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11. Advances in flash memory devices.

Author

LUDWIG, C., BEUG, M. F., and KÜSTERS, K.-H.

Subjects
FLASH memory, DIELECTRICS, RANDOM access memory, SEMICONDUCTOR storage devices, COMPUTER storage devices
Abstract

Fundamental challenges are discussed concerning the down-scaling of flash memory cells for mass storage applications. A general scaling issue for all various memory cell concepts is the structuring limit of conventional lithography. Therefore sub-lithographical structuring methods like e.g., double-patterning for future flash chips, have been evaluated. Another common scaling challenge of charge trapping (CT) and floating gate (FG) cells, the two future concurrent flash memory cell concepts, is the introduction of new materials such as high k dielectrics. Their implementation into CT and FG cells and the scaling related electrical issues of both cell concepts is also been discussed. [ABSTRACT FROM AUTHOR]

Published
2010

12. Scaling of nonvolatile memories to nanoscale feature sizes.

Author

Mikolajick, T., Nagel, N., Riedel, S., Mueller, T., and Küsters, K.-H.

Subjects
COMPUTER storage devices, SCALABILITY, RANDOM access memory, FLASH memory, SWITCHING theory, SEMICONDUCTOR storage devices
Abstract

The market for nonvolatile memory devices is growing rapidly. Today, the vast majority of nonvolatile memory devices are based on the floating gate device which is facing serious scaling limitations. Material innovations currently under investigation to extend the scalability of floating gate devices are discussed. An alternative path is to replace the floating gate by a charge trapping material. The combination of charge trapping and localized channel hot electron injection allows storing two physically separated bits in one memory cell. The current status and prospects of charge trapping devices are reviewed, demonstrating their superior scalability. Floating gate as well as charge trapping memory cells suffer from severe performance limitations with respect to write and erase speed and endurance driving system overhead. A memory that works like random access memory and is nonvolatile would simplify system design. This, however, calls for new switching effects that are based on integrating new materials into the memory cell. An outlook to memory concepts that use ferroelectric switching, magnetic switching, phase change, or other resistive switching effects is given, illustrating how the integration of new materials may solve the limitations of today's semiconductor memory concepts. [ABSTRACT FROM AUTHOR]

Published
2007

16. "High-throughput screening of catalytically active inclusion bodies using laboratory automation and Bayesian optimization".

Author

Helleckes LM, Küsters K, Wagner C, Hamel R, Saborowski R, Marienhagen J, Wiechert W, and Oldiges M

Subjects
Reproducibility of Results, Bayes Theorem, Inclusion Bodies, Automation, Automation, Laboratory, High-Throughput Screening Assays
Abstract

Background: In recent years, the production of inclusion bodies that retain substantial catalytic activity was demonstrated. These catalytically active inclusion bodies (CatIBs) are formed by genetic fusion of an aggregation-inducing tag to a gene of interest via short linker polypeptides. The resulting CatIBs are known for their easy and cost-efficient production, recyclability as well as their improved stability. Recent studies have outlined the cooperative effects of linker and aggregation-inducing tag on CatIB activities. However, no a priori prediction is possible so far to indicate the best combination thereof. Consequently, extensive screening is required to find the best performing CatIB variant., Results: In this work, a semi-automated cloning workflow was implemented and used for fast generation of 63 CatIB variants with glucose dehydrogenase of Bacillus subtilis (BsGDH). Furthermore, the variant BsGDH-PT-CBDCell was used to develop, optimize and validate an automated CatIB screening workflow, enhancing the analysis of many CatIB candidates in parallel. Compared to previous studies with CatIBs, important optimization steps include the exclusion of plate position effects in the BioLector by changing the cultivation temperature. For the overall workflow including strain construction, the manual workload could be reduced from 59 to 7 h for 48 variants (88%). After demonstration of high reproducibility with 1.9% relative standard deviation across 42 biological replicates, the workflow was performed in combination with a Bayesian process model and Thompson sampling. While the process model is crucial to derive key performance indicators of CatIBs, Thompson sampling serves as a strategy to balance exploitation and exploration in screening procedures. Our methodology allowed analysis of 63 BsGDH-CatIB variants within only three batch experiments. Because of the high likelihood of TDoT-PT-BsGDH being the best CatIB performer, it was selected in 50 biological replicates during the three screening rounds, much more than other, low-performing variants., Conclusions: At the current state of knowledge, every new enzyme requires screening for different linker/aggregation-inducing tag combinations. For this purpose, the presented CatIB toolbox facilitates fast and simplified construction and screening procedures. The methodology thus assists in finding the best CatIB producer from large libraries in short time, rendering possible automated Design-Build-Test-Learn cycles to generate structure/function learnings., (© 2024. The Author(s).)

Published
2024
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17. Construction and characterization of BsGDH-CatIB variants and application as robust and highly active redox cofactor regeneration module for biocatalysis.

Author

Küsters K, Saborowski R, Wagner C, Hamel R, Spöring JD, Wiechert W, and Oldiges M

Subjects
Biocatalysis, Inclusion Bodies metabolism, Oxidation-Reduction, Enzymes, Immobilized chemistry, NAD metabolism
Abstract

Background: Catalytically active inclusion bodies (CatIBs) are known for their easy and cost efficient production, recyclability as well as high stability and provide an alternative purely biological technology for enzyme immobilization. Due to their ability to self-aggregate in a carrier-free, biodegradable form, no further laborious immobilization steps or additional reagents are needed. These advantages put CatIBs in a beneficial position in comparison to traditional immobilization techniques. Recent studies outlined the impact of cooperative effects of the linker and aggregation inducing tag on the activity level of CatIBs, requiring to test many combinations to find the best performing CatIB variant., Results: Here, we present the formation of 14 glucose dehydrogenase CatIB variants of Bacillus subtilis, a well-known enzyme in biocatalysis due to its capability for substrate coupled regeneration of reduced cofactors with cheap substrate glucose. Nine variants revealed activity, with highest productivity levels for the more rigid PT-Linker combinations. The best performing CatIB, BsGDH-PT-CBDCell, was characterized in more detail including long-term storage at -20 °C as well as NADH cofactor regeneration performance in repetitive batch experiments with CatIB recycling. After freezing, BsGDH-PT-CBDCell CatIB only lost approx. 10% activity after 8 weeks of storage. Moreover, after 11 CatIB recycling cycles in repetitive batch operation 80% of the activity was still present., Conclusions: This work presents a method for the effective formation of a highly active and long-term stable BsGDH-CatIB as an immobilized enzyme for robust and convenient NADH regeneration., (© 2022. The Author(s).)

Published
2022
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18. Catalytically Active Inclusion Bodies─Benchmarking and Application in Flow Chemistry.

Author

Ölçücü G, Baumer B, Küsters K, Möllenhoff K, Oldiges M, Pietruszka J, Jaeger KE, and Krauss U

Subjects
Alcohol Dehydrogenase genetics, Alcohol Dehydrogenase metabolism, Biocatalysis, Enzymes, Immobilized chemistry, Inclusion Bodies metabolism, Proteins metabolism, Benchmarking, Escherichia coli metabolism
Abstract

In industries, enzymes are often immobilized to obtain stable preparations that can be utilized in batch and flow processes. In contrast to traditional immobilization methods that rely on carrier binding, various immobilization strategies have been recently presented that enable the simultaneous production and in vivo immobilization of enzymes. Catalytically active inclusion bodies (CatIBs) are a promising example for such in vivo enzyme immobilizates. CatIB formation is commonly induced by fusion of aggregation-inducing tags, and numerous tags, ranging from small synthetic peptides to protein domains or whole proteins, have been successfully used. However, since these systems have been characterized by different groups employing different methods, a direct comparison remains difficult, which prompted us to benchmark different CatIB-formation-inducing tags and fusion strategies. Our study highlights that important CatIB properties like yield, activity, and stability are strongly influenced by tag selection and fusion strategy. Optimization enabled us to obtain alcohol dehydrogenase CatIBs with superior activity and stability, which were subsequently applied for the first time in a flow synthesis approach. Our study highlights the potential of CatIB-based immobilizates, while at the same time demonstrating the robust use of CatIBs in flow chemistry.

Published
2022
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19. A fully automated pipeline for the dynamic at-line morphology analysis of microscale Aspergillus cultivation.

Author

Jansen R, Küsters K, Morschett H, Wiechert W, and Oldiges M

Abstract

Background: Morphology, being one of the key factors influencing productivity of filamentous fungi, is of great interest during bioprocess development. With increasing demand of high-throughput phenotyping technologies for fungi due to the emergence of novel time-efficient genetic engineering technologies, workflows for automated liquid handling combined with high-throughput morphology analysis have to be developed., Results: In this study, a protocol allowing for 48 parallel microbioreactor cultivations of Aspergillus carbonarius with non-invasive online signals of backscatter and dissolved oxygen was established. To handle the increased cultivation throughput, the utilized microbioreactor is integrated into a liquid handling platform. During cultivation of filamentous fungi, cell suspensions result in either viscous broths or form pellets with varying size throughout the process. Therefore, tailor-made liquid handling parameters such as aspiration/dispense height, velocity and mixing steps were optimized and validated. Development and utilization of a novel injection station enabled a workflow, where biomass samples are automatically transferred into a flow through chamber fixed under a light microscope. In combination with an automated image analysis concept, this enabled an automated morphology analysis pipeline. The workflow was tested in a first application study, where the projected biomass area was determined at two different cultivation temperatures and compared to the microbioreactor online signals., Conclusions: A novel and robust workflow starting from microbioreactor cultivation, automated sample harvest and processing via liquid handling robots up to automated morphology analysis was developed. This protocol enables the determination of projected biomass areas for filamentous fungi in an automated and high-throughput manner. This measurement of morphology can be applied to describe overall pellet size distribution and heterogeneity.

Published
2021
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20. Construction and comprehensive characterization of an EcLDCc-CatIB set-varying linkers and aggregation inducing tags.

Author

Küsters K, Pohl M, Krauss U, Ölçücü G, Albert S, Jaeger KE, Wiechert W, and Oldiges M

Subjects
Carboxy-Lyases metabolism, Escherichia coli metabolism, Inclusion Bodies metabolism
Abstract

Background: In recent years, the production of inclusion bodies that retained substantial catalytic activity was demonstrated. These catalytically active inclusion bodies (CatIBs) were formed by genetic fusion of an aggregation inducing tag to a gene of interest via short linker polypeptides and overproduction of the resulting gene fusion in Escherichia coli. The resulting CatIBs are known for their high stability, easy and cost efficient production, and recyclability and thus provide an interesting alternative to conventionally immobilized enzymes., Results: Here, we present the construction and characterization of a CatIB set of the lysine decarboxylase from Escherichia coli (EcLDCc), constructed via Golden Gate Assembly. A total of ten EcLDCc variants consisting of combinations of two linker and five aggregation inducing tag sequences were generated. A flexible Serine/Glycine (SG)- as well as a rigid Proline/Threonine (PT)-Linker were tested in combination with the artificial peptides (18AWT, L6KD and GFIL8) or the coiled-coil domains (TDoT and 3HAMP) as aggregation inducing tags. The linkers were fused to the C-terminus of the EcLDCc to form a linkage between the enzyme and the aggregation inducing tags. Comprehensive morphology and enzymatic activity analyses were performed for the ten EcLDCc-CatIB variants and a wild type EcLDCc control to identify the CatIB variant with the highest activity for the decarboxylation of L-lysine to 1,5-diaminopentane. Interestingly, all of the CatIB variants possessed at least some activity, whilst most of the combinations with the rigid PT-Linker showed the highest conversion rates. EcLDCc-PT-L6KD was identified as the best of all variants allowing a volumetric productivity of 457 g L - 1 d - 1 and a specific volumetric productivity of 256 g L - 1 d - 1 g CatIB -1 . Noteworthy, wild type EcLDCc, without specific aggregation inducing tags, also partially formed CatIBs, which, however showed lower activity compared to most of the newly constructed CatIB variants (volumetric productivity: 219 g L - 1 d - 1 , specific volumetric activity: 106 g L - 1 d - 1 g CatIB - 1 ). Furthermore, we demonstrate that microscopic analysis can serve as a tool to find CatIB producing strains and thus allow for prescreening at an early stage to save time and resources., Conclusions: Our results clearly show that the choice of linker and aggregation inducing tag has a strong influence on the morphology and the enzymatic activity of the CatIBs. Strikingly, the linker had the most pronounced influence on these characteristics.

Published
2021
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21. Catalytically-active inclusion bodies for biotechnology-general concepts, optimization, and application.

Author

Jäger VD, Lamm R, Küsters K, Ölçücü G, Oldiges M, Jaeger KE, Büchs J, and Krauss U

Subjects
Biocatalysis, Biotechnology, Protein Engineering, Recombinant Proteins genetics, Recombinant Proteins metabolism, Escherichia coli genetics, Inclusion Bodies metabolism
Abstract

Bacterial inclusion bodies (IBs) have long been considered as inactive, unfolded waste material produced by heterologous overexpression of recombinant genes. In industrial applications, they are occasionally used as an alternative in cases where a protein cannot be expressed in soluble form and in high enough amounts. Then, however, refolding approaches are needed to transform inactive IBs into active soluble protein. While anecdotal reports about IBs themselves showing catalytic functionality/activity (CatIB) are found throughout literature, only recently, the use of protein engineering methods has facilitated the on-demand production of CatIBs. CatIB formation is induced usually by fusing short peptide tags or aggregation-inducing protein domains to a target protein. The resulting proteinaceous particles formed by heterologous expression of the respective genes can be regarded as a biologically produced bionanomaterial or, if enzymes are used as target protein, carrier-free enzyme immobilizates. In the present contribution, we review general concepts important for CatIB production, processing, and application. KEY POINTS: • Catalytically active inclusion bodies (CatIBs) are promising bionanomaterials. • Potential applications in biocatalysis, synthetic chemistry, and biotechnology. • CatIB formation represents a generic approach for enzyme immobilization. • CatIB formation efficiency depends on construct design and expression conditions.

Published
2020
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22. Biotin Synthesis in Ralstonia eutropha H16 Utilizes Pimeloyl Coenzyme A and Can Be Regulated by the Amount of Acceptor Protein.

Author

Eggers J, Strittmatter CS, Küsters K, Biller E, and Steinbüchel A

Subjects
Bacillus subtilis metabolism, Bacterial Proteins metabolism, Cupriavidus necator genetics, Escherichia coli metabolism, Metabolic Networks and Pathways, Acyl Coenzyme A metabolism, Bacterial Proteins genetics, Biotin metabolism, Cupriavidus necator enzymology, Gene Expression Regulation, Bacterial
Abstract

The biotin metabolism of the Gram-negative facultative chemolithoautotrophic bacterium Ralstonia eutropha (syn. Cupriavidus necator ), which is used for biopolymer production in industry, was investigated. A biotin auxotroph mutant lacking bioF was generated, and biotin depletion in the cells and the minimal biotin demand of a biotin-auxotrophic R. eutropha strain were determined. Three consecutive cultivations in biotin-free medium were necessary to prevent growth of the auxotrophic mutant, and 40 ng/ml biotin was sufficient to promote cell growth. Nevertheless, 200 ng/ml biotin was necessary to ensure growth comparable to that of the wild type, which is similar to the demand of biotin-auxotrophic mutants among other prokaryotic and eukaryotic microbes. A phenotypic complementation of the R. eutropha ΔbioF mutant was only achieved by homologous expression of bioF of R. eutropha or heterologous expression of bioF of Bacillus subtilis but not by bioF of Escherichia coli Together with the results from bioinformatic analysis of BioFs, this leads to the assumption that the intermediate of biotin synthesis in R. eutropha is pimeloyl-CoA instead of pimeloyl-acyl carrier protein (ACP) like in the Gram-positive B. subtilis Internal biotin content was enhanced by homologous expression of accB , whereas homologous expression of accB and accC2 in combination led to decreased biotin concentrations in the cells. Although a DNA-binding domain of the regulator protein BirA is missing, biotin synthesis seemed to be influenced by the amount of acceptor protein present. IMPORTANCE Ralstonia eutropha is applied in industry for the production of biopolymers and serves as a research platform for the production of diverse fine chemicals. Due to its ability to grow on hydrogen and carbon dioxide as the sole carbon and energy source, R. eutropha is often utilized for metabolic engineering to convert inexpensive resources into value-added products. The understanding of the metabolic pathways in this bacterium is mandatory for further bioengineering of the strain and for the development of new strategies for biotechnological production., (Copyright © 2020 American Society for Microbiology.)

Published
2020
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23. A closer look at Aspergillus : online monitoring via scattered light enables reproducible phenotyping.

Author

Jansen RP, Beuck C, Moch M, Klein B, Küsters K, Morschett H, Wiechert W, and Oldiges M

Abstract

Background: Filamentously growing microorganisms offer unique advantages for biotechnological processes, such as extraordinary secretion capacities, going along with multiple obstacles due to their complex morphology. However, limited experimental throughput in bioprocess development still hampers taking advantage of their full potential. Miniaturization and automation are powerful tools to accelerate bioprocess development, but so far the application of such technologies has mainly been focused on non-filamentous systems. During cultivation, filamentous fungi can undergo remarkable morphological changes, creating challenging cultivation conditions. Depending on the process and product, only one specific state of morphology may be advantageous to achieve e.g. optimal productivity or yield. Different approaches to control morphology have been investigated, such as microparticle enhanced cultivation. However, the addition of solid microparticles impedes the optical measurements typically used by microbioreactor systems and thus alternatives are needed., Results: Aspergillus giganteus IfGB 0902 was used as a model system to develop a time-efficient and robust workflow allowing microscale cultivation with increased throughput. The effect of microtiter plate geometry, shaking frequency and medium additives (talc and calcium chloride) on homogeneity of culture morphology as well as reproducibility were analyzed via online biomass measurement, microscopic imaging and cell dry weight. While addition of talc severely affected online measurements, 2% (w v -1 ) calcium chloride was successfully applied to obtain a highly reproducible growth behavior with homogenous morphology. Furthermore, the influence of small amounts of complex components was investigated for the applied model strain. By correlation to cell dry weight, it could be shown that optical measurements are a suitable signal for biomass concentration. However, each correlation is only applicable for a specific set of cultivation parameters. These optimized conditions were used in micro as well as lab-scale bioreactor cultivation in order to verify the reproducibility and scalability of the setup., Conclusion: A robust workflow for A. giganteus was developed, allowing for reproducible microscale cultivation with online monitoring, where calcium chloride is an useful alternative to microparticle enhanced cultivation in order to control the morphology. Independent of the cultivation volume, comparable phenotypes were observed in microtiter plates and in lab-scale bioreactor., Competing Interests: Competing interestsThe authors declare that they have no competing interests.

Published
2019
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24. DksA-RNA polymerase interactions support new origin formation and DNA repair in Escherichia coli.

Author

Myka KK, Küsters K, Washburn R, and Gottesman ME

Subjects
DNA-Directed RNA Polymerases genetics, Escherichia coli enzymology, Escherichia coli Proteins genetics, Gene Expression Regulation, Bacterial, Mutation, Transcription, Genetic, DNA Repair, DNA-Directed RNA Polymerases metabolism, Escherichia coli genetics, Escherichia coli Proteins metabolism, Replication Origin
Abstract

The formation of new replication origins (cSDR) and repair of DNA double-strand breaks (DSBs) in E. coli share a commonality. We find that the two processes require the RNAP-associated factor, DksA. However, whereas cSDR also relies on (p)ppGpp, the alarmone molecule is dispensable for the repair of topoisomerase type II (Top II) DNA adducts and associated DSBs. The requirement for DksA in repair of nalidixic acid (Nal)-induced DSBs or for the formation of new origins is not suppressed by a greA deletion mutation, indicating an active role of DksA rather than competition with GreA for insertion into the RNAP secondary channel. Like dksA mutations, transcription termination factor Rho mutations also confer sensitivity to Nal. The rho and dksA mutations are not epistatic, suggesting they involve different repair pathways. The roles of DksA in DSB repair and cSDR differ; certain DksA and RNAP mutants are able to support the first process, but not the latter. We suggest that new origin formation and DNA repair of protein adducts with DSBs may both involve the removal of RNAP without destruction of the RNA:DNA hybrid., (© 2019 The Authors. Molecular Microbiology Published by John Wiley & Sons Ltd.)

Published
2019
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