HELP-based matrices for stimuli-responsive controlled release of bioactive compounds

Direct delivery of bioactive substances to the sites of injury represents a key issue for therapies based on regenerative medicine and tissue repair [1]. Protein derived hydrogels represent an interesting system for this purpose because they possess several features that make them suitable to this purpose. A method for preparation of hydrogel matrices based on Human Elastin-like Polypeptide (HELP) has been set up [2]. HELPs are a family of elastin-like recombinant biopolymers modeled after the most regularly repeated domain in human tropoelastin, retaining peculiar properties as self-assembling and thermoresponsive behavior [3]. In this study we assayed two elastolytic activities from different sources to test their potential to specifically degrade the HELP matrix

A tryptophan ‘gate’ in the CRISPR-Cas3 nuclease controls ssDNA entry into the nuclease site, that when removed results in nuclease hyperactivity

Cas3 is a ssDNA-targeting nuclease-helicase essential for class 1 prokaryotic CRISPR immunity systems, which has been utilized for genome editing in human cells. Cas3-DNA crystal structures show that ssDNA follows a pathway from helicase domains into a HD-nuclease active site, requiring protein conformational flexibility during DNA translocation. In genetic studies, we had noted that the efficacy of Cas3 in CRISPR immunity was drastically reduced when temperature was increased from 30C to 37C, caused by an unknown mechanism. Here, using E. coli Cas3 proteins, we show that reduced nuclease activity at higher temperature corresponds with measurable changes in protein structure. This effect of temperature on Cas3 was alleviated by changing a single highly conserved tryptophan residue (Trp-406) into an alanine. This Cas3W406A protein is a hyperactive nuclease that functions independently from temperature and from the interference effector module Cascade. Trp-406 is situated at the interface of Cas3 HD and RecA1 domains that is important for maneuvering DNA into the nuclease active site. Molecular dynamics simulations based on the experimental data showed temperature-induced changes in positioning of Trp-406 that either blocked or cleared the ssDNA pathway. We propose that Trp- 406 forms a ‘gate’ for controlling Cas3 nuclease activity via access of ssDNA to the nuclease active site. The effect of temperature in these experiments may indicate allosteric control of Cas3 nuclease activity caused by changes in protein conformations. The hyperactive Cas3W406A protein may offer improved Cas3-based genetic editing in human cells

Integrative epigenome-wide analysis demonstrates that DNA methylation may mediate genetic risk in inflammatory bowel disease

Epigenetic alterations may provide important insights into gene-environment interaction in inflammatory bowel disease (IBD). Here we observe epigenome-wide DNA methylation differences in 240 newly-diagnosed IBD cases and 190 controls. These include 439 differentially methylated positions (DMPs) and 5 differentially methylated regions (DMRs), which we study in detail using whole genome bisulphite sequencing. We replicate the top DMP (RPS6KA2) and DMRs (VMP1, ITGB2 and TXK) in an independent cohort. Using paired genetic and epigenetic data, we delineate methylation quantitative trait loci; VMP1/microRNA-21 methylation associates with two polymorphisms in linkage disequilibrium with a known IBD susceptibility variant. Separated cell data shows that IBD-associated hypermethylation within the TXK promoter region negatively correlates with gene expression in whole-blood and CD8+ T cells, but not other cell types. Thus, site-specific DNA methylation changes in IBD relate to underlying genotype and associate with cell-specific alteration in gene expression

Bioproduction of Anticancer Podophyllotoxin and Related Aryltretralin-Lignans in Hairy Root Cultures of Linum Flavum L.

Podophyllotoxin (PPT) is the unique natural precursor of Etoposide, a topoisomerase II inhibitor drug, used in more than a dozen anticancer chemotherapy treatments. Etoposide is appearing on the list of essential medicines of the World Health Organization. PPT is still exclusively extracted from the rhizome of Podophyllum species, its main natural source. The supply of Podophyllum hexandrum plants is limited, since the occurrence of these plant species is scarce, collection is destructive, and the plants need a long regeneration period. As a consequence, this species is now endangered and listed on Appendix II of the Convention on International Trading of Endangered Species. Chemical synthesis of PPT is difficult due to the presence of four contiguous chiral centers and the presence of a base sensitive trans-lactone moiety. Alternatives are being actively searched, but so far, no wild plants have been described with similar PPT production capacity as compared to Podophyllum. However, several plants producing PPT or other related aryltetralin lignans (ATL) have been identified in recent decades, including the Linaceae. Given its high lignan accumulation capacity, Linum flavum is considered a promising alternative source of PPT and other related ATL. However, unlike the common flax L. usitatissimum, L. flavum has a low agricultural potential (e.g., slow growth and dehiscence of fruits). Therefore, in vitro cultures of plant cells and/or tissues provide an interesting alternative to whole L. flavum plants for the production of these valuable ATL. In particular, L. flavum hairy roots (HRs) accumulate high levels of ATL and it is also possible to further increase this ATL accumulation by the selection of the best genotype, optimization of cultures media and conditions and choice of carbon sources, use of plant growth regulators, elicitor treatments, or precursors’ addition. To date, the ATL accumulation levels can still be perceived insufficient for L. flavum HRs before being used as a commercially viable biotechnological production system. To reach this goal, a better knowledge of the mechanisms that regulate the metabolic flux of intermediates in the different branches of the ATL metabolic pathway will be an important prerequisite to direct the biosynthesis toward the production of a high amount of the desired PPT. In the future, metabolic engineering aiming at constructing the PPT pathway in a heterologous host is very appealing, but for that approach in-depth knowledge of the biosynthetic pathway toward PPT and other related ATL is necessary

Stimuli-Induced Release of Compounds from Elastin Biomimetic Matrix

Stimuli-responsive hydrogel matrices have attracted great attention in biomedical and biotechnological fields for controlled delivery of bioactive compounds, as well as a vehicle for therapeutic cell spreading. Elastin-derived biomimetic polypeptides are recombinant macromolecules suitable for the realization of smart biomaterials. In this study, we explored the potential of an elastin biomimetic matrix to realize proteolytic stimuli-responsive systems to control the release of substances. Our approach showed that this matrix was susceptible to elastolytic degradation, and it has been successfully employed to obtain an efficient delivery of a model protein. This setup will constitute a therapeutic agent delivery platform to realize devices capable of responding and interacting with biological systems at the molecular level

Integrative epigenome-wide analysis demonstrates that DNA methylation may mediate genetic risk in inflammatory bowel disease

Epigenetic alterations may provide important insights into gene-environment interaction in inflammatory bowel disease (IBD). Here we observe epigenome-wide DNA methylation differences in 240 newly-diagnosed IBD cases and 190 controls. These include 439 differentially methylated positions (DMPs) and 5 differentially methylated regions (DMRs), which we study in detail using whole genome bisulphite sequencing. We replicate the top DMP (RPS6KA2) and DMRs (VMP1, ITGB2 and TXK) in an independent cohort. Using paired genetic and epigenetic data, we delineate methylation quantitative trait loci; VMP1/microRNA-21 methylation associates with two polymorphisms in linkage disequilibrium with a known IBD susceptibility variant. Separated cell data shows that IBD-associated hypermethylation within the TXK promoter region negatively correlates with gene expression in whole-blood and CD8+T cells, but not other cell types. Thus, site-specific DNA methylation changes in IBD relate to underlying genotype and associate with cell-specific alteration in gene expression