FaceBase: A Community-Driven Hub for Data-Intensive Research.

The FaceBase Consortium, funded by the National Institute of Dental and Craniofacial Research of the National Institutes of Health, was established in 2009 with the recognition that dental and craniofacial research are increasingly data-intensive disciplines. Data sharing is critical for the validation and reproducibility of results as well as to enable reuse of data. In service of these goals, data ought to be FAIR: Findable, Accessible, Interoperable, and Reusable. The FaceBase data repository and educational resources exemplify the FAIR principles and support a broad user community including researchers in craniofacial development, molecular genetics, and genomics. FaceBase demonstrates that a model in which researchers "self-curate" their data can be successful and scalable. We present the results of the first 2.5 y of FaceBase's operations as an open community and summarize the data sets published during this period. We then describe a research highlight from work on the identification of regulatory networks and noncoding RNAs involved in cleft lip with/without cleft palate that both used and in turn contributed new findings to publicly available FaceBase resources. Collectively, FaceBase serves as a dynamic and continuously evolving resource to facilitate data-intensive research, enhance data reproducibility, and perform deep phenotyping across multiple species in dental and craniofacial research.

DNA methylation profiles in diffuse large B-cell lymphoma and their relationship to gene expression status.

In an initial epigenetic characterization of diffuse large B-cell lymphoma (DLBCL), we evaluated the DNA methylation levels of over 500 CpG islands. Twelve CpG islands (AR, CDKN1C, DLC1, DRD2, GATA4, GDNF, GRIN2B, MTHFR, MYOD1, NEUROD1, ONECUT2 and TFAP2A) showed significant methylation in over 85% of tumors. Interestingly, the methylation levels of a CpG island proximal to FLJ21062 differed between the activated B-cell-like (ABC-DLBCL) and germinal center B-cell-like (GCB-DLBCL) subtypes. In addition, we compared the methylation and expression status of 67 genes proximal (within 500 bp) to the methylation assays. We frequently observed that hypermethylated CpG islands are proximal to genes that are expressed at low or undetectable levels in tumors. However, many of these same genes were also poorly expressed in DLBCL tumors where their cognate CpG islands were hypomethylated. Nevertheless, the proportional reductions in BNIP3, MGMT, RBP1, GATA4, IGSF4, CRABP1 and FLJ21062 expression with increasing methylation suggest that epigenetic processes strongly influence these genes. Lastly, the moderate expression of several genes proximal to hypermethylated CpG tracts suggests that DNA methylation assays are not always accurate predictors of gene silencing. Overall, further investigation of the highlighted CpG islands as potential clinical biomarkers is warranted.

Molecular pathology of head and neck cancer.

Squamous cell carcinoma of the head and neck region (HNSCC) is the sixth most frequent cancer worldwide, comprising almost 50% of all malignancies in some developing nations. In the United States, 30,000 new cases and 8,000 deaths are reported each year. Survival rates vary depending on tobacco and alcohol consumption, age, gender, ethnic background, and geographic area. This variability reflects the multifactorial pathogenesis of the disease. Early detection and diagnosis has increased survival but the overall 5 year rate of 50% is among the lowest of the major cancers. Differences between normal epithelium and cancer cells of the upper aerodigestive tract arise from specific alterations in genes controlling DNA repair, proliferation, immortalization, apoptosis, invasion, and angiogenesis. These proteins include both tumor suppressors and activating oncogenes which regulate a wide variety of intracellular signaling pathways. Included in these pathways are growth factor receptors, signal transducers, and transcription factors which regulate DNA damage response, cell cycle arrest, and programmed cell death. In head and neck cancer, alterations of three signaling pathways occur with sufficient frequency and produce such dramatic phenotypic changes as to be considered the critical transforming events of the disease. These changes include mutation of the p53 tumor suppressor, inactivation of the cyclin dependent kinase inhibitor p16, and overexpression of epidermal growth factor receptor (EGFR). This review will focus on the molecular changes which occur in these pathways and how they contribute to the pathogenesis of HNSCC.

Genome of the apes.

The Human Genome Project has generated both the information and technological infrastructure needed to accelerate genetic comparisons between humans and the African great apes (chimpanzees and gorillas). Sequence and chromosomal organization differences between these highly related genomes will provide clues to the genetic basis for recently evolved, specifically human traits such as bipedal gait and advanced cognitive function. Recent studies comparing the primate genomes have the potential to affect many aspects of human biomedical research and could benefit primate conservation efforts.

Oligonucleotide microarray based detection of repetitive sequence changes.

Prior studies of oligonucleotide microarray-based mutational analysis have demonstrated excellent sensitivity and specificity except in circumstances where a frameshift mutation occurs in the context of a short repeated sequence. To further evaluate this circumstance, a series of nucleic acid samples having heterozygous mutations within repetitive BRCA1 sequence tracts was prepared and evaluated. These mutations included single nucleotide insertions and deletions in homopolymer runs, insertions and deletions of trinucleotide repeats, and duplications. Two-color comparative hybridization experiments were used wherein wild type reference and test targets are co-hybridized to microarrays designed to screen the entire BRCA1 coding sequence for all possible sequence changes. Mutations in simulated heterozygote samples were detected by observing relative losses of test target hybridization signal to select perfect match oligonucleotide probes. While heterozygous mutations could be readily distinguished above background noise in 9/19 cases, it was not possible to detect alterations in a poly dA/dT tract, small triplet repeat expansions, and a 10 bp direct repeat. Unexpectedly, samples containing (GAT)(3) triplet repeat expansions showed significantly higher affinity toward specific perfect match probes relative to their wild type counterparts. Therefore, markedly increased as well as decreased test sample hybridization to perfect match probes should be used to raise a suspicion of repetitive sequence changes.

Mutational analysis using oligonucleotide microarrays.

The development of inexpensive high throughput methods to identify individual DNA sequence differences is important to the future growth of medical genetics. This has become increasingly apparent as epidemiologists, pathologists, and clinical geneticists focus more attention on the molecular basis of complex multifactorial diseases. Such undertakings will rely upon genetic maps based upon newly discovered, common, single nucleotide polymorphisms. Furthermore, candidate gene approaches used in identifying disease associated genes necessitate screening large sequence blocks for changes tracking with the disease state. Even after such genes are isolated, large scale mutational analyses will often be needed for risk assessment studies to define the likely medical consequences of carrying a mutated gene. This review concentrates on the use of oligonucleotide arrays for hybridisation based comparative sequence analysis. Technological advances within the past decade have made it possible to apply this technology to many different aspects of medical genetics. These applications range from the detection and scoring of single nucleotide polymorphisms to mutational analysis of large genes. Although we discuss published scientific reports, unpublished work from the private sector could also significantly affect the future of this technology.

Design of modified oligodeoxyribonucleotide probes to detect telomere repeat sequences in FISH assays.

A series of dye-labeled oligonucleotide probes containing base and sugar modifications were tested for the ability to detect telomeric repeat sequences in FISH assays. These modified oligonucleotides, all 18 nt in length, were complementary to either the cytidine-rich (C(3)TA(2))(n)or guanosine-rich (T(2)AG(3))(n)telomere target sequences. Oligonucleotides were modified to either increase target affinity by enhancing duplex stability [2'-OMe ribose sugars and 5-(1-propynyl)pyrimidine residues] or inhibit the formation of inter- or intramolecular structures (7-deazaguanosine and 6-thioguanosine residues), which might interfere with binding to the target. Several dye-labeled oligonucleotide probes were found that could effectively stain the telomeric repeat sequences of either cytidine- or guanosine-rich strands in a specific manner. Such probes could be used as an alternative to peptide nucleic acids for investigating the dynamics of telomere length and maintenance. In principle, these relatively inexpensive and readily synthesized modified oligonucleotides could be used for other FISH-related assays.

Determination of ancestral alleles for human single-nucleotide polymorphisms using high-density oligonucleotide arrays.

Here we report the application of high-density oligonucleotide array (DNA chip)-based analysis to determine the distant history of single nucleotide polymorphisms (SNPs) in current human populations. We analysed orthologues for 397 human SNP sites (identified in CEPH pedigrees from Amish, Venezuelan and Utah populations) from 23 common chimpanzee, 19 pygmy chimpanzee and 11 gorilla genomic DNA samples. From this data we determined 214 proposed ancestral alleles (the sequence found in the last common ancestor of humans and chimpanzees). In a diverse human population set, we found that SNP alleles with higher frequencies were more likely to be ancestral than less frequently occurring alleles. There were, however, exceptions. We also found three shared human/pygmy chimpanzee polymorphisms, all involving CpG dinucleotides, and two shared human/gorilla polymorphisms, one involving a CpG dinucleotide. We demonstrate that microarray-based assays allow rapid comparative sequence analysis of intra- and interspecies genetic variation.

Resequencing and mutational analysis using oligonucleotide microarrays.

Oligonucleotide microarray (DNA chip)-based hybridization analysis is a promising new technology which potentially allows rapid and cost-effective screens for all possible mutations and sequence variations in genomic DNA. Here, I review current strategies and uses for DNA chip-based resequencing and mutational analysis, the underlying principles of experimental designs, and future efforts to improve the sensitivity and specificity of chip-based assays.

Applications of DNA chips for genomic analysis.

A major frontier in medical genetics is the definition of the molecular basis of multifactorial diseases. This is especially relevant in the field of clinical psychiatry where the majority of common disorders display complex inheritance patterns, and are further influenced by environmental interactions. New technologies are needed to help address the pressing needs for discovering and deciphering the nature of such disease-associated genes. One such technology which has emerged within the past 3 years involves hybridization-based nucleic acid array (DNA chip) analysis. This technology has the potential to have a lasting impact on diverse genomic-based applications such as large-scale gene mapping studies, mutational analysis, and global expression level monitoring of all human genes. In this review we will describe the fundamental principles behind nucleic acid array-based assays, while focusing on their applications towards genome-wide DNA and RNA analysis. The current capabilities and limitations of these technologies will be discussed, with a focus on areas where future development will be needed for DNA chip-based assays to achieve their full potential.

Enhanced high density oligonucleotide array-based sequence analysis using modified nucleoside triphosphates.

Pairs of high density oligonucleotide arrays (DNA chips) consisting of >96 000 oligonucleotides were designed to screen the entire 5.53 kb coding region of the hereditary breast and ovarian cancer BRCA1 gene for all possible sequence changes in the homozygous and heterozygous states. Single-stranded RNA targets were generated by PCR amplification of individual BRCA1 exons using primers containing T3 and T7RNA polymerase promoter tails followed by in vitro transcription and partial fragmentation reactions. Fluorescent hybridization signals from targets containing the four natural bases to >5592 different fully complementary 25mer oligonucleotide probes on the chip varied over two orders of magnitude. To examine the thermodynamic contribution of rU.dA and rA.dT target.probe base pairs to this variability, modified uridine [5-methyluridine and 5-(1-propynyl)-uridine)] and modified adenosine (2,6-diaminopurine riboside) 5'-triphosphates were incorporated into BRCA1 targets. Hybridization specificity was assessed based upon hybridization signals from >33 200 probes containing centrally localized single base pair mismatches relative to target sequence. Targets containing 5-methyluridine displayed promising localized enhancements in hybridization signal, especially in pyrimidine-rich target tracts, while maintaining single nucleotide mismatch hybridization specificities comparable with those of unmodified targets.

Two color hybridization analysis using high density oligonucleotide arrays and energy transfer dyes.

High density oligonucleotide arrays (DNA chips) have been used in two color mutational analysis of the 3.43 kb exon 11 of the hereditary breast and ovarian cancer gene BRCA1 . Two color analysis allows competitive hybridization between a reference standard and an unknown sample, improving the performance of the assay. Fluorescein and phycoerythrin dyes werepreviously used due to their compatibility with a single line 488 nm excitation source. Here we show that an alternative dye combination, containing the energy transfer dye system phycoerythrin*cy5 along with phycoerythrin, provides more evenly matched signal intensities and decreased spectral overlap between the two fluorophores, while maintaining compatibility with a 488 nm excitation source.

Structure of a stereoregular phosphorothioate DNA/RNA duplex.

In this work, we present the first NMR solution structure of a DNA/RNA hybrid containing stereoregular Rp-phosphorothioate modifications of all DNA backbone linkages. The complex of the enzymatically synthesized phosphorothioate DNA octamer (all-Rp)-d(GCGTCAGG) and its complementary RNA r(CCUGACGC) was found to adopt an overall conformation within the A-form family. Most helical parameters and the sugar puckers of the DNA strand assume values intermediate between A- and B-form. The close structural similarity with the unmodified DNA/RNA hybrid of the same sequence may explain why both the natural and the sulfur-substituted complex can be recognized and digested by ribonuclease H.

Evolutionary sequence comparisons using high-density oligonucleotide arrays.

We explored the utility of high-density oligonucleotide arrays (DNA chips) for obtaining sequence information from homologous genes in closely related species. Orthologues of the human BRCA1 exon 11, all approximately 3.4 kb in length and ranging from 98.2% to 83.5% nucleotide identity, were subjected to hybridization-based and conventional dideoxysequencing analysis. Retrospective guidelines for identifying high-fidelity hybridization-based sequence calls were formulated based upon dideoxysequencing results. Prospective application of these rules yielded base-calling with at least 98.8% accuracy over orthologous sequence tracts shown to have approximately 99% identity. For higher primate sequences with greater than 97% nucleotide identity, base-calling was made with at least 99.91% accuracy covering a minimum of 97% of the sequence. Using a second-tier confirmatory hybridization chip strategy, shown in several cases to confirm the identity of predicted sequence changes, the complete sequence of the chimpanzee, gorilla and orangutan orthologues should be deducible solely through hybridization-based methodologies. Analysis of less highly conserved orthologues can still identify conserved nucleotide tracts of at least 15 nucleotides and can provide useful information for designing primers. DNA-chip based assays can be a valuable new technology for obtaining high-throughput cost-effective sequence information from related genomes.

Strategies for mutational analysis of the large multiexon ATM gene using high-density oligonucleotide arrays.

Mutational analysis of large genes with complex genomic structures plays an important role in medical genetics. Technical limitations associated with current mutation screening protocols have placed increased emphasis on the development of new technologies to simplify these procedures. High-density arrays of >90,000-oligonucleotide probes, 25 nucleotides in length, were designed to screen for all possible heterozygous germ-line mutations in the 9.17-kb coding region of the ATM gene. A strategy for rapidly developing multiexon PCR amplification protocols in DNA chip-based hybridization analysis was devised and implemented in preparing target for the 62 ATM coding exons. Improved algorithms for interpreting data from two-color experiments, where reference and test samples are cohybridized to the arrays, were developed. In a blinded study, 17 of 18 distinct heterozygous and 8 of 8 distinct homozygous sequence variants in the assayed region were detected accurately along with five false-positive calls while scanning >200 kb in 22 genomic DNA samples. Of eight heterozygous sequence changes found in more than one sample, six were detected in all cases. Five previously unreported sequence changes, not found by other mutational scanning methodologies on these same samples, were detected that led to either amino acid changes or premature truncation of the ATM protein. DNA chip-based assays should play a valuable role in high throughput sequence analysis of complex genes.

New approaches to BRCA1 mutation detection.

The development of technologies to identify quickly, efficiently, and inexpensively all possible heterozygous mutations and sequence variants in patient samples will play a crucial role in the future of medical genetics. In addition to the continued refinement of more established mutation detection protocols, several innovative methodologies recently have emerged with the potential to increase sample throughput as well as decrease the cost of mutational analysis. The allelic heterogeneity of BRCA1 mutations serves as an example of the considerable technical challenge in developing diagnostic tests for all possible sequence variants in large genes. We describe recent advances in methologies that have previously been or could be readily adapted for use in BRCA1 mutation detection. Special emphasis is placed on the use of high density oligonucleotide arrays (DNA chips) as tools for detecting sequence variations in BRCA1.

Detection of heterozygous mutations in BRCA1 using high density oligonucleotide arrays and two-colour fluorescence analysis.

The ability to scan a large gene rapidly and accurately for all possible heterozygous mutations in large numbers of patient samples will be critical for the future of medicine. We have designed high-density arrays consisting of over 96,600 oligonucleotides 20-nucleotides (nt) in length to screen for a wide range of heterozygous mutations in the 3.45-kilobases (kb) exon 11 of the hereditary breast and ovarian cancer gene BRCA1. Reference and test samples were co-hybridized to these arrays and differences in hybridization patterns quantitated by two-colour analysis. Fourteen of fifteen patient samples with known mutations were accurately diagnosed, and no false positive mutations were identified in 20 control samples. Eight single nucleotide polymorphisms were also readily detected. DNA chip-based assays may provide a valuable new technology for high-throughput cost-efficient detection of genetic alterations.

Phosphorothioate oligonucleotide-directed triple helix formation.

Phosphorothioate oligodeoxyribonucleotides were tested for their ability to recognize double-helical DNA in two distinct triple helix motifs. Purine-rich oligonucleotides containing a diastereomeric mixture of phosphorothioate or stereoregular (all RP) phosphorothioate linkages are shown to form triple-helical complexes with affinities similar to those of the corresponding natural phosphodiester oligonucleotides. In contrast, pyrimidine-rich phosphorothioate oligonucleotides containing a mixture of diastereomeric or stereoregular (all RP) linkages do not bind to double-helical DNA with measurable affinity. These observations have implications for triple helix structure and for biological applications.

Inhibition of Klenow fragment DNA polymerase on double-helical templates by oligonucleotide-directed triple-helix formation.

We have examined the capacity of oligonucleotide-directed triple helices to block the progress of primer extension by DNA polymerase. Occupancy of the major groove of a double-helical DNA substrate obstructed Klenow fragment progress at sites that map near the proximal boundary between duplex and triplex. Among a family of related third-strand oligonucleotides that all stably occupied the target duplex in the absence of polymerase, those forming longer triplexes were more effective polymerase inhibitors than shorter complexes. Kinetic analysis revealed that the triple-helical complex provided an effective blockade for times of at least 20 min. These observations provide the basis for considering and further dissecting repair DNA polymerase function and mechanism by using various defined local three-stranded DNA structures as probes.