Linear furocoumarins and other constituents from thamnosma texana

Eight linear furocoumarins and three coumarins were isolated and identified from Thamnosma texana. They were xanthotoxin, imperatorin, bergapten, alloimperatorin methyl ether epoxide, heraclenin, isopimpinellin, psoralen, oxypeucedanin, and the coumarins herniarin, osthol and thamnosmin. The linear furocoumarins appear to be agents that account for the known photosensitizing properties of Thamnosma texana, and consequently its colloquial name, ‘blisterweed.’ This is the first report on the occurrence of imperatorin, heraclenin, oxypeucedanin, herniarin or osthol in any Thamnosma species.     

Noninvasive measurement of protein aggregation by mutant huntingtin fragments or alpha-synuclein in the lens

Many diverse human diseases are associated with protein aggregation in ordered fibrillar structures called amyloid. Amyloid formation may mediate aberrant protein interactions that culminate in neurodegeneration in Alzheimer, Huntington, and Parkinson diseases and in prion encephalopathies. Studies of protein aggregation in the brain are hampered by limitations in imaging techniques and often require invasive methods that can only be performed postmortem. Here we describe transgenic mice in which aggregation-prone proteins that cause Huntington and Parkinson disease are expressed in the ocular lens. Expression of a mutant huntingtin fragment or alpha-synuclein in the lens leads to protein aggregation and cataract formation, which can be monitored in real time by noninvasive, highly sensitive optical techniques. Expression of a mutant huntingtin fragment in mice lacking the major lens chaperone, alphaB-crystallin, markedly accelerated the onset and severity of aggregation, demonstrating that the endogenous chaperone activity of alphaB-crystallin suppresses aggregation in vivo. These novel mouse models will facilitate the characterization of protein aggregation in vivo and are being used in efficient and economical screens for chemical and genetic modifiers of disease-relevant protein aggregation.     

Correlating structure and affinity for PEX5:PTS1 complexes

Many proteins that are destined to reside within the lumen of the peroxisome contain the peroxisomal targeting signal-1 (PTS1), a C-terminal tripeptide approximating the consensus sequence -Ser-Lys-Leu-COO(-). The PTS1 is recognized by the tetratricopeptide repeat (TPR) domains of PEX5, a cytosolic receptor that cycles between the cytoplasm and the peroxisome. To gain insight into the energetics of PTS1 binding specificity and to correlate these with features from the recently determined structure of a PEX5:PTS1 complex, we used a fluorescence-based binding assay that enables the quantitation of the dissociation constants for PTS1-containing peptide complexes with the TPR region of human PEX5. Through application of this assay to a collection of pentapeptides containing different C-terminal tripeptide sequences, including both natural and unnatural amino acids, the thermodynamic effects of sequence variation were examined. PTS1 variants that correspond to known functional targeting signals bind to the PEX5 fragment with a change in the standard binding free energy within 1.8 kcal mol(-1) of that corresponding to the peptide ending with -Ser-Lys-Leu-COO(-). The results suggest that a binding energy threshold may determine the functionality of PTS1 sequences.     

A fast and robust 19F NMR-based method for finding new HIV-1 protease inhibitors

The human immunodeficiency virus (HIV) which encodes, among other indispensable enzymes, an aspartic protease that is essential for viral maturation and replication. Numerous inhibitors of the protease have been developed. However, the eventual resistance of HIV-1 to these drugs implies a continuous battle to develop new inhibitors. Proposed herein is a robust, fast, and reliable method employing (19)F NMR for the evaluation of the inhibitory activity of new compounds against HIV-1 protease.     

Folding mechanism of an ankyrin repeat protein: scaffold and active site formation of human CDK inhibitor p19(INK4d)

The p19(INK4d) protein consists of five ankyrin repeats (ANK) and controls the human cell cycle by inhibiting the cyclin D-dependent kinases (CDK) 4 and 6. We investigated the folding of p19(INK4d) by urea-induced unfolding transitions, kinetic analyses of unfolding and refolding, including double-mixing experiments and a special assay for folding intermediates. Folding is a sequential two-step reaction via a hyperfluorescent on-pathway intermediate. This intermediate is present under all conditions, during unfolding, refolding and at equilibrium. The folding mechanism was confirmed by a quantitative global fit of a consistent set of equilibrium and kinetic data revealing the thermodynamics and intrinsic folding rates of the different states. Surprisingly, the N<-->I transition is much faster compared to the I<-->U transition. The urea-dependence of the intrinsic folding rates causes population of the intermediate at equilibrium close to the transition midpoint. NMR detected hydrogen/deuterium exchange and the analysis of truncated variants showed that the C-terminal repeats ANK3-5 are already folded in the on-pathway intermediate, whereas the N-terminal repeats 1 and 2 are not folded. We suggest that during refolding, repeats ANK3-ANK5 first form the scaffold for the subsequent assembly of repeats ANK1 and ANK2. The binding function of p19(INK4d) resides in the latter repeats. We propose that the graded stability and the facile unfolding of repeats 1 and 2 is a prerequisite for the down-regulation of the inhibitory activity of p19(INK4d) during the cell-cycle.     

Thermal stresses in frozen organs

An analysis was performed to determine the thermal stresses in the solid region of an organ frozen so that a constant cooling rate is imposed on its outer surface. The analysis shows that at the instant the water freezes at a certain location in the organ, compressive azimuthal stresses develop in the region close to the change of phase front. The compressive asimuthal stresses decrease and become tensile at that location as the change of phase front propagates further. The radial stresses are always compressive. It is hypothesized that those stresses might induce mechanical damage to the cellular components of the organ. The analysis shows that the magnitude of these stresses is a function of the material properties and the product of the outer surface cooling rate and the square of the outer surface radius.