Project description:Background Housekeeping genes (HKG) are constitutively expressed in all tissues while tissue-enriched genes (TEG) are expressed at a much higher level in a single tissue type than in others. HKGs serve as valuable experimental controls in gene and protein expression experiments, while TEGs tend to represent distinct physiological processes and are frequently candidates for biomarkers or drug targets. The genomic features of these two groups of genes expressed in opposing patterns may shed light on the mechanisms by which cells maintain basic and tissue-specific functions. Results Here, we generate gene expression profiles of 42 normal human tissues on custom high-density microarrays to systematically identify 1,522 HKGs and 975 TEGs and compile a small subset of 20 housekeeping genes that can be used as experimental reference and are superior to many commonly used HKGs. Cross-species comparison shows that both the functions and expression patterns of HKGs are conserved. TEGs are enriched with respect to both segmental duplication and copy number variation, while no such enrichment is observed for HKGs, suggesting the high expression of HKGs are not due to high copy numbers. Analysis of genomic and epigenetic features of HKGs and TEGs reveals that the high expression of HKGs across different tissues is associated with decreased nucleosome occupancy at the transcription start site as indicated by enhanced DNase hypersensitivity. Additionally, we systematically and quantitatively demonstrated that the CpG islands' enrichment in HKGs transcription start sites (TSS) and their depletion in TEGs TSS. Histone methylation patterns differ significantly between HKGs and TEGs, suggesting that methylation contributes to the differential expression patterns as well. Conclusions We have compiled a set of high quality HKGs that should provide higher and more consistent expression when used as references in laboratory experiments than currently used HKGs. The comparison of genomic features between HKGs and TEGs shows that HKGs are more conserved than TEGs in terms of functions, expression pattern and polymorphisms. In addition, our results identify chromatin structure and epigenetic features of HKGs and TEGs that are likely to play an important role in regulating their strikingly different expression patterns. PolyA+ purified RNA pooled from multiple donors of a single human tissue type (e.g. cerebellum) were amplified with random primers and hybridized on a two-color ink-jet oligonucletodie microarray against a common reference pool, comprising ~20 normal adult tissue pools, on custom microarray patterns. Total 42 normal human tissues were testes against the pools. This dataset is part of the TransQST collection.

Project description:Housekeeping genes (HKG) are constitutively expressed in all tissues while tissue-enriched genes (TEG) are expressed at a much higher level in a single tissue type than in others. HKGs serve as valuable experimental controls in gene and protein expression experiments, while TEGs tend to represent distinct physiological processes and are frequently candidates for biomarkers or drug targets. The genomic features of these two groups of genes expressed in opposing patterns may shed light on the mechanisms by which cells maintain basic and tissue-specific functions. Here, we generate gene expression profiles of 42 normal human tissues on custom high-density microarrays to systematically identify 1,522 HKGs and 975 TEGs and compile a small subset of 20 housekeeping genes which are highly expressed in all tissues with lower variance than many commonly used HKGs. Cross-species comparison shows that both the functions and expression patterns of HKGs are conserved. TEGs are enriched with respect to both segmental duplication and copy number variation, while no such enrichment is observed for HKGs, suggesting the high expression of HKGs are not due to high copy numbers. Analysis of genomic and epigenetic features of HKGs and TEGs reveals that the high expression of HKGs across different tissues is associated with decreased nucleosome occupancy at the transcription start site as indicated by enhanced DNase hypersensitivity. Additionally, we systematically and quantitatively demonstrated that the CpG islands' enrichment in HKGs transcription start sites (TSS) and their depletion in TEGs TSS. Histone methylation patterns differ significantly between HKGs and TEGs, suggesting that methylation contributes to the differential expression patterns as well.We have compiled a set of high quality HKGs that should provide higher and more consistent expression when used as references in laboratory experiments than currently used HKGs. The comparison of genomic features between HKGs and TEGs shows that HKGs are more conserved than TEGs in terms of functions, expression pattern and polymorphisms. In addition, our results identify chromatin structure and epigenetic features of HKGs and TEGs that are likely to play an important role in regulating their strikingly different expression patterns.

Project description:Housekeeping genes (HKG) are constitutively expressed in all tissues while tissue-enriched genes (TEG) are expressed at a much higher level in a single tissue type than in others. HKGs serve as valuable experimental controls in gene and protein expression experiments, while TEGs tend to represent distinct physiological processes and are frequently candidates for biomarkers or drug targets. The genomic features of these two groups of genes expressed in opposing patterns may shed light on the mechanisms by which cells maintain basic and tissue-specific functions. Here, we generate gene expression profiles of 42 normal human tissues on custom high-density microarrays to systematically identify 1,522 HKGs and 975 TEGs and compile a small subset of 20 housekeeping genes which are highly expressed in all tissues with lower variance than many commonly used HKGs. Cross-species comparison shows that both the functions and expression patterns of HKGs are conserved. TEGs are enriched with respect to both segmental duplication and copy number variation, while no such enrichment is observed for HKGs, suggesting the high expression of HKGs are not due to high copy numbers. Analysis of genomic and epigenetic features of HKGs and TEGs reveals that the high expression of HKGs across different tissues is associated with decreased nucleosome occupancy at the transcription start site as indicated by enhanced DNase hypersensitivity. Additionally, we systematically and quantitatively demonstrated that the CpG islands' enrichment in HKGs transcription start sites (TSS) and their depletion in TEGs TSS. Histone methylation patterns differ significantly between HKGs and TEGs, suggesting that methylation contributes to the differential expression patterns as well.We have compiled a set of high quality HKGs that should provide higher and more consistent expression when used as references in laboratory experiments than currently used HKGs. The comparison of genomic features between HKGs and TEGs shows that HKGs are more conserved than TEGs in terms of functions, expression pattern and polymorphisms. In addition, our results identify chromatin structure and epigenetic features of HKGs and TEGs that are likely to play an important role in regulating their strikingly different expression patterns. We performed microarray experiment on more tissues and probesets in additional to the previous GEO submission (Series GSE11863). In brief, PolyA+ purified RNA pooled from multiple donors of a single human tissue type (e.g. cerebellum) were amplified with random primers and hybridized on a two-color ink-jet oligonucletodie microarray against a common reference pool, comprising ~20 normal adult tissue pools, on custom microarray patterns containing probes to monitor every exon and exon-exon junction in transcript databases, patent databases, and predicted from mouse transcripts. Data were analyzed for gene expression (the average of multiple probes), exon and junction expression, and splice form proportionality.

Project description:The clinical and pathological features of early-onset colorectal cancer (EOCRC) differ from those of late-onset colorectal cancer (LOCRC). Our research aims to thoroughly elucidate the distinctions between them by analyzing clinical prognosis, metastatic patterns, gene expression, and genomic mutation profiles. Our deliberation will uncover latent strategies for personalized therapeutic of both EOCRC and LOCRC.

Project description:Metaphase chromosome staining was used to provide a high level overview of the pattern of histone modifications (H3K27ac, H3K27me3 and H3K4me3) at a single cell level in human lymphoblastois cells. These epigenomic banding patterns were related to various genomic features including gene and CpG island density as well as gene expression.

Project description:To systematically profile and characterize miRNA expression pattern in the lesion epicenter of spinal tissues after traumatic spinal cord injury (TSCI). We used RNA-Seq to profle the expression and regulation patterns of miRNAs of mice models after TSCI. A total of 155 miRNAs were identified in TSCI mice models to be differentially expressed.

Project description:One model for how cells integrate cis-regulatory information is that housekeeping and developmental core promoters respond specifically to certain types of enhancers or chromatin features at different chromosomal locations. We tested this model using a genome-integrated massively parallel reporter assay (MPRA) to measure the activity of hundreds of diverse core promoters at four genomic locations While genomic locations had large effects on expression, the relative strengths of core promoters were preserved across locations regardless of promoter class, suggesting that their intrinsic activities are scaled at different genomic locations. We further show that core promoter scaling is a genome-wide phenomenon by testing six core promoters at thousands of locations across the genome. While the rank order of core promoters is preserved, the scaling of expression across the genome is non-linear and depends on the genomic location and the strength of the core promoter, but not on its class, suggesting that housekeeping and developmental promoters do not make different interactions with the surrounding genomic environment. Instead, our results support a modular genome in which genomic environments containing different enhancers and chromatin features scale the activities of core promoters in an independent, but non-linear manner.

Project description:We addressed the lack of experimentally supported transcript annotations in the Rhesus macaque genome by ab initio identification of the transcription start sites (TSSs). We took advantage of histone H3 lysine 4 trimethylation (H3K4me3)'s ability to mark TSSs and the recently developed ChIP-Seq and RNA-Seq technology to survey the transcript structures in the macaque brain. We then integrated the two types of our newly generated data with genomic sequence features and extended a TSS prediction algorithm to ab initio predict and verify 16,833 of previously electronically annotated transcription start sites at 500 bp resolution and predicted ~10,000 new TSSs. We took advantage of histone H3 lysine 4 trimethylation (H3K4me3)M-bM-^@M-^Ys ability to mark transcription start sites (TSSs) and the recently developed ChIP-Seq and RNA-Seq technology to survey the transcript structures. By integrating the ChIP-seq, RNA-seq and small RNA-seq data (previously uploaded to GEO as GSM450615 by our collaborator) with genomic sequence features and extending and improving a state-of-the-art TSS prediction algorithm, we ab initio predicted and verified previously electronically annotated TSSs at a high resolution, and predicted some novel TSSs.

Project description:Research using the oyster Crassostrea gigas as a model has experienced a rapid growth in recent years thanks to the development of high throughput molecular technologies. As many as 56,268 EST sequences have so far been sequenced, representing a genome-wide resource that can be used for microarray investigations. We have developed an oyster microarray containing cDNAs representing 31,918 unique transcribed sequences. The genes spotted on the array have been selected from the publicly accessible GigasDatabase established from cDNA libraries derived from a wide variety of tissues and different developmental stages. n this paper, we report the transcriptome of male and female gonads, mantle, gills, posterior adductor muscle, visceral ganglion, hemocytes, labial palps and digestive gland. Following validation of the microarray, statistical analyses were used to identify genes differentially expressed among tissues and define clusters of tissue-specific genes. These genes reflect well major tissue-specific functions at the molecular level. Analysis of hierarchical clustering data also predicted the involvement of un-annotated genes in selected functional pathways. In a second instance, microarray data were used to accurately select housekeeping genes common to all tissues. Their expression profiles was compared to common oyster standard genes used for quantitative RT-PCR calibration (actin, g3apdh and ef1α). The novel candidate housekeeping gene, adp-ribosylation factor 1 (arf1) and g3apdh gene seem to be more robust for normalizing gene expression data of tissues. This study provides a new source for annotating the oyster genome. It also identified new candidate housekeeping genes, a prerequisite for accurate quantitative RT-PCR expression profiling.

Project description:BACKGROUND AND OBJECTIVES: Low-grade B-cell lymphomas include several subtypes of tumors with different degrees of histological, biological or clinical features. Differential diagnosis is frequently compromised by the lack of specific cytogenetic or molecular features. As a consequence, therapies remain in many lymphoma types largely based in common protocols with largely variable success. Our objectives were to describe and to compare the genomic profile of a series of samples from the most prevalent low-grade lymphoma subtypes; all of them systematically analyzed with the same approach. DESIGN-AND-METHODS: We carried out a high-resolution genomic DNA analysis (44K probes) in 87 low grade B cell lymphoma tumor samples that unambiguously presented the clinical picture, analytical features, and peripheral blood morphology and phenotype described for each entity. RESULTS: The genomic integrity of the samples was heavily compromised (80% of the tumors presented at least one aberration). This phenomenon also involved lymphoplasmocytic and marginal zone lymphomas that have not been previously studied by this genomic approach. New aberrations have been described for almost every subtype. We have also generated reports of the extension of the genomic instability, detecting distinct patterns of genomic instability within subtypes. INTERPRETATION-AND-CONCLUSIONS: The genomic profile of each subgroup showed substantive differences. The bioinformatic analysis of the data detected a set of new aberrations which were present in the majority of the subgroups and that pointed out to specific pathways, such as NF-kB (gains that involved REL, BCL11A and COMMD1) or DNA repair checkpoint pathways (deletion of 16q24 involving CDT1). Experiment Overall Design: Comparative experiment: pheripheral blood pool of ten healthy female donors: CONTROL vs. 87 Low grade Lymphoma tumour samples