Structure-guided design of pyrazolo[1,5-a]pyrimidines as inhibitors of human cyclin-dependent kinase 2.

The protein structure guided design of a series of pyrazolo[1,5-a]pyrimidines with high potency for human cyclin-dependent kinase 2 (CDK2) is described. Some examples were shown to inhibit the growth of human colon tumour cells, were equipotent for CDK1 and were selective against GSK-3beta and other kinases.

Structure-based design of agents targeting the bacterial ribosome.

Rational structure-based drug design has been applied to the antibiotic thiostrepton, in an attempt to overcome some of its' limitations. The identification of a proposed binding fragment allowed construction of a number of key fragments, which were derivatised to generate a library of potential antibiotics. These were then evaluated to determine their ability to bind to the L11 binding domain of the prokaryotic ribosome and inhibit bacterial protein translation.

Characterisation of the immune response to the UK human anthrax vaccine.

The UK human anthrax vaccine consists of the alum-precipitated culture supernatant of Bacillus anthracis Sterne. In addition to protective antigen (PA), the key immunogen, the vaccine also contains a number of other bacteria- and media-derived proteins. These proteins may contribute to the transient side effects experienced by some individuals and could influence the development of the PA-specific immune response. Bacterial cell-wall components have been shown to be potent immunomodulators. B. anthracis expresses two S-layer proteins, EA1 and Sap, which have been demonstrated to be immunogenic in animal studies. These are also immunogenic in man so that convalescent and post-immunisation sera contain specific antibodies to Ea1, and to a lesser extent, to Sap. To determine if these proteins are capable of modifying the protective immune response to PA, A/J mice were immunised with equivalent amounts of recombinant PA and S-layer proteins in the presence of alhydrogel. IgG isotype profiles were determined and the animals were subsequently challenged with spores of B. anthracis STI. The results suggest that there was no significant shift in IgG isotype profile and that the presence of the S-layer proteins did not adversely affect the protective immune response induced by PA.

Mucosal or parenteral administration of microsphere-associated Bacillus anthracis protective antigen protects against anthrax infection in mice.

Existing licensed anthrax vaccines are administered parenterally and require multiple doses to induce protective immunity. This requires trained personnel and is not the optimum route for stimulating a mucosal immune response. Microencapsulation of vaccine antigens offers a number of advantages over traditional vaccine formulations, including stability without refrigeration and the potential for utilizing less invasive routes of administration. Recombinant protective antigen (rPA), the dominant antigen for protection against anthrax infection, was encapsulated in poly-L-lactide 100-kDa microspheres. Alternatively, rPA was loosely attached to the surfaces of microspheres by lyophilization. All of the microspheric formulations were administered to A/J mice with a two-dose schedule by either the intramuscular route, the intranasal route, or a combination of these two routes, and immunogenicity and protective efficacy were assessed. An intramuscular priming immunization followed by either an intramuscular or intranasal boost gave optimum anti-rPA immunoglobulin G titers. Despite differences in rPA-specific antibody titers, all immunized mice survived an injected challenge consisting of 10(3) median lethal doses of Bacillus anthracis STI spores. Immunization with microencapsulated and microsphere-associated formulations of rPA also protected against aerosol challenge with 30 median lethal doses of STI spores. These results show that rPA can be encapsulated and surface bound to polymeric microspheres without impairing its immunogenicity and also that mucosal or parenteral administration of microspheric formulations of rPA efficiently protects mice against both injected and aerosol challenges with B. anthracis spores. Microspheric formulations of rPA could represent the next generation of anthrax vaccines, which could require fewer doses because they are more potent, are less reactogenic than currently available human anthrax vaccines, and could be self-administered without injection.