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http://www.ebi.ac.uk/Tools/blast2/index.html
It is used to compare a novel sequence with those contained in nucleotide and protein databases by aligning the novel sequence with previously characterized genes.
Proper citation: Washington University Basic Local Alignment Search Tool (RRID:SCR_008285) Copy
http://www.uwstructuralgenomics.org/
It is a specialized research center supported by the Protein Structure Initiative (PSI) of the National Institute of General Medical Sciences (NIGMS), one of the National Institutes of Health (NIH). PSI is a federal, university, and industry effort aimed at dramatically reducing the costs and lessening the time it takes to determine a three-dimensional protein structure. The long-range goal of PSI is to solve 10,000 protein structures in 10 years and to make the three-dimensional atomic-level structures of most proteins easily obtainable from knowledge of their corresponding DNA sequences. CESG is located within the Department of Biochemistry at the University of Wisconsin-Madison (Madison, WI) and the Department of Biochemistry at the Medical College of Wisconsin (Milwaukee, WI). CESG develops new methods and technologies to address unique eukaryotic bottlenecks and disseminates its methodologies and experimental results to the scientific community worldwide through: :- Cell-Free Protein Production Workshops :- Plasmids at PSI Materials Repository :- Posters Presented at Scientific Meetings :- Publications in PubMed / PubMed Central :- Sesame (LIMS) Available for Researchers :- Solved Structures in the Protein Data Bank :- Technology Dissemination Reports They have welcomed requests by researchers to solve eukaryotic protein structures, particularly medically relevant proteins, through our Online Structure Request System for Researchers. They have solved many community-nominated targets and deposited information about these targets in public databases and published on our investigations and findings. Sponsors: CESG is supported by NIH / NIGMS Protein Structure Initiative grant numbers U54 GM074901 and P50 GM064598.
Proper citation: CESG (RRID:SCR_008451) Copy
Center for Computational Biology as a joint research center in the McKusick-Nathans Institute of Genetic Medicine, spanning the School of Medicine, the Whiting School of Engineering, the Bloomberg School of Public Health, and the Krieger School of Arts & Sciences. Multidisciplinary center dedicated to research on genomics, genetics, DNA sequencing technology, and computational methods for DNA and RNA sequence analysis.
Proper citation: Center for Computational Biology at JHU (RRID:SCR_016680) Copy
Ratings or validation data are available for this resource
Human and mouse genome annotation project which aims to identify all gene features in the human genome using computational analysis, manual annotation, and experimental validation.
Proper citation: GENCODE (RRID:SCR_014966) Copy
https://www.ncbi.nlm.nih.gov/genbank/tbl2asn2/
Software tool as a command-line program that automates the creation of sequence records for submission to GenBank. Records need no additional manual editing before submission.
Proper citation: tbl2asn (RRID:SCR_016636) Copy
https://github.com/asdcid/Gene-conservation-informed-contig-alignment
Software tool for separation haplotigs from genome assembly. Method to separate haplotigs based on sequence similarity.
Proper citation: Gene-conservation-informed-contig-alignment (RRID:SCR_017617) Copy
https://github.com/ruanjue/smartdenovo
Software tool as de novo assembler for PacBio and Oxford Nanopore data. It produces assembly from all-vs-all raw read alignments without error correction stage. Allows to read overlapping, rescue missing overlaps, identify low-quality regions and chimaera and produce better consensus.
Proper citation: SMARTdenovo (RRID:SCR_017622) Copy
https://github.com/brentp/duphold
Software tool to annotate structural variant calls with sequence depth information that can add or remove confidence to SV predicted to affect copy number. Indicates the presence of a rapid change in depth relative to the regions surrounding the breakpoints. Allows the run time to be nearly independent of the number of variants important for large, jointly called projects with many samples. Annotates structural variant predictions made from both short read and long read data.
Proper citation: duphold (RRID:SCR_016938) Copy
https://chlorobox.mpimp-golm.mpg.de/OGDraw.html
Software package for graphical visualization of organellar genomes. Converts annotations in GenBank format into graphical maps. Used to create visual representations of circular and linear annotated genome sequences provided as GenBank files or accession numbers.
Proper citation: OGDraw (RRID:SCR_017337) Copy
http://deweylab.biostat.wisc.edu/detonate/
Software tool to evaluate de novo transcriptome assemblies from RNA-Seq data. Consists of RSEM-EVAL and REF-EVAL packages. RSEM-EVAL is reference-free evaluation method. REF-EVAL is reference based and can be used to compare sets of any kinds of genomic sequences.
Proper citation: DETONATE (RRID:SCR_017035) Copy
http://www.cbs.dtu.dk/services/TMHMM/
Web application for the prediction of transmembrane helices in proteins using Hidden Markov Models. FASTA formatted sequences can be uploaded via file or copy-paste, and output can be formatted as extensive with graphics, extensive without graphics, or one line per protein. Submissions are limited to 10,000 sequences and 4,000,000 amino acids - each sequence is limited to no more than 8,000 amino acids.
Proper citation: TMHMM Server (RRID:SCR_014935) Copy
http://www.cbs.dtu.dk/services/ProP/
Web application which predicts arginine and lysine propeptide cleavage sites in eukaryotic protein sequences using an ensemble of neural networks. Furin-specific prediction is the default. It is also possible to perform a general proprotein convertase prediction.
Proper citation: ProP Server (RRID:SCR_014936) Copy
Web tool for discovery and visualization of differences in amino acid composition. Two samples of amino acid sequences serve as input and a bar chart composed of twenty data points is output.
Proper citation: Composition Profiler (RRID:SCR_014630) Copy
http://www.ncbi.nlm.nih.gov/igblast/
THIS RESOURCE IS NO LONGER IN SERVICE.Documented on January 4,2023. IgBLAST was developed at NCBI to facilitate analysis of immunoglobulin V region sequences in GenBank. In addition to performing a regular BLAST search, IgBLAST has several additional functions: - Reports the germline V, D and J gene matches to the query sequence. - Annotates the immunoglobulin domains (FWR1 through FWR3). - Matches the returned hits (for databases other than germline genes) to the closest germline V genes, making it easier to identify related sequences. - Reveals the V(D)J junction details such as nucleotide homology between the ends of V(D)J segments and N nucleotide insertions. D and J gene reporting is only for nucleotide sequence search and requires a stretch of five or more nucleotide identity between the query and D or J genes. Sponsors: This resource is supported by the National Center for Biotechnology Information, a division of the U.S. National Library of Medicine.
Proper citation: IgBLAST (RRID:SCR_002873) Copy
http://clones.invitrogen.com/cloneranger.php
The Invitrogen Clone Collection: * Ultimate ORF Clones: Full-insert sequenced human and mouse open reading frames (ORFs) in a Gateway entry vector offering the highest utility for your downstream analysis needs. * GeneStorm Clones: GeneStorm Clones are human ORFs cloned and tested for expression in a mammalian, insect, or bacterial expression system. They are sequenced for identity and classification and are not guaranteed at the nucleotide level. * Full-Length Clones: An unparalleled repository of clones enriched for full-length inserts, derived from both public and proprietary sources. * BAC/PAC Clones: Invitrogen offers several genomic libraries from a selection of tissues and sources to facilitate your research and discovery. These collections are available in a variety of formats including clones, plates, pools and high-density colony membrane filters. * Yeast Deletions: Each yeast deletion represents a unique gene-knockout of the S. cerevisiae genome. Each open reading frame is knocked out using a PCR-based gene deletion strategy. Yeast deletions are available as clones, pools, plates and complete collections. * Yeast GFP Clones: The Yeast GFP Clone Collection of S. cerevisiae tagged open reading frames were generated by Dr. Erin O''Shea and Dr. Jonathan Weissman at University of California-San Francisco. The GFP fusion proteins are integrated into the yeast chromosome through homologous recombination and are expressed using endogenous promoters.
Proper citation: Invitrogen Clones (RRID:SCR_005371) Copy
http://www.sanger.ac.uk/resources/software/vagrent/
Software tool set for calculating the biological consequences of genomic variations. The suite of perl modules compares genomic variations with reference genome annotations and generates the possible effects each variant may have on the transcripts it overlaps. It evaluates each variation/transcript combination and describes the effects in the mRNA, CDS and protein sequence contexts. It provides details of the sequence and position of the change within the transcript / protein as well as Sequence Ontology terms to classify its consequences.
Proper citation: VAGrENT (RRID:SCR_005180) Copy
https://sites.google.com/a/blueprint.org/trades/
With Trajectory Directed Ensemble Sampling (TraDES) create large ensembles of high-quality protein structures quickly, ranging from near-native to partially unfolded to intrinsically unfolded. TraDES is a system for directly controlling and sampling protein conformational space. TraDES has been previously used for measuring the vastness of protein conformational space and testing the hypothesis of a brute force solution to the protein folding problem. Over 10 Billion protein structures have been produced by TraDES software in previous distributed computing experiments. The package is comprised of binary executable programs and accessory programs and scripts as well as protein structure data files that map out protein conformational space in a probabilistic way. The main programs are: * trades - generates protein structures following the Trajectory Distribution (see below) * seq2trj - makes Trajectory Distributions from sequences for sampling * str2tr - makes Trajectory Distributions from 3D structures for sampling Trajectory Distributions - Controlling the Sampling of Conformational Space The concept of the trajectory distribution may be new to many protein scientists. A trajectory distribution is simply a map of available conformational space at an amino acid residue. NMR scientists are the primary users of the TraDES package.
Proper citation: TraDES (RRID:SCR_006142) Copy
http://www.imtech.res.in/raghava/bhairpred/
Bhairpred server is based on machine learning technique SVM using single sequence information, evolutionary profile, predicted and observed secondary structure (as obtained using Psipred and DSSP), predicted and observed accessibility values (as obtainned from Netasa and DSSP). The methods were trained and tested on dataset of 2880 proteins and their performance was evaluated on dataset of 534 proteins used by Thornton (PNAS, 2002). Best prediction results were obtained with hybrid approach that combined prediction results from evolutionary profile, predicted secondary structure and accessibility.
Proper citation: SVM based method for predicting beta hairpin structures in proteins (RRID:SCR_008349) Copy
http://www.medinfopoli.polimi.it/GFINDer/
THIS RESOURCE IS NO LONGER IN SERVICE, documented on August 16, 2019. Multi-database system providing large-scale lists of user-classified sequence identifiers with genome-scale biological information and functional profiles biologically characterizing the different gene classes in the list. GFINDer automatically retrieves updated annotations of several functional categories from different sources, identifies the categories enriched in each class of a user-classified gene list, and calculates statistical significance values for each category. Moreover, GFINDer enables to functionally classify genes according to mined functional categories and to statistically analyze the obtained classifications, aiding in better interpreting microarray experiment results.
Proper citation: GFINDer: Genome Function INtegrated Discoverer (RRID:SCR_008868) Copy
http://bioinfo2.ugr.es/IsoF/isofinder.html
Isofinder is an algorithm running on the web able to predict isochores at the sequence level. Isochores are long genome segments homogeneous in G+C. The algorithm works by moving a sliding pointer from left to right along the DNA sequence and computing the mean G+C values to the left and to the right of the pointer at each point. Additionally, the program checks whether this significance exceeds a probability threshold. If so, the sequence is cut at this point into two subsequences; otherwise, the sequence remains undivided. The procedure continues recursively for each of the two resulting subsequences created by each cut. This leads to the decomposition of a chromosome sequence into long homogeneous genome regions (LHGRs) with well-defined mean G+C contents, each significantly different from the G+C contents of the adjacent LHGRs. Most LHGRs can be identified with Bernardi''s isochores, given their correlation with biological features such as gene density, SINE and LINE (short, long interspersed repetitive elements) densities, recombination rate or single nucleotide polymorphism variability. The resulting isochore maps are available at http://bioinfo2.ugr.es/isochores/, and also at the UCSC Genome Browser (http://genome.cse.ucsc.edu/). Sponsors: Isofinder is funded by Universidad de Granada, Spain.
Proper citation: Isofinder: Isochore Computational Prediction (RRID:SCR_008342) Copy
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