PAS domain allostery and light-induced conformational changes in photoactive yellow protein upon I2 intermediate formation, probed with enhanced hydrogen/deuterium exchange mass spectrometry.

Photoactive yellow protein (PYP) is a small bacterial photoreceptor that undergoes a light-activated reaction cycle. PYP is also the prototypical Per-Arnt-Sim (PAS) domain. PAS domains, found in diverse multi-domain proteins from bacteria to humans, mediate protein-protein interactions and function as sensors and signal transducers. Here, we investigate conformational and dynamic changes in solution in wild-type PYP upon formation of the long-lived putative signaling intermediate I2 with enhanced hydrogen/deuterium exchange mass spectrometry (DXMS). The DXMS results showed that the central beta-sheet remains stable but specific external protein segments become strongly deprotected. Light-induced disruption of the dark-state hydrogen bonding network in I2 produces increased flexibility and opening of PAS core helices alpha3 and alpha4, releases the beta4-beta5 hairpin, and propagates conformational changes to the central beta-sheet. Surprisingly, the first approximately 10 N-terminal residues, which are essential for fast dark-state recovery from I2, become more protected. By combining the DXMS results with our crystallographic structures, which reveal detailed changes near the chromophore but limited protein conformational change, we propose a mechanism for I2 state formation. This mechanism integrates the results from diverse biophysical studies of PYP, and links an allosteric T to R-state conformational transition to three pathways for signal propagation within the PYP fold. On the basis of the observed changes in PYP plus commonalities shared among PAS domain proteins, we further propose that PAS domains share this conformational mechanism, which explains the versatile signal transduction properties of the structurally conserved PYP/PAS module by framework-encoded allostery.

Molecular determinants for interaction of SHEP1 with Cas localize to a highly solvent-protected region in the complex.

Protein-protein interactions between SHEP and Cas proteins influence cellular signaling through tyrosine kinases, as well as integrin-mediated signaling, and may be linked to antiestrogen resistance. Data from past studies suggests that association between SHEP and Cas proteins is critical for these cellular effects. In this study, the interacting domains of each protein were co-expressed in bacteria and a soluble stable complex was purified. Deuterium exchange mass spectrometry was used to define regions that are buried when SHEP1 is in complex with Cas. The results reveal four segments in SHEP1 that are highly protected, including a region (residues 619-640) that contains a key residue, tyrosine 635, required for association with Cas. This region is predominately hydrophilic, yet remains protected from solvent in the complex.

Structural determinants for the binding of anthrax lethal factor to oligomeric protective antigen.

Anthrax lethal toxin assembles at the surface of mammalian cells when the lethal factor (LF) binds via its amino-terminal domain, LF(N), to oligomeric forms of activated protective antigen (PA). LF x PA complexes are then trafficked to acidified endosomes, where PA forms heptameric pores in the bounding membrane and LF translocates through these pores to the cytosol. We used enhanced peptide amide hydrogen/deuterium exchange mass spectrometry and directed mutagenesis to define the surface on LF(N) that interacts with PA. A continuous surface encompassing one face of LF(N) became protected from deuterium exchange when LF(N) was bound to a PA dimer. Directed mutational analysis demonstrated that residues within this surface on LF(N) interact with Lys-197 on two PA subunits simultaneously, thereby showing that LF(N) spans the PA subunit:subunit interface and explaining why heptameric PA binds a maximum of three LF(N) molecules. Our results elucidate the structural basis for anthrax lethal toxin assembly and may be useful in developing drugs to block toxin action.

Characterization of the PR domain of RIZ1 histone methyltransferase.

RIZ1 (PRDM2) and PRDI-BF1 (PRDM1) are involved in B cell differentiation and the development of B cell lymphomas. These proteins are expressed in two forms that differ by the presence or absence of a PR domain. The protein product that retains the PR domain is anti-tumorigenic while the product that lacks the PR domain is oncogenic and over-expressed in tumor cells. The conserved PR domain is homologous to the SET domain from a family of histone methyltransferases. RIZ1 is also a histone methyltransferase and methylates lysine 9 in histone H3. This activity has been mapped to the PR domain. In the present study, deuterium exchange mass spectrometry was used to define the structural boundaries of the RIZ1 PR domain and to map sites of missense mutations that occur in human cancers and reduce methyltransferase activity. Flexible segments were selectively deleted to produce protein products that crystallize for structural studies. Segments at the carboxyl terminus of the PR domain that are involved in methylation of H3 were shown to be flexible, similar to SET domains, suggesting that the PR and SET methyltransferases may belong to an emerging class of proteins that contain mobile functional regions.