Article on lectin-inhibitors published in ChemMedChem

Karolina and Joe’s review article on “Structural considerations for building synthetic glycoconjugates as inhibitors for Pseudomonas aeruginosa lectins” has been published by ChemMedChem. The article is available here: https://doi.org/10.1002/cmdc.202200081

Pseudomonas aeruginosa is a pathogenic bacterium, responsible for a large portion of nosocomial infections globally and designated as critical priority by the World Health Organisation. Its characteristic carbohydrate-binding proteins LecA and LecB, which play a role in biofilm-formation and lung-infection, can be targeted by glycoconjugates. In the review, we present the wide range of inhibitors for these proteins (136 references), highlighting structural features and which impact binding affinity and/or therapeutic effects, including carbohydrate selection; linker length and rigidity; and scaffold topology, particularly for multivalent candidates. We also discuss emerging therapeutic strategies, which build on targeting of LecA and LecB, such as anti-biofilm activity, anti-adhesion and drug-delivery, with promising prospects for medicinal chemistry.

This article would be a good entry-point for any researchers considering tackling P. aeruginosa as a target organism, particularly if they want to build lectin-targeting ligands building on the existing consensus in the field on the best structural features to ensure high lectin affinity.

Thanks to Science Foundation Ireland for funding this research.

New article in RSC Advances: Glycoclusters with anti-biofilm activity

Our new article, published in RSC Advances (a Gold Open Access journal), describes a series of new ruthenium-centred glycoclusters, which present four carbohydrate motifs around a three-dimensional octahedral scaffold. Multivalent glycoclusters have previously shown the ability to inhibit the carbohydrate-binding proteins which are produced by bacterium P. aeruginosa. Gordon Cooke’s group in TU Dublin tested these new compounds for their ability to inhibit growth of biofilm by P. aeruginosa and we observed that complex 8Gal, with flexible arms between the scaffold core and the galactose motif gave up to 80% inhibition of biofilm, when compared to the control – the other complexes and the ligand did not show antimicrobial activity. We propose that this activity is due to the ability of galactose to interact with the carbohydrate-binding protein LecA.

We thank Science Foundation Ireland for financial support for this work, as well as UCD School of Medicine’s SSRA Scheme, where preliminary studies began.

New paper in ChemCatChem

Joe was part of a collaborative project between University of Bern (Switzerland) and Universitat Jaume I (Spain), which was recently published in ChemCatChem. This work describes the use of mesoionic iridium(III)-NHC complexes as catalysts for efficient dehydrogenation of carbohydrates in water. Without the need for additives, these complexes compare were to previous work published by Dr Jose Mata’s group, using imdazolylidene iridium(III) complexes, along with sulfuric acid.

DOI: 10.1002/cctc.202000544R1

Introducing abnormal triazolylidene NHC complexes from the Albrecht lab, allowed for this further enhancement of activity for this interesting reaction, which releases hydrogen from carbohydrate substrates, giving only the carbohydrate acid (e.g. gluconic acid) as a by-product, which has potential utility as a initial platform chemical for further synthesis, derived from biomass feedstocks.

New publication in Dalton Transactions

I’m delighted to finally publish this work, the first of my research carried out during my Marie Curie Fellowship in University of Bern to come out. A lot of hard work by Erasmus student Pauline went into gathering data behind this manuscript where we asked the question – what impact would incorporating carbohydrates into the structure of a Ruthenium(II)-triazolylidene complex have on its ability to convert a ketone to an alcohol via transfer hydrogenation catalysis.

There were challenges in isolating the desired compound, so it had to be generated in situ, but we were able to assess the activity, and the results were interesting, and can be found in detail here in Dalton Transactions.

To summarise the conclusions: The carbohydrate functionality does impact catalytic activity (transfer hydrogenation of ketones). In complexes with the glucose directly triazolylidene-bound,  turnover rates were substantially higher when compared to more remote carbohydrate functionalisation (i.e. with an ethylene spacer). Both new complexes, however, have reduced activity compared to  unfunctionalised carbene complexes. Insight was also gained into the nature of the catalytic cycle through a substrate scope analysis.