Investigation into the protective ability of monovalent and bivalent A Malaysia 97 and A Iraq 64 vaccine strains against infection with an A/Asia/SEA-97 variant in pigs.

Over the last 15 years, FMDV serotype A viruses in South-East Asia (A/ASIA/SEA-97 lineage) have diverged into several clusters. Variants from Thailand in 2011-2013 have caused vaccine failures and returned poor r-values (<0.30) to A Iraq 64 (A22) and A Malaysia 97 (A May) vaccine strains.

Protection in sheep against heterologous challenge with serotype Asia-1 foot-and-mouth disease virus using high potency vaccine.

Foot-and-mouth disease virus (FMDV) serotype Asia-1 is prevalent in countries considered high risk for incursion into Australia, and has recently been responsible for a number of outbreaks in India, Bangladesh, Pakistan and Turkey. In vitro vaccine matching has shown a number of contemporary FMDV Asia-1 strains vary antigenically to the Asia-1 Shamir vaccine strain, which could result in poor protection with use of this vaccine. Therefore it was important to test the ability of the Asia-1 Shamir vaccine to protect sheep from challenge with a recent, heterologous strain at different days post-vaccination (dpv), including in an emergency vaccination scenario (challenge 4 or 7 dpv).

The protective capacity of high payload FMDV A22 IRQ vaccine in sheep against direct-contact challenge with a heterologous, contemporary FMDV A strain from South East Asia.

Foot-and-mouth disease (FMD) is an acute, highly contagious viral disease of domestic and wild cloven-hoofed animals, caused by FMD virus (FMDV). An FMD outbreak can cause major production losses and have significant implications for trade. Vaccination can assist in controlling the disease, and emergency vaccination using high antigen payload vaccines (>6 PD50/dose) is considered an important control approach in the event of an outbreak.

Structural basis for the interaction of the beta-secretase with copper.

The β-secretase (BACE1) features a unique sulfur rich motif (MxxxCxxxMxxxCxxxC) in its transmembrane helix (BACE1-TM) which is characteristic for proteins involved in copper ion storage and transport. While this motif has been shown to promote BACE1-TM trimerization and binding of copper ions in vitro, the structural basis for the interaction of copper ions with the BACE1-TM is still not well understood. Using molecular dynamics (MD) simulations, we show that membrane embedded BACE1-TMs adopt a flexible trimeric structure that binds and conducts copper ions through variable coordination.