• The pathogen Acinetobacter baumannii is one of three highest priority pathogens identified by WHO (World Health Organisation) for which new antibiotics are urgently needed
• Understanding the enzymes that assemble antibiotics which can kill the pathogen is key to altering their structures to target the pathogen more effectively

Researchers at the University of Warwick have made a breakthrough in understanding the functions and structures of key enzymes in the assembly of an antibiotic with activity against the pathogen, which could enable more effective versions to be created

For the full article, see here.

Congratulations to Dr Matthew Jenner, Leverhulme Early Career Research Fellow in the Department of Chemistry, who has been awarded a BBSRC Future Leader Fellowship.

Full press release here

Peptide-mimetic metallohelices bind Alzheimer protein and extend life in an insect model

The GibsonGroup report in Angewandte Chemie a new macromolecular ‘antifreeze’ which improves the cryopreservation of cells

Timur Avkiran, a postgraduate researcher in the Department of Chemistry, has been awared an Industrial Fellowship by The Royal Commission for the Exhibition of 1851 to design and synthesise small molecule drugs for improving Tuberculosis treatment.

On Saturday morning (east cost US time, Saturday night in UK), a team of students from Edgecombe Community College (Carolina, USA), in collaboration with NASA and NC space grant, will launch a student-lead high altitude baloon, including an experiment based on the GibsonGroups innovative cryopreservation science.

The balloon will be launched to 60 to 100,000 feet, so high that the curvature of the Earth will be clearly visible. It will contain experiments to track movement, altitude humitity and more, but also 1 additional science experiment. The students, lead by Jillian Leary approached Professor Gibson to ask if the GibsonGroup's unique ice-growth inhibiting polymers, inspired by Natures antifreeze proteins, could be included as an experiment to see how cells respond to the harsh high-altitude envirnoments. The polymers are design to stop ice crystals growing, and enables cells, which would otherwise need large volumes of toxic solvents to survive being frozen and stressed. This technology has the potential to revolutionise regenerative and transplantation medicine.

The launch will be streamed live on facebook https://www.facebook.com/EdgecombeCC/posts/?ref=page_internal

Read more here https://www.edgecombe.edu/news/students-preparing-high-altitude-balloon-launch/

Several studentship opportunities for PhD study are available in the Chemistry Department of Warwick University.

Collaborative work between the Blindauer group and the teams of Prof. Wladek Minor (University of Virginia), Dr Maksymilian Chruszcz (University of South Carolina) and Dr Alan Stewart (University of St. Andrews) has been highlighted in a press release entitled “Here’s How Your Body Transports Zinc to Protect Your Health“.

This relates to a recent joint publication which reports the first X-ray crystal structures of human and equine serum albumins bound to zinc. Serum albumin is the major carrier of zinc in the blood and is required for the effective systemic distribution of this essential nutrient. The new findings are published in the RSC journal Chemical Science. Full text of the open-access article is available here.

An antibody that senses one enantiomer of plant hormone abscisic acid (ABA) is characterised and published by Marsh and Napier groups in Chemistry and Life Sciences in PLOS ONE.