M13 bacteriophage coat proteins engineered for improved phage display.

This chapter describes a method for increasing levels of protein fusions displayed on the surfaces of M13 bacteriophage particles. By introducing mutations into the anchoring M13 coat protein, protein display levels can be increased by up to two orders of magnitude. Experimental methods are presented for the design, construction, and screening of phage-displayed libraries for improved protein display.

Computational design and selections for an engineered, thermostable terpene synthase.

Terpenoids include structurally diverse antibiotics, flavorings, and fragrances. Engineering terpene synthases for control over the synthesis of such compounds represents a long sought goal. We report computational design, selections, and assays of a thermostable mutant of tobacco 5-epi-aristolochene synthase (TEAS) for the catalysis of carbocation cyclization reactions at elevated temperatures. Selection for thermostability included proteolytic digestion followed by capture of intact proteins. Unlike the wild-type enzyme, the mutant TEAS retains enzymatic activity at 65°C. The thermostable terpene synthase variant denatures above 80°C, approximately twice the temperature of the wild-type enzyme.

Sequestration of plant-derived phenolglucosides by larvae of the leaf beetle Chrysomela lapponica: thioglucosides as mechanistic probes.

Feeding larvae of Chrysomela lapponica (Coleoptera: Chrysomelidae) acquire characteristic O-glucosides from the leaves of their food plants. The glucosides are selectively channeled from the gut to the defensive gland. Subsequent enzymatic transformations generate a blend of different defensive compounds, e.g., salicylaldehyde and two series of 2-methylbutyl and isobutyryl esters. By using systematically modified and hydrolysis-resistant thioglucosides as structural mimics of the plant-derived glucosides, e.g., salicin and its o-, m-, and p-isomers 1, 2, and 3; o-, m-, and p-cresols 5, 6, 7; along with thioglucosides of 2-phenylethanol 9 and (3Z)-hexenol 10, we demonstrated that the larvae of C. lapponica are able to sequester a broad range of structurally different thioglucosides with comparable efficiency. This sharply contrasts with the sequestration habitus previously observed in Chrysomela populi and Phratora vitellinae, which secrete almost pure salicylaldehyde and posses a highly specific transport mechanism for salicin (Kuhn et al., Proc. Natl. Acad. Sci. USA 101:13808-13813, 2004). Also, neither C. lapponica nor C. populi sequester in their gland the thioglucoside of 8-hydroxygeraniol, the mimic of the glucoside specifically transported by larvae secreting iridoid monoterpenes (Phaedon cochleariae, Gastrophysa viridula). Accordingly, leaf beetle larvae possess selective membrane carriers in their gut and their defensive systems that match the orientation of the functional groups of glucosides from their food plants probably by embedding the substrate in a network of hydrogen bonds inside the membrane carriers. The synthesis and the spectroscopic properties of the test compounds along with a comparative evaluation of the transport capabilities of larvae of C. populi and C. lapponica are described.

Convenient methods for the synthesis of P1-farnesyl-P2-indicator diphosphates.

To access P1-farnesyl-P2-indicator diphosphates, more efficient methods for the synthesis of farnesyl-phosphate and diphosphates were developed. The procedures reported here provide more flexible conditions than the conventional imidazolide and morpholidate coupling methods. Milder conditions for the synthesis of sensitive allylic diphosphates and greatly improved reaction efficiencies provide access to novel reagents for analysis of diphosphate-based enzymatic reactions.

Selective transport systems mediate sequestration of plant glucosides in leaf beetles: a molecular basis for adaptation and evolution.

Chrysomeline larvae respond to disturbance and attack by everting dorsal glandular reservoirs, which release defensive secretions. The ancestral defense is based on the de novo synthesis of monoterpene iridoids. The catabolization of the host-plant O-glucoside salicin into salicylaldehyde is a character state that evolved later in two distinct lineages, which specialized on Salicaceae. By using two species producing monoterpenes (Hydrothassa marginella and Phratora laticollis) and two sequestering species (Chrysomela populi and Phratora vitellinae), we studied the molecular basis of sequestration by feeding the larvae structurally different thioglucosides resembling natural O-glucosides. Their accumulation in the defensive systems demonstrated that the larvae possess transport systems, which are evolutionarily adapted to the glycosides of their host plants. Minor structural modifications in the aglycon result in drastically reduced transport rates of the test compounds. Moreover, the ancestral iridoid-producing leaf beetles already possess a fully functional import system for an early precursor of the iridoid defenses. Our data confirm an evolutionary scenario in which, after a host-plant change, the transport system of the leaf beetles may play a pivotal role in the adaptation on new hosts by selecting plant-derived glucosides that can be channeled to the defensive system.