Coiled coils have attracted considerable interest as design templates in a wide range of applications. Successful coiled-coil design strategies therefore require a detailed understanding of coiled-coil folding. One common feature shared by coiled coils is the presence of a short autonomous helical folding unit, termed ''trigger sequence,'' that is indispensable for folding. Detailed knowledge of trigger sequences at the molecular level is thus key to a general understanding of coiled-coil formation. Using a multidisciplinary approach, we identify and characterize here the molecular determinants that specify the helical conformation of the monomeric early folding intermediate of the GCN4 coiled coil. We demonstrate that a network of hydrogen-bonding and electrostatic interactions stabilize the trigger-sequence helix. This network is rearranged in the final dimeric coiled-coil structure, and its destabilization significantly slows down GCN4 leucine zipper folding. Our findings provide a general explanation for the molecular mechanism of coiled-coil formation.autonomous folding unit ͉ protein folding ͉ trigger sequence ͉ leucine zipper ͉ ␣-helix A lthough coiled coils have been used traditionally as model systems for protein folding studies, the molecular basis of how they fold is still largely unknown. A need for a detailed understanding of coiled-coil folding is relevant, particularly in light of the important functions these structures play in almost all biological processes, as well as the considerable attention coiled coils have recently garnered in a wide range of applications, including basic research, nanomaterials, protein engineering, biotechnology, and medicine (1-13). Furthermore, understanding the folding mechanisms of coiled coils is of fundamental interest to experimentalists and theoreticians challenged by the question of how the sequence of a protein defines its specific 3D structure. Along these lines, we have been interested particularly in coiled-coil ''trigger sequences,'' which encode stable monomeric ␣-helices that are indispensable for coiled-coil formation (14-18). Although there are a few examples of synthetic peptides that fold either into heterodimers (19) or at conditions of extremes of pH (20) without an apparent trigger sequence, the ''trigger site'' concept is generally accepted because these short autonomous helical folding units are structurally and functionally conserved in a large number of native coiled-coil proteins (reviewed in refs. 21-24). Detailed knowledge of the properties of trigger sequences at the molecular level is therefore key to an understanding of coiled-coil formation and function in general.The parallel two-stranded leucine zipper of the yeast transcriptional activator GCN4 is the best-characterized coiled coil and thus represents an excellent paradigm for a comprehensive analysis of the roles of trigger sequences in coiled-coil folding. Our current understanding of the folding kinetics of the GCN4 leucine zipper is based on extensive stopped-flow studies and te...
We used PET with the tracers [18F]fluorodeoxyglucose (FDG), [18F]fluorodopa (FDOPA) and [11C]raclopride (RACLO) to study striatal glucose and dopa metabolism, and dopamine D2 receptor binding, respectively, in nine patients with multiple system atrophy. Ten patients with classical Parkinson's disease were investigated with the same three PET tracers' and three separate groups, each of 10 healthy subjects, served as control populations. We found that striatal FDOPA values separated all healthy subjects from patients with parkinsonism but they were not useful in distinguishing multiple system atrophy from Parkinson's disease. Conversely, striatal RACLO as well as FDG values discriminated all multiple system atrophy from Parkinson's disease patients as well as from healthy control subjects. Metabolic and receptor binding decrements in the putamen of multiple system atrophy patients were significantly correlated. Stepwise regression analysis revealed that a linear combination of putamen RACLO and FDOPA values accurately predicted clinical measures of disease severity in the multiple system atrophy group. Our findings suggest that striatal FDG and particularly RACLO are sensitive and effective measures of striatal function and may help characterizing patients with multiple system atrophy. In contrast, FDOPA measurements are accurate in detecting abnormalities of the nigrostriatal dopaminergic system but may not distinguish among different forms of parkinsonism.
The primary sensorimotor cortex of the adult brain is capable of significant reorganization of topographic maps after deafferentation and de-efferentation. Here we show that patients with spinal cord injury exhibit extensive changes in the activation of cortical and subcortical brain areas during hand movements, irrespective of normal (paraplegic) or impaired (tetraplegic patients) hand function. Positron emission tomography ([15O]-H2O-PET) revealed not only an expansion of the cortical 'hand area' towards the cortical 'leg area', but also an enhanced bilateral activation of the thalamus and cerebellum. The areas of the brain which were activated were qualitatively the same in both paraplegic and tetraplegic patients, but differed quantitatively as a function of the level of their spinal cord injury. We postulate that the changes in brain activation following spinal cord injury may reflect an adaptation of hand movement to a new body reference scheme secondary to a reduced and altered spino-thalamic and spino-cerebellar input.
With the purpose of studying neural activation associated with reward processing in humans, we measured regional cerebral blood flow in 10 right-handed healthy subjects performing a delayed go-no go task in two different reinforcement conditions. Correct responses were either rewarded by money or a simple "ok' reinforcer. Behaviour rewarded by money, as compared with the "ok' reinforcement, was most significantly associated with activation of dorsolateral and orbital frontal cortex and also involved the midbrain and thalamus. These results may reflect the processing of reward information, although arousal effects cannot be completely excluded. It is suggested that the observed foci are implicated in the assessment of consequences in goal-directed behaviour which agrees with research in non-human primates.
Our results show that FDOPA, RACLO, and FDG PET measurements provide complementary information to characterize metabolic and receptor changes in the striatum of PD with different degrees of motor disability. The FDOPA uptake reflects the best motor-related pathologic features, as indicated by the significant correlation between Ki values and clinical scores. The significant association between RACLO and FDOPA in the putamen suggests that D2 dopamine receptor changes are related to the reduction of presynaptic dopaminergic nerve terminals. Putamen FDG increase is probably the result of more complex feedback mechanisms that are primarily induced by striatal dopamine deficiency.
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