N-terminal glutamate to pyroglutamate conversion in vivo for human IgG2 antibodies.

Therapeutic proteins contain a large number of post-translational modifications, some of which could potentially impact their safety or efficacy. In one of these changes, pyroglutamate can form on the N terminus of the polypeptide chain. Both glutamine and glutamate at the N termini of recombinant monoclonal antibodies can cyclize spontaneously to pyroglutamate (pE) in vitro.

Use of site-directed cysteine and disulfide chemistry to probe protein structure and dynamics: applications to soluble and transmembrane receptors of bacterial chemotaxis.

Site-directed cysteine and disulfide chemistry is broadly useful in the analysis of protein structure and dynamics, and applications of this chemistry to the bacterial chemotaxis pathway have illustrated the kinds of information that can be generated. Notably, in many cases, cysteine and disulfide chemistry can be carried out in the native environment of the protein whether it be aqueous solution, a lipid bilayer, or a multiprotein complex. Moreover, the approach can tackle three types of problems crucial to a molecular understanding of a given protein: (1) it can map out 2 degrees structure, 3 degrees structure, and 4 degrees structure; (2) it can analyze conformational changes and the structural basis of regulation by covalently trapping specific conformational or signaling states; and (3) it can uncover the spatial and temporal aspects of thermal fluctuations by detecting backbone and domain dynamics.

The PICM chemical scanning method for identifying domain-domain and protein-protein interfaces: applications to the core signaling complex of E. coli chemotaxis.

The number of known protein structures is growing exponentially (Berman et al., 2000), but the structural mapping of essential domain-domain and protein-protein interaction surfaces has advanced more slowly. It is particularly difficult to analyze the interaction surfaces of membrane proteins on a structural level, both because membrane proteins are less accessible to high-resolution structural analysis and because the membrane environment is often required for native complex formation.

Conserved glycine residues in the cytoplasmic domain of the aspartate receptor play essential roles in kinase coupling and on-off switching.

The aspartate receptor of the bacterial chemotaxis pathway serves as a scaffold for the formation of a multiprotein signaling complex containing the receptor and the cytoplasmic pathway components. Within this complex, the receptor regulates the autophosphorylation activity of histidine kinase CheA, thereby controlling the signals sent to the flagellar motor and the receptor adaptation system. The receptor cytoplasmic domain, which controls the on-off switching of CheA, possesses 14 glycine residues that are highly conserved in related receptors.

Conversion of a mechanosensitive channel protein from a membrane-embedded to a water-soluble form by covalent modification with amphiphiles.

Covalent modification of integral membrane proteins with amphiphiles may provide a general approach to the conversion of membrane proteins into water-soluble forms for biophysical and high-resolution structural studies. To test this approach, we mutated four surface residues of the pentameric Mycobacterium tuberculosis mechanosensitive channel of large conductance (MscL) to cysteine residues as anchors for amphiphile attachment. A series of modified ion channels with four amphiphile groups attached per channel subunit was prepared.

The structures of BtuCD and MscS and their implications for transporter and channel function.

The passage of most molecules across biological membranes is mediated by specialized integral membrane proteins known as channels and transporters. Although these transport families encompass a wide range of functions, molecular architectures and mechanisms, there are common elements that must be incorporated within their structures, namely the translocation pathway, ligand specificity elements and regulatory sensors to control the rate of ligand flow across the membrane. This minireview discusses aspects of the structure and mechanism of two bacterial transport systems, the stretch-activated mechanosensitive channel of small conductance (MscS) and the ATP-dependent vitamin B12 uptake system (BtuCD), emphasizing their general implications for transporter function.

Crystal structure of Escherichia coli MscS, a voltage-modulated and mechanosensitive channel.

The mechanosensitive channel of small conductance (MscS) responds both to stretching of the cell membrane and to membrane depolarization. The crystal structure at 3.9 angstroms resolution demonstrates that Escherichia coli MscS folds as a membrane-spanning heptamer with a large cytoplasmic region.