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genome browsers (e.g. Ensembl or UCSC). Specific genomic mutations, for example in
human tumors or heart failure, are also deposited in various databases (e.g. OMIM) and
can be used by users. DNA sequencing thus makes it possible to sequence unknown
genomes, such as new resistant bacterial strains, or to determine the underlying mutations
in diseases in medical diagnostics.
Transcriptome sequencing (gene expression sequencing) provides insights into gene
expression, i.e. into the activation of gene transcripts. Common methods are microarray
experiments or newer high-throughput methods such as RNA sequencing. These measure
gene expression (mRNA level) and thus provide information on the corresponding changes
in mRNA (up- or down-regulated), for example after infection or treatment. Meanwhile,
there are increasingly efficient methods that can, for example, measure the expression of
the host and the pathogen in parallel in one cell and thus provide insights into the changes
in both organisms after an infection (dual RNAseq). Subsequent bioinformatic gene
expression analysis can then examine the RNA secondary structure (e.g., RNAfold), the
RNA sequence for regulatory RNA elements such as IRE (e.g., RNAAnalyzer) or in more
detail with regard to possible interaction partners, for example RNA-protein (e.g., catR
APID, NPInter) or miRNA-mRNA interactions (e.g., miRanda, TargetScan). Numerous
databases already contain gene expression datasets (e.g. GEO, cBioPortal, TCGA or
GENEVESTIGATOR), information on RNA sequence, structure and binding motifs (e.g.
Rfam) or information on specific RNA classes (e.g. miRNA [miRBase], lncRNA
[LNCipedia]) and can be used for own analyses.
Protein sequencing can be done with mass spectroscopy or protein microarrays and
provides information on the amino acid sequence in the protein. It is often of great interest
how the proteome changes under certain conditions, for example after an infection or
therapy. However, one is usually also interested in the changes or modifications in the
amino acid sequence, for example in the functional side, and their effect on protein
9 Complex Systems Behave Fundamentally in a Similar Way