TY  - GEN
A1  - Bentele, Kajetan
A1  - Saffert, Paul
A1  - Rauscher, Robert
A1  - Ignatova, Zoya
A1  - Bluethgen, Nils
T1  - Efficient translation initiation dictates codon usage at gene start
T2  - Postprints der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe
N2  - The genetic code is degenerate; thus, protein evolution does not uniquely determine the coding sequence. One of the puzzles in evolutionary genetics is therefore to uncover evolutionary driving forces that result in specific codon choice. In many bacteria, the first 5-10 codons of protein-coding genes are often codons that are less frequently used in the rest of the genome, an effect that has been argued to arise from selection for slowed early elongation to reduce ribosome traffic jams. However, genome analysis across many species has demonstrated that the region shows reduced mRNA folding consistent with pressure for efficient translation initiation. This raises the possibility that unusual codon usage is a side effect of selection for reduced mRNA structure. Here we discriminate between these two competing hypotheses, and show that in bacteria selection favours codons that reduce mRNA folding around the translation start, regardless of whether these codons are frequent or rare. Experiments confirm that primarily mRNA structure, and not codon usage, at the beginning of genes determines the translation rate.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 912 
KW  - codon usage
KW  - mRNA structure
KW  - translation
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-441337
SN  - 1866-8372
IS  - 912
ER  - 
TY  - JOUR
A1  - Bentele, Kajetan
A1  - Saffert, Paul
A1  - Rauscher, Robert
A1  - Ignatova, Zoya
A1  - Bluethgen, Nils
T1  - Efficient translation initiation dictates codon usage at gene start
JF  - Molecular systems biology
N2  - The genetic code is degenerate; thus, protein evolution does not uniquely determine the coding sequence. One of the puzzles in evolutionary genetics is therefore to uncover evolutionary driving forces that result in specific codon choice. In many bacteria, the first 5-10 codons of protein-coding genes are often codons that are less frequently used in the rest of the genome, an effect that has been argued to arise from selection for slowed early elongation to reduce ribosome traffic jams. However, genome analysis across many species has demonstrated that the region shows reduced mRNA folding consistent with pressure for efficient translation initiation. This raises the possibility that unusual codon usage is a side effect of selection for reduced mRNA structure. Here we discriminate between these two competing hypotheses, and show that in bacteria selection favours codons that reduce mRNA folding around the translation start, regardless of whether these codons are frequent or rare. Experiments confirm that primarily mRNA structure, and not codon usage, at the beginning of genes determines the translation rate.
KW  - codon usage
KW  - mRNA structure
KW  - translation
Y1  - 2013
U6  - https://doi.org/10.1038/msb.2013.32
SN  - 1744-4292
VL  - 9
IS  - 6
PB  - Nature Publ. Group
CY  - New York
ER  - 
TY  - GEN
A1  - Del Campo, Cristian
A1  - Bartholomäus, Alexander
A1  - Fedyunin, Ivan
A1  - Ignatova, Zoya
T1  - Secondary Structure across the Bacterial Transcriptome Reveals Versatile Roles in mRNA Regulation and Function
T2  - Postprints der Universität Potsdam : Mathematisch Naturwissenschaftliche Reihe
N2  - Messenger RNA acts as an informational molecule between DNA and translating ribosomes. Emerging evidence places mRNA in central cellular processes beyond its major function as informational entity. Although individual examples show that specific structural features of mRNA regulate translation and transcript stability, their role and function throughout the bacterial transcriptome remains unknown. Combining three sequencing approaches to provide a high resolution view of global mRNA secondary structure, translation efficiency and mRNA abundance, we unraveled structural features in E. coli mRNA with implications in translation and mRNA degradation. A poorly structured site upstream of the coding sequence serves as an additional unspecific binding site of the ribosomes and the degree of its secondary structure propensity negatively correlates with gene expression. Secondary structures within coding sequences are highly dynamic and influence translation only within a very small subset of positions. A secondary structure upstream of the stop codon is enriched in genes terminated by UAA codon with likely implications in translation termination. The global analysis further substantiates a common recognition signature of RNase E to initiate endonucleolytic cleavage. This work determines for the first time the E. coli RNA structurome, highlighting the contribution of mRNA secondary structure as a direct effector of a variety of processes, including translation and mRNA degradation.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 520 
KW  - Escherichia coli
KW  - in vivo
KW  - translation initiation
KW  - crystal-structure
KW  - single ribosomes
KW  - gene-expression
KW  - global analysis
KW  - codon usage
KW  - E-cleavage
KW  - genome
Y1  - 2019
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-409662
SN  - 1866-8372
IS  - 520
ER  - 
TY  - GEN
A1  - Hess, Anne-Katrin
A1  - Saffert, Paul
A1  - Liebeton, Klaus
A1  - Ignatova, Zoya
T1  - Optimization of translation profiles enhances protein expression and solubility
T2  - Postprints der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe
N2  - mRNA is translated with a non-uniform speed that actively coordinates co-translational folding of protein domains. Using structure-based homology we identified the structural domains in epoxide hydrolases (EHs) and introduced slow-translating codons to delineate the translation of single domains. These changes in translation speed dramatically improved the solubility of two EHs of metagenomic origin in Escherichia coli. Conversely, the importance of transient attenuation for the folding, and consequently solubility, of EH was evidenced with a member of the EH family from Agrobacterium radiobacter, which partitions in the soluble fraction when expressed in E. coli. Synonymous substitutions of codons shaping the slow-transiting regions to fast-translating codons render this protein insoluble. Furthermore, we show that low protein yield can be enhanced by decreasing the free folding energy of the initial 5'-coding region, which can disrupt mRNA secondary structure and enhance ribosomal loading. This study provides direct experimental evidence that mRNA is not a mere messenger for translation of codons into amino acids but bears an additional layer of information for folding, solubility and expression level of the encoded protein. Furthermore, it provides a general frame on how to modulate and fine-tune gene expression of a target protein.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 518 
KW  - transfer-RNA genes
KW  - codon usage
KW  - Escherichia coli
KW  - Epoxide hydrolases
KW  - messenger-RNA
KW  - sequence
KW  - elongation
KW  - Ribosome
KW  - mechanism
KW  - Membrane
Y1  - 2019
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-409574
SN  - 1866-8372
IS  - 518
ER  - 
TY  - THES
A1  - Osterloh-Quiroz, Mandy
T1  - Optimierung der Expressionsstärke von fremdstoffmetabolisierenden Enzymen in Bakterien und permanenten Zellkulturen für toxikologische Untersuchungen
T1  - Optimization of xenobiotic-metabolizing enzyme expression in bacteria and cell culture for toxicological investigations
N2  - Die Enzymsuperfamilie der löslichen Sulfotransferasen (SULT) spielt eine wichtige Rolle in der Phase II des Fremdstoffmetabolismus. Sie katalysieren den Transfer einer Sulfonylgruppe auf nucleophile Gruppen endogener und exogener Substrate. Die Sulfokonjugation von Fremdstoffen erhöht deren Wasserlöslichkeit und behindert die passive Permeation von Zellmembranen. Dadurch wird die Ausscheidung dieser konjugierten Substanzen erleichtert. In Abhängigkeit von der Struktur des Zielmoleküls kann die Sulfokonjugation aber auch zur metabolischen Aktivierung von Fremdstoffen durch die Bildung instabiler Metabolite führen. Die SULT-vermittelte Aktivierung promutagener Substanzen ist somit von toxikologischem Interesse. Für die Detektion SULT-vermittelter Mutagenität mittels bakterieller in-vitro Testsysteme ist die heterologe Expression der fremdstoffmetabolisierenden Enzyme direkt in den Indikatorzellen notwendig. S. typhimurium exprimieren selbst keine SULT, und externe Metabolisierungssysteme sind problematisch, weil die negativ geladenen, kurzlebigen Metabolite nur schlecht die Zellmembran penetrieren können. Die Expression humaner Enyme in Bakterien ist jedoch zum Teil sehr kritisch. So zeigen z.B. sehr ähnliche Enzyme (SULT1A2*1 und *2) deutliche Unterschiede im Expressionsniveau bei exakt gleichen äußeren Bedingungen. Dies erschwert den Vergleich der enzymatischen Aktivitäten dieser Enzyme im in-vitro Testsystem. Andere Enzyme (z.B. SULT2B1b) werden unter Verwendung ihrer Wildtyp-cDNA zum Teil nicht detektierbar exprimiert. Deshalb sollte in dieser Arbeit eine Methode zur Optimierung der heterologen Expression fremdstoffmetabolisierender Enzyme für Genotoxizitätsuntersuchungen etabliert werden.  Es wurde bereits gezeigt dass synonyme Codonaustausche am 5’-Ende der humanen SULT1A2-cDNA zu einer Erhöhung der Expression des entsprechenden Enzyms in S. typhimurium führten. Dementsprechend wurden in dieser Arbeit Codonaustausche am 5’-Ende der cDNA verschiedener SULT (1A1*1, 1A2*1, 2B1b) sowie der Ratten Glutathion-S-Transferase Theta 2 (rGSTT2) und dem Reportergen Luciferase durchgeführt. Die Expression der so generierten Konstrukte wurde in verschiedenen S. typhimurium und E. coli Stämmen quantifiziert und die Aktivität der überexprimierten Enzyme im Ames-Test bzw. im Enzym-Aktivitätsassay überprüft. Durch das Einführen seltener Codons in die cDNA konnte die Proteinexpression von SULT1A1*1, SULT1A2*1 und SULT2B1b maximal 7-fach, 18-fach und 100-fach im Vergleich zur Wildtyp-cDNA gesteigert werden. Die Expression der rGSTT2 wurde ebenfalls durch das Einführen seltener Codons erhöht (maximal 5-fach). Bei dem Reportergen Luciferase jedoch führte das Austauschen häufiger Codons gegen seltene Codons zu einer Reduktion der Proteinexpression um 80 %. Die Expression von Fusionsproteinen aus 2B1b (5’-Ende) und Luciferase (3’-Ende) wurde durch das Einführen seltener Codons ebenfalls um 50 % reduziert. Die S. typhimurium Stämme mit optimierter SULT 1A1*1- bzw. 1A2*1-Expression wurden im Ames-Test eingesetzt und zeigten im Vergleich zu den geringer exprimierenden Stämmen eine höhere Sensitivität. Für SULT2B1b konnte keine Mutagenaktivierung im Ames-Test nachgewiesen werden. Allerdings zeigte ein Enzym-Aktivitätsassay mit Dehydroepiandosteron, dass das bakteriell exprimierte Enzym funktionell war. Da in der Literatur der Effekt seltener Codons auf die Expression in Bakterien bisher fast ausschließlich als inhibitorisch beschrieben wurde, sollte die Wirkungsweise der hier beobachteten Expressionserhöhung durch seltene Codons genauer untersucht werden. Dazu wurden verschiedene Konstrukte der SULT1A2*1 und der SULT2B1b, die unterschiedlich viele seltene Codons in verschiedenen Kombinationen besaßen, hergestellt. Es konnten jedoch keine einzelnen Codons, die für die Expressionssteigerung allein verantwortlich waren, identifiziert werden. Die Plasmidkopienzahl in den verschiedenen SULT2B1b-Klonen war konstant und die SULT2B1b-mRNA-Konzentration zeigte nur moderate Schwankungen, die nicht als Ursache für die dramatische Erhöhung der SULT2B1b-Expression in Frage kommen. Die berechnete Stabilität der potentiellen mRNA-Sekundärstrukturen wurde durch die seltenen Codons häufig stark gesenkt und ist als eine mögliche Ursache für die Expressionssteigerung anzusehen. Zusätzlich erhöhten die seltenen Codons den Consensus der Downstream Box zur 16S rRNA, was ebenfalls eine Ursache für die Expressionssteigerung sein kann.  In dieser Arbeit konnte somit die Expression der humanen SULT1A1*1, 1A2*1 und der 2B1b sowie der rGSTT2 erfolgreich mittels synonymer Codonaustausche erhöht werden. Die so optimierten S. typhimurium Stämme zeigten im Ames-Test eine erhöhte Sensitivität gegenüber SULT aktivierten Promutagenen bzw. erhöhte Aktivität in spezifischen Enymaktivitätsassays.
N2  - The enzyme super familiy of human sulfotransferases (SULT) plays an important role in phase II metabolism of xenobiotics. They catalyze the transfer of a sulfonyl moiety to nucleophilic groups of endogenous and exogenous substrates. Sulfoconjugation of xenobiotics facilitates their excretion by increasing the water solubility and inhibiting passive permeation of cell membranes. Depending on the molecular structure of the substance, sulfonation can also lead to metabolic activation. Highly reactive resonance-stabilized carbenium- and nitrenium-ions that are able to covalently bind to cellular nucleophiles, e.g. DNA, can be formed. Thus, SULT-mediated activation of promutagenic compounds is of toxicological interest. The detection of SULT-mediated mutagenicity in bacterial in-vitro testsystems (e.g. S. typhimurium) requires the heterologous expression of xenobiotic-metabolizing enzymes directly in these indicator cells. S. typhimurium do not express endogenous SULT and external metabolic systems are problematic as penetration of cell membranes is hampered for charged and short-lived metabolites. But the expression of human enzymes in bacteria can be problematic too. SULT1A2*1 and *2 for instance are allelic variants that differ only in two amino acids. However, using the same experimental conditions strong differences in their expression level have been observed. This complicates the comparison of the mutagenic activities of the polymorphic enzymes in the in-vitro test system. Other enzymes (e.g. SULT2B1b) show no detectable expression in bacteria when their genuine cDNA obtained from human tissues is used. Therefore, the aim of this study was to to optimize protein levels of heterologously expressed xenobiotic-metabolizing enzymes in indicator cells for mutagenicity testing.  So far it has been shown that synonymous codon-exchanges at the 5’end of human SULT1A2-cDNA led to an enhanced expression of the corresponding enzyme in S. typhimurium. Accordingly, codon-exchanges at the 5’end of SULT1A1*1, -1A2*1, -2B1b, rat glutathione-S-transferase theta 2 (rGSTT2) and the reportergene luciferase were conducted. The expression of the resulting constructs was quantified in S. typhimurium and E. coli using specific antibodies and activity of the overexpressed enzymes was proved by Ames test and enzyme activity assays. The introduction of low-usage codons at the 5’end of SULT1A1*1, -1A2*1 and -2B1b cDNA led to a 7-, 18- and 100-fold increase of expression level, respectively. Expression of rGSTT2 was 5-fold enhanced after the introduction of low-usage codons. In contrast, the introduction of low-usage codons into the luciferase cDNA resulted in a decrease of protein expression up to 80 %. Fusionproteins of SULT2B1b (5’end) and luciferase (3’end) showed a reduction of protein expression about 50 % after the introduction of low-usage codons. S. typhimurium strains with optimized SULT1A1*1 and -1A2*1 expression were used in the Ames test and showed a higher sensitivity compared to the lower expressing strains. For SULT2B1b no mutagen-activation could be detected in the Ames test, but enzyme activity was proved through Dehydroepiandosterone sulfation in vitro.  Since an inhibitory effect of low-usage codons on expression in bacteria was described in literature, the enhancement of expression after the introduction of low-usage codons observed in this study was analyzed more in detail. Various constructs of SULT1A2*1 and -2B1b cDNAs containing different numbers and combinations of synonymous low-usage codons were generated. No single codon that was responsible for the enhanced expression could be identified. Plasmid copy number of different SULT2B1b constructs was unchanged and SULT2B1b-mRNA showed only moderate variations that could not explain the strong enhancement of SULT2B1b expression. Calculations suggested that the stability of potential mRNA secondary structures was reduced due to the introduction of low-usage codons. Moreover, the consensus of the downstream box and the 16S rRNA was increased. Both effects probably improved the efficiency of translation and thereby increased the yield of protein expression.  In this study the heterologous expression of SULT1A1*1, -1A2*1, -2B1b and rGSTT2 could be enhanced by the introduction of synonymous low-usage codons. The optimized S. typhimurium strains showed higher activities in enzyme assays with specific substrates and an increased sensitivity towards SULT-activated promutagens.
KW  - Mutagenität
KW  - Bioaktivierung
KW  - Sulfotransferasen
KW  - Codon Usage
KW  - Mutagenität
KW  - Bioaktivierung
KW  - Sulfotransferasen
KW  - Codon Usage
KW  - mutagenicity
KW  - bioactivation
KW  - sulfotranferases
KW  - codon usage
Y1  - 2006
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus-8945
ER  -