Project description:Species-specific genes play an important role in defining the phenotype of an organism. However, current gene prediction methods can only efficiently find genes that share features such as sequence similarity or general sequence characteristics with previously known genes. Novel sequencing methods and tiling arrays can be used to find genes without prior information and they have demonstrated that novel genes can still be found from extensively studied model organisms. Unfortunately, these methods are expensive and thus are not easily applicable, e.g., to finding genes that are expressed only in very specific conditions. We demonstrate a method for finding novel genes with sparse arrays, applying it on the 33.9 Mb genome of the filamentous fungus Trichoderma reesei. Our computational method does not require normalisations between arrays and it takes into account the multiple-testing problem typical for analysis of microarray data. In contrast to tiling arrays, that use overlapping probes, only one 25mer microarray oligonucleotide probe was used for every 100 b. Thus, only relatively little space on a microarray slide was required to cover the intergenic regions of a genome. The analysis was done as a by-product of a conventional microarray experiment with no additional costs. We found at least 23 good candidates for novel transcripts that could code for proteins and all of which were expressed at high levels. Candidate genes were found to neighbour ire1 and cre1 and many other regulatory genes. Our simple, low-cost method can easily be applied to finding novel species-specific genes without prior knowledge of their sequence properties. Experiment consists of three conditions relevant for study of protein secretion, growth rate D=0.03 h-1, growth rate D=0.06 h-1 and growth rate D=0.03 h-1 with high cell density. Each condition has three biological repeats thus there are nine chemostat cultivations.

Project description:We have developed a double-tiling method that effectively doubles the number of sequences on a microarray, and with these arrays we confirm that our design can be utilized quickly and easily. Keywords: testing novel microarray design

Project description:High-density oligonucleotide tiling-microarrays are currently providing a powerful tool for genome-wide in vivo DNA footprinting assays, yielding unprecedented insights into tissuespecific protein-DNA interactions and chromatin structure. Despite the impressive advances, however, the technology still suffers from numerous complications caused by background noise and probespecific effects. A few computational methods modeling sequencerelated probe effects are now available for Affymetrix tiling arrays, but no counterpart is yet available for two-color arrays. A novel normalization method based on the GC content of probes is developed for two-color tiling-arrays. The proposed method, together with robust estimates of the model parameters, is shown to perform superbly on published data sets. Accompanying the normalization method, a robust algorithm for detecting peak regions is formulated and also shown to perform well compared to other approaches. The tools presented herein have been implemented for NimbleGen tiling arrays as a stand-alone Java program, which can also display various plots of statistical analysis for quality control of experiments. Upon changing the file format, the program also works on Agilent data. Keywords: ChIP-chip

Project description:The number of methods for pre-processing and analysis of gene expression data continues to increase, often making it difficult to select the most appropriate approach. We present a simple procedure for the comparative estimation of a variety of methods for microarray data pre-processing and analysis. Our approach is based on the use of real microarray data in which controlled fold changes are introduced into 20% of the data to provide a metric for comparison with the unmodified data. The data modification can be easily applied to raw data measured with any technological platform and retains all the complex structures and statistical characteristics of the real-world data. The power of the method is illustrated by its application to a comparative analysis of the significance analysis of microarray (SAM), Limma, and associative analysis tuned to the exact structure of the experimental data. We present a novel finding that SAM and Limma analyses fail to detect the most interesting differentially expressed genes at high expression level, while the associative analysis does recognize them. Our results demonstrate that the method of controlled modifications of real experimental data provides a simple tool for assessing the performance of data preprocessing and analysis methods.

Project description:The number of methods for pre-processing and analysis of gene expression data continues to increase, often making it difficult to select the most appropriate approach. We present a simple procedure for the comparative estimation of a variety of methods for microarray data pre-processing and analysis. Our approach is based on the use of real microarray data in which controlled fold changes are introduced into 20% of the data to provide a metric for comparison with the unmodified data. The data modification can be easily applied to raw data measured with any technological platform and retains all the complex structures and statistical characteristics of the real-world data. The power of the method is illustrated by its application to a comparative analysis of the significance analysis of microarray (SAM), Limma, and associative analysis tuned to the exact structure of the experimental data. We present a novel finding that SAM and Limma analyses fail to detect the most interesting differentially expressed genes at high expression level, while the associative analysis does recognize them. Our results demonstrate that the method of controlled modifications of real experimental data provides a simple tool for assessing the performance of data preprocessing and analysis methods. 20 samples of Epstein-Barr Virus-transformed B cells collected from normal healthy donors. All samples were biological. No treatment were introduced, and the whole group of 20 samples is presumably homogeneous

Project description:We describe a method, MADS (Microarray Analysis of Differential Splicing), for discovery of differential alternative splicing from exon tiling microarrays. MADS incorporates a series of low-level analysis algorithms motivated by the “probe-rich” design of exon arrays, including background correction, iterative probe selection, and removal of sequence-specific cross-hybridization to off-target transcripts. We used MADS to analyze Affymetrix Exon 1.0 array data on a mouse neuroblastoma cell line after shRNA-mediated knockdown of the splicing factor PTB. From a list of exons with pre-determined inclusion/exclusion profiles in response to PTB depletion, MADS recognized all exons known to have large changes in transcript inclusion levels, and offered improvement over Affymetrix’s analysis procedure. We also identified numerous novel PTB-dependent splicing events. 30 novel events were tested by RT-PCR, and 27 were confirmed. This work demonstrates that the exon tiling microarray design is an efficient and powerful approach for global, unbiased analysis of pre-mRNA splicing. Keywords: control / knockdown comparison

Project description:A ruler array combines novel sample preparation protocols, tiling genomic microarrays, and a new computational method to turn each probe on a microarray into a ruler that measures the physical distance between defined genomic sequences regardless of the intervening sequence. The ruler array protocol involves (1) genomic DNA purification (2) digestion with a restriction enzyme (3) ligation of a biotinylated adapter molecule to the cut sites (4) purification on streptavidin beads (5) polymerase extensions from a primer complementary to the adapter using labeled dNTPs and (6) hybridization to a tiling microarray

Project description:Microarray analysis is being performed with cultivated selections using custom designed arrays. Custom designed arrays include the design of microarray probes using clearly described bioinformatics methods. We have used the sequence data related to fungal resistance from Camellia Sp. and Arabidopsis thaliana available in the biological databases, to design these arrays. Results of this work will help us to understand the genes expressed during the blister blight and grey blight infection.

Project description:Detecting novel genes with sparse arrays

Project description:The majority of all genes have so far been identified and annotated systematically through in silico gene finding. Here we report the finding of 3,217 strand-specific Transcriptionally Active Regions (TARs) in the genome of Bacillus subtilis by the use of tiling arrays. We have measured the genome-wide expression during mid-exponential growth on rich (LB) and minimal (M9) medium. The identified TARs account for 81.5% of the genes as they are currently annotated and additionally we find 44 novel protein-coding genes, 85 putative non-coding RNAs (ncRNAs) and 184 antisense transcripts. Hybridization of labeled genomic DNA (gDNA) has revealed a few thousand regions giving rise to very low signals. These are mostly caused by sequence errors, as is observed in the highly degenerate trp operon and the folding of stable structures such as the regions containing Rho-independent terminators. Through this work we have discovered a group of membrane-associated genes, among these having a long conserved 3’ UnTranslated Region (UTR) predicted to fold into a large and highly stable structure. Among these are YwbN, a target of the twin-arginine translocase (Tat) protein translocation system.