Carolin C. Lechner scite author profile

Biomineralization processes leading to complex solid structures of inorganic material in biological systems are constantly gaining attention in biotechnology and biomedical research. An outstanding example for biomineral morphogenesis is the formation of highly elaborate, nano-patterned silica shells by diatoms. Among the organic macromolecules that have been closely linked to the tightly controlled precipitation of silica in diatoms, silaffins play an extraordinary role. These peptides typically occur as complex posttranslationally modified variants and are directly involved in the silica deposition process in diatoms. However, even in vitro silaffin-based peptides alone, with and without posttranslational modifications, can efficiently mediate biomimetic silica precipitation leading to silica material with different properties as well as with encapsulated cargo molecules of a large size range. In this review, the biomineralization process of silica in diatoms is summarized with a specific focus on silaffins and their in vitro silica precipitation properties. Applications in the area of bio- and nanotechnology as well as in diagnostics and therapy are discussed.

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A sequence‐function analysis of the silica precipitating silaffin R5 peptide

Lechner

Becker

2014

Journal of Peptide Science

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The R5 peptide is derived from silaffin peptides naturally occurring in the diatom Cylindrotheca fusiformis and exhibits outstanding activity in silica precipitation. Because of its ability to cause silicification under mild conditions, several biotechnological applications based on R5-mediated biomimetic silica formation have already been reported. Yet a more detailed understanding of the R5 peptide and its intrinsic silica precipitation activity will help the rational design of R5 peptide variants as efficient agents for defined silica precipitation. The herein presented analysis of the relationship between the R5 amino acid sequence and its activity in silica precipitation emphasizes the essential role of the lysine residues in mediating silica polycondensation. Furthermore, a tetra amino acid motif (RRIL) has to be present within the R5 sequence, but in contrast to previous reports, we demonstrate that localization of the RRIL motif shows minor impact on silica precipitation activity but rather on morphology of the resulting silica material. The amino acid sequence of silaffin peptides is a well-balanced arrangement in terms of charges, functional groups and distances. The impact of this pattern of charges and functionalities was highlighted by the disturbed morphology of silica spheres resulting from R5 variants with scrambled sequences. A detailed understanding of the highly evolved silaffin sequence(s) will contribute to unravel the intriguing process of silica biomineralization in diatoms.

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Traceless Synthesis of Asymmetrically Modified Bivalent Nucleosomes

2016

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Nucleosomes carry extensive post-translational modifications (PTMs), which results in complex modification patterns that are involved in epigenetic signaling. Although two copies of each histone coexist in a nucleosome, they may not carry the same PTMs and are often differently modified (asymmetric). In bivalent domains, a chromatin signature prevalent in embryonic stem cells (ESCs), namely H3 methylated at lysine 4 (H3K4me3), coexists with H3K27me3 in asymmetric nucleosomes. We report a general, modular, and traceless method for producing asymmetrically modified nucleosomes. We further show that in bivalent nucleosomes, H3K4me3 inhibits the activity of the H3K27-specific lysine methyltransferase (KMT) polycomb repressive complex 2 (PRC2) solely on the same histone tail, whereas H3K27me3 stimulates PRC2 activity across tails, thereby partially overriding the H3K4me3-mediated repressive effect. To maintain bivalent domains in ESCs, PRC2 activity must thus be locally restricted or reversed.

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Exploring the effect of native and artificial peptide modifications on silaffin induced silica precipitation

Lechner

Becker

2012

Chem. Sci.

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Harnessing polarity and viscosity to identify green binary solvent mixtures as viable alternatives to DMF in solid-phase peptide synthesis

et al. 2021

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