Quantitative Assessment of Electrostatic Embedding in Density Functional Theory Calculations of Biomolecular Systems.

We evaluate the accuracy of density functional theory quantum calculations of biomolecular subsystems using a simple electrostatic embedding scheme. Our scheme is based on dividing the system of interest into a primary and secondary subsystem. A finite difference discretization of the Kohn-Sham equations is used for the primary subsystem, while its electrostatic environment is modeled with a simple one-electron potential. Force-field atomic partial charges are used to generate smeared Gaussian charge densities and to model the secondary subsystem. We illustrate the utility of this approach with calculations of truncated dipeptide chains. We analyze quantitatively the accuracy of this approach by calculating atomic forces and comparing results with full QM calculations. The impact of the choice made in terminating dangling bonds at the frontier of the QM region is also investigated.

Hydrophobic hydration is an important source of elasticity in elastin-based biopolymers.

Molecular dynamics simulations with explicit waters have been employed to investigate the dominant source of elastin's elasticity. An elastin-like peptide, (VPGVG)(18), was pulled and released in molecular dynamics simulations, at 10 and 42 degrees C, lasting several nanoseconds, which is consistent with the experimentally determined dielectric and NMR relaxation time scales. At elastin's physiological temperature and degree of extension, the simulations indicate that the orientational entropy of waters hydrating hydrophobic groups decreases during pulling of the molecule, but it increases upon release. In contrast, the main-chain fluctuations and other measures of mobility suggest that elastin's backbone is more dynamic in the extended than released state. These results and the agreement between the simulations with various experimental observations suggest that hydrophobic hydration is an important source of the entropy-based elasticity of elastin. Moreover, elastin tends to reorder itself to form a hydrophobic globule when it was held in its extended state, indicating that the hydrophobic effect also contributes in the holding process. On the whole, our simulations support the hydrophobic mechanism of elasticity and provide a framework for description of the molecular basis of this phenomenon.

Response to intradialytic parenteral nutrition.

Malnutrition is a major clinical problem in patients receiving maintenance hemodialysis and has adverse effects on survival. Nutritional intervention is indicated, and there is evidence that intradialytic parenteral nutrition can be beneficial. We describe the application of a formal policy regarding the use of intradialytic parenteral nutrition and the beneficial effects on nutrition in the first four patients managed in this fashion. However, the fifth patient did not respond to parenteral nutrition, despite adequate dialysis. This prompted further investigation, and the patient was shown to have extensive gastric malignancy. This report shows that establishing a protocol for intradialytic parenteral nutrition is possible in a medium-sized hemodialysis unit. In these circumstances, nonresponse to this intervention should always be investigated to determine if there is another underlying cause of malnutrition unrelated to renal failure.

Interdomain information transfer during substrate activation of yeast pyruvate decarboxylase: the interaction between cysteine 221 and histidine 92.

Oligonucleotide-directed site-specific mutagenesis was carried out on pyruvate decarboxylase (EC 4.1.1.1) from Saccharomyces cerevisiae at two cysteines on the beta domain (221 and 222) and at H92 on the alpha domain, across the domain divide from C221. While C221 has been shown to provide the trigger for substrate activation [Baburina, I., et al. (1994) Biochemistry 33, 5630-5635], the information must be transmitted from the substrate bound at this site [Arjunan, D., et al. (1996) J. Mol. Biol. 256, 590-600] to the active center thiamin diphosphate located at the interface of the alpha and gamma domains. Substitution at H92 with G, A, or C leads to great reduction of the Hill coefficient (from 2.0 in the wild-type enzyme to 1.2-1.3), while substitution for Lys affords an active enzyme with a Hill coefficient of 1.5-1.6. Iodoacetate at 10 mM reduced the Hill coefficient from 2.0 to 1.1, while also causing significant inactivation of the enzyme, presumably by carboxymethylation of C221. 1,3-Dibromoacetone, a potential cross-linker when added to the H92C/C222S variant at 0.1 mM, abolished substrate activation while reducing the activity only by 30%. Therefore, 1,3-dibromoacetone may cross-link C92 and C221. It was concluded that H92 is on the information transfer pathway during the substrate activation process and the interaction between C221 on the beta domain and H92 on the alpha domain is required for substrate activation. Extensive pH studies of the steady-state kinetic constants provide support for the interaction of C221 and H92 and the transmission of regulatory information to the active center via this pathway and pKaS for the two groups. This important interaction between the C221-bound pyruvate and His92 probably has both electrostatic and steric components.