these novel insertions are copy-number polymorphic. We find that they are significantly enriched within the last 5 Mb of chromosomes (a 2.9-fold enrichment, p=1.0e-18, binomial test) and that most arose as a result of deletions in the human lineage after separation from the African great apes. A subset of these sites shows evidence of marked population stratification among Asian, African and European populations, including a 3.9-kb insertion within the first intron of the lactase gene. Complete sequencing of clones from 192 genomic loci, including 156 completely spanned insertions, provides a detailed and contextual view of 1.67 Mb of inserted sequence. Analysis of this sequence identified 477 elements that show evidence of sequence constraint over evolutionary time, as well as matches to 22 RefSeq gene segments. Twenty-six of the insertions contain matches against mRNA-seq data indicating the potential presence of functionally important, unannotated human sequences. Taking advantage of this high-quality sequence, we develop a method to accurately genotype these novel insertions using next-generation whole-genome sequencing datasets.

Project description:The extent of human genomic structural variation suggests that there must be portions of the genome yet to be discovered, annotated and characterized at the sequence level. We present a resource and analysis of 2,363 new insertion sequences corresponding to 720 genomic loci. We found that a substantial fraction of these sequences are either missing, fragmented or misassigned when compared to recent de novo sequence assemblies from short-read next-generation sequence data. We determined that 18-37% of these new insertions are copy-number polymorphic, including loci that show extensive population stratification among Europeans, Asians and Africans. Complete sequencing of 156 of these insertions identified new exons and conserved noncoding sequences not yet represented in the reference genome. We developed a method to accurately genotype these new insertions by mapping next-generation sequencing datasets to the breakpoint, thereby providing a means to characterize copy-number status for regions previously inaccessible to single-nucleotide polymorphism microarrays.

Project description:The transcriptional error rate can be significantly increased by the presence of DNA lesions that instruct mis-insertion during transcription; a process referred to as transcriptional mutagenesis (TM) that can result in altered protein function. Herein, we determined the effect of O6-methylguanine (O6-meG) on transcription and subsequent transactivation activity of p53 in human lung H1299 cells. Levels of TM and effects on transactivation were determined genome wide by RNA-seq. Results showed that 47% of all p53 transcripts contained an uridine misincorporation opposite the lesion at 6 h post transfection, which was decreased to 18% at 24 h. TM at these levels reduced DNA binding activity of p53 to 21% and 80% compared to wild type p53, respectively. Gene expression data were analysed to identify differentially expressed genes due to TM of p53. We show a temporal repression of transactivation of > 100 high confidence p53 target genes including regulators of the cell cycle, DNA damage response and apoptosis. In addition, TM repressed the transcriptional downregulation by p53 of several negative regulators of proliferation and differentiation. Our work demonstrates that TM, even when restricting its effect to an individual transcription factor, has the potential to alter gene expression programs and diversify cellular phenotypes.

Project description:Sequence-specific binding by the human p53 master regulator is critical to its tumor suppressor activity in response to environmental stresses. p53 binds as a tetramer to two decameric half-sites separated by 0-13 nucleotides (nt), originally defined by the consensus RRRCWWGYYY (n = 0-13) RRRCWWGYYY. To better understand the role of sequence, organization, and level of p53 on transactivation at target response elements (REs) by wild type (WT) and mutant p53, we deconstructed the functional p53 canonical consensus sequence using budding yeast and human cell systems. Contrary to early reports on binding in vitro, small increases in distance between decamer half-sites greatly reduces p53 transactivation, as demonstrated for the natural TIGER RE. This was confirmed with human cell extracts using a newly developed, semi-in vitro microsphere binding assay. These results contrast with the synergistic increase in transactivation from a pair of weak, full-site REs in the MDM2 promoter that are separated by an evolutionary conserved 17 bp spacer. Surprisingly, there can be substantial transactivation at noncanonical (1/2)-(a single decamer) and (3/4)-sites, some of which were originally classified as biologically relevant canonical consensus sequences including PIDD and Apaf-1. p53 family members p63 and p73 yielded similar results. Efficient transactivation from noncanonical elements requires tetrameric p53, and the presence of the carboxy terminal, non-specific DNA binding domain enhanced transactivation from noncanonical sequences. Our findings demonstrate that RE sequence, organization, and level of p53 can strongly impact p53-mediated transactivation, thereby changing the view of what constitutes a functional p53 target. Importantly, inclusion of (1/2)- and (3/4)-site REs greatly expands the p53 master regulatory network.

Project description:The effects of diverse stresses on promoter selectivity and transcription regulation by the tumor suppressor p53 are poorly understood. We have taken a comprehensive approach to characterizing the human p53 network that includes p53 levels, binding, expression and chromatin changes under diverse stresses. Human osteosarcoma U2OS cells treated with anti-cancer drugs Doxorubicin (DXR) or Nutlin-3 (Nutlin) led to strikingly different p53 gene binding patterns based on chromatin immunoprecipitation with high-throughput sequencing experiments. Although two contiguous RRRCWWGYYY decamers is the consensus binding motif, p53 can bind a single decamer and function in vivo. Although the number of sites bound by p53 was six times greater for Nutlin than DXR, expression changes induced by Nutlin were much less dramatic compared with DXR. Unexpectedly, the solvent dimethylsulphoxide (DMSO) alone induced p53 binding to many sites common to DXR; however, this binding had no effect on target gene expression. Together, these data imply a two-stage mechanism for p53 transactivation where p53 binding only constitutes the first stage. Furthermore, both p53 binding and transactivation were associated with increased active histone modification histone H3 lysine 4 trimethylation. We discovered 149 putative new p53 target genes including several that are relevant to tumor suppression, revealing potential new targets for cancer therapy and expanding our understanding of the p53 regulatory network.

Project description:Transcriptional activation by the tumor suppressor p53 is considered to depend on cellular level, although there are few systems where this dependence on cellular level of p53 has been directly addressed. Previously, we reported that transactivation from p53 targets was sensitive to both p53 amount and DNA sequence, with some sequences being responsive to much lower p53 levels than others when examined in yeast model systems or human cells. Because p53 is normally present at low levels and perturbations might lead to small increases, we examined transactivation under limiting p53. Unlike the positive relationship between transactivation and binding affinity from target sequences at high cellular levels of human p53 in yeast, no such relationship was found at low levels. However, transactivation in the yeast system and the torsional flexibility of target sequences were highly correlated, revealing a unique structural relationship between transcriptional function and sequence. Surprisingly, a few sequences supported high transactivation at low p53 levels in yeast or when transfected into human cells. On the basis of kinetic and flexibility analyses the "supertransactivation" property was due to low binding off rates of flexible target sites. Interestingly, a supertransactivation response element can differentiate transcriptional capacities of many breast cancer-associated p53 mutants. Overall, these studies, which are relevant to other transcription factors, address the extent to which transactivation properties of p53 target sequences are determined by their intrinsic physical properties and reveal unique rules of engagement of target sequences at low p53 levels.

Project description:p53 is a master regulatory, sequence-specific transcription factor that directly controls expression of over 100 genes in response to various stress signals. Transactivation is generally considered to occur through p53 binding to a consensus response element (RE) composed of two 5'-RRRCWWGYYY-3' decamers. Recently, studying the human angiogenesis-related gene FLT1 we discovered that p53 can mediate limited transactivation at a noncanonical 1/2 site and could synergize with the estrogen receptor (ER) acting in cis at a nearby ER 1/2 site. To address the generality of concerted transactivation by p53 and ER, the 1/2 site in the FLT1 promoter was replaced with a variety of 1/2 sites, as well as canonical weak and strong p53 REs of human target genes. The p53 transactivation of all tested sequences was greatly enhanced by ligand-activated ER acting in cis. Furthermore, enhanced transactivation extends to several cancer-associated p53 mutants with altered function, suggesting ER-dependent mutant p53 activity for at least some REs. The enhanced transactivation was also found with p63 and p73. We propose a general synergistic relationship between p53 family and ER master regulators in transactivation of p53 target canonical and noncanonical REs, which might be poorly responsive to p53 on their own. This relationship greatly expands the transcriptional master network regulated by p53 in terms of genes affected and levels of expression and has implications for the appearance and possible treatments of cancer.

Project description:p53 is one of the most studied tumor suppressor proteins that plays an important role in basic biological processes including cell cycle, DNA damage response, apoptosis, and senescence. The human TP53 gene contains alternative promoters that produce N-terminally truncated proteins and can produce several isoforms due to alternative splicing. p53 function is realized by binding to a specific DNA response element (RE), resulting in the transactivation of target genes. Here, we evaluated the influence of quadruplex DNA structure on the transactivation potential of full-length and N-terminal truncated p53? isoforms in a panel of S. cerevisiae luciferase reporter strains. Our results show that a G-quadruplex prone sequence is not sufficient for transcription activation by p53? isoforms, but the presence of this feature in proximity to a p53 RE leads to a significant reduction of transcriptional activity and changes the dynamics between co-expressed p53? isoforms.

Project description:Mdm2, the principal negative regulator of p53, is critical for survival, a fact clearly demonstrated by the p53-dependent death of germline or conditional mice following deletion of Mdm2. On the other hand, Mdm2 hypomorphic (Mdm2Puro/?7-12) or heterozygous (Mdm2+/-) mice that express either 30 or 50% of normal Mdm2 levels, respectively, are viable but present distinct phenotypes because of increased p53 activity. Mdm2 levels are also transcriptionally regulated by p53. We evaluated the significance of this reciprocal relationship in a new hypomorphic mouse model inheriting an aberrant Mdm2 allele with insertion of the neomycin cassette and deletion of 184-bp sequence in intron 3. These mice also carry mutations in the Mdm2 P2-promoter and thus express suboptimal levels of Mdm2 entirely encoded from the P1-promoter. Resulting mice exhibit abnormalities in skin pigmentation and reproductive tissue architecture, and are subfertile. Notably, all these phenotypes are rescued on a p53-null background. Furthermore, these phenotypes depend on distinct p53 downstream activities as genetic ablation of the pro-apoptotic gene Puma reverts the reproductive abnormalities but not skin hyperpigmentation, whereas deletion of cell cycle arrest gene p21 does not rescue either phenotype. Moreover, p53-mediated upregulation of Kitl influences skin pigmentation. Altogether, these data emphasize tissue-specific p53 activities that regulate cell fate.

Project description:The tumor suppressor gene p53 encodes a transcriptional activator that has two transactivation domains (TAD) located in its amino terminus. These two TAD can transactivate genes independently, and at least one TAD is required for p53 transactivation function. The 1st TAD (a.a. 1-40) is essential for the induction of numerous classical p53 target genes, while the second TAD (a.a. 41-61) suffices for tumor suppression, although its precise molecular function remains unclear. In this study, we comprehensively identified the sites to which p53 lacking the 1st TAD (?1stTAD-p53) binds, as well as its potential target genes. We found that the binding sequences for ?1stTAD-p53 are divergent and include not only the canonical p53 consensus binding sequences but also sequences similar to those recognized by a number of other known transcription factors. We identified and analyzed the functions of three ?1stTAD-p53 target genes, PTP4A1, PLK2 and RPS27L. All three genes were induced by both full-length p53 and ?1stTAD-p53, and were dependent on the transactivation activity of the 2nd TAD. We also found that two of these, PTP4A1 and PLK2, are endoplasmic reticulum (ER) stress-inducible genes. We found that upon ER stress, PTP4A1 suppresses apoptosis while PLK2 induces apoptosis. These results reveal a novel ?1stTAD-p53 downstream pathway that is dependent on the transcription activation activity of the 2nd TAD.