Long-range stabilization of anthrax protective antigen upon binding to CMG2.

Protective antigen (PA) mediates entry of edema factor (EF) and lethal factor (LF) into the cytoplasmic space of the cells through the formation of a membrane-spanning pore. To do this, PA must initially bind to a host cellular receptor. Recent mass spectrometry analysis of PA using histidine hydrogen-deuterium exchange (His-HDX) has shown that binding of the von Willebrand factor A (vWA) domain of the receptor capillary morphogenesis protein-2 (CMG2) lowers the exchange rates of the imidazole C2 hydrogen of several histidines, suggesting that receptor binding decreases the structural flexibility of PA. Here, using His-HDX and fluorescence as a function of denaturant, and protease susceptibility, we show that binding of the vWA domain of CMG2 largely increases the stability of PA and the effect reaches up to 70 Å from the receptor binding interface. We also show that the pKa values and HDX rates of histidines located in separate domains change upon receptor binding. These results indicate that when one end of the protein is anchored, the structure of PA is tightened, noncovalent interactions are strengthened, and the global stability of the protein increases. These findings suggest that CMG2 may be used to stabilize PA in future anthrax vaccines.

(19)F nuclear magnetic resonance and crystallographic studies of 5-fluorotryptophan-labeled anthrax protective antigen and effects of the receptor on stability.

The anthrax protective antigen (PA) is an 83 kDa protein that is one of three protein components of the anthrax toxin, an AB toxin secreted by Bacillus anthracis. PA is capable of undergoing several structural changes, including oligomerization to either a heptameric or octameric structure called the prepore, and at acidic pH a major conformational change to form a membrane-spanning pore. To follow these structural changes at a residue-specific level, we have conducted initial studies in which we have biosynthetically incorporated 5-fluorotryptophan (5-FTrp) into PA, and we have studied the influence of 5-FTrp labeling on the structural stability of PA and on binding to the host receptor capillary morphogenesis protein 2 (CMG2) using (19)F nuclear magnetic resonance (NMR). There are seven tryptophans in PA, but of the four domains in PA, only two contain tryptophans: domain 1 (Trp65, -90, -136, -206, and -226) and domain 2 (Trp346 and -477). Trp346 is of particular interest because of its proximity to the CMG2 binding interface, and because it forms part of the membrane-spanning pore. We show that the (19)F resonance of Trp346 is sensitive to changes in pH, consistent with crystallographic studies, and that receptor binding significantly stabilizes Trp346 to both pH and temperature. In addition, we provide evidence that suggests that resonances from tryptophans distant from the binding interface are also stabilized by the receptor. Our studies highlight the positive impact of receptor binding on protein stability and the use of (19)F NMR in gaining insight into structural changes in a high-molecular weight protein.

Enhanced energy metabolism contributes to the extended life span of calorie-restricted Caenorhabditis elegans.

Caloric restriction (CR) markedly extends life span and improves the health of a broad number of species. Energy metabolism fundamentally contributes to the beneficial effects of CR, but the underlying mechanisms that are responsible for this effect remain enigmatic. A multidisciplinary approach that involves quantitative proteomics, immunochemistry, metabolic quantification, and life span analysis was used to determine how CR, which occurs in the Caenorhabditis elegans eat-2 mutants, modifies energy metabolism of the worm, and whether the observed modifications contribute to the CR-mediated physiological responses. A switch to fatty acid metabolism as an energy source and an enhanced rate of energy metabolism by eat-2 mutant nematodes were detected. Life span analyses validated the important role of these previously unknown alterations of energy metabolism in the CR-mediated longevity of nematodes. As observed in mice, the overexpression of the gene for the nematode analog of the cytosolic form of phosphoenolpyruvate carboxykinase caused a marked extension of the life span in C. elegans, presumably by enhancing energy metabolism via an altered rate of cataplerosis of tricarboxylic acid cycle anions. We conclude that an increase, not a decrease in fuel consumption, via an accelerated oxidation of fuels in the TCA cycle is involved in life span regulation; this mechanism may be conserved across phylogeny.

Rapid and effective removal of perfluorooctanoic acid from proteomics samples.

We recently demonstrated that perfluorooctanoic acid (PFOA), a volatile surfactant, is as effective as sodium dodecyl sulfate at solubilizing the membrane proteins. PFOA can be removed by repeated evaporation prior to mass spectrometry analysis. However, the removal of PFOA by evaporation is a lengthy process that takes approximately 6 h. Toward the goal of decreasing the length of time required to remove PFOA from protein digests, we tested the efficiency of PFOA removal and subsequent peptide recovery using strong cation exchange (SCX) chromatography, hydrophilic interaction chromatography (HILIC), fluorous solid phase extraction (FSPE), and anion exchange (ANX) chromatography. We found that all these chromatographic techniques except ANX chromatography remove PFOA thoroughly from protein digest. Peptide recovery rates from the SCX chromatography varied widely; nonacidic peptides were recovered at a rate of up to 95%, while acidic peptides were recovered at a rate of less than 10%. On the other hand, acidic peptides were recovered well from HILIC, while peptides whose pIs are greater than 6 were recovered poorly. Peptide recovery using FSPE was considerably lower, less than 10% for most of the peptides. These results indicate that the SCX and HILIC chromatography provide a more rapid alternative to the evaporation method for applications in which recovery of entire set of peptides is not required.

Quantitative measurement of the solvent accessibility of histidine imidazole groups in proteins.

We report a method for expressing the solvent accessibility of histidine imidazole groups in proteins. The method is based on measuring the rate of the hydrogen exchange (HX) reaction of the imidazole C(ε1)-hydrogen. The rate profile of the HX reaction as a function of pH gives a sigmoidal curve, which reaches the maximal rate constant (k(max)) on the alkaline side of the sigmoidal curve. To quantitatively describe the solvent accessibility of imidazole groups in proteins, it is necessary to compare the k(max) of the imidazole groups with their intrinsic k(max) ((i)k(max)), the maximal rate constants for the given imidazole groups when they are fully exposed to the bulk solvent. However, the mechanism of the HX reaction suggests that the (i)k(max) of an imidazole group differs depending on its pK(a), and no systematic study has been conducted to clarify how the (i)k(max) is affected by pK(a). We therefore investigated the relationship between (i)k(max) and pK(a) using four imidazole derivatives at three different temperatures. The experimentally determined pK(a)-specific (i)k(max) values allowed us to derive a general formula to estimate the (i)k(max) value of any given imidazole group exhibiting a specific pK(a) at a specific temperature. Using the formula, the protection factors (PF), the ratio of (i)k(max) to k(max), of five imidazole groups in dihydrofolate reductase were obtained and used to express the magnitude of their solvent accessibility. In this definition, the smaller the PF value, the higher the solvent accessibility, and a value of 1 indicates full exposure to the bulk solvent. The solvent accessibility expressed by the PF values agreed well with the solvent accessible surface areas obtained from the X-ray diffraction data.