Folding propensity of intrinsically disordered proteins by osmotic stress.

Proteins imparted with intrinsic disorder conduct a range of essential cellular functions. To better understand the folding and hydration properties of intrinsically disordered proteins (IDPs), we used osmotic stress to induce conformational changes in nuclear co-activator binding domain (NCBD) and activator for thyroid hormone and retinoid receptor (ACTR) separate from their mutual binding. Osmotic stress was applied by the addition of small and polymeric osmolytes, where we discovered that water contributions to NCBD folding always exceeded those for ACTR.

Discovery of an inhibitor of Z-alpha1 antitrypsin polymerization.

Polymerization of the Z variant alpha-1-antitrypsin (Z-α1AT) results in the most common and severe form of α1AT deficiency (α1ATD), a debilitating genetic disorder whose clinical manifestations range from asymptomatic to fatal liver and/or lung disease. As the altered conformation of Z-α1AT and its attendant aggregation are responsible for pathogenesis, the polymerization process per se has become a major target for the development of therapeutics. Based on the ability of Z-α1AT to aggregate by recruiting the reactive center loop (RCL) of another Z-α1AT into its s4A cavity, we developed a high-throughput screening assay that uses a modified 6-mer peptide mimicking the RCL to screen for inhibitors of Z-α1AT polymer growth.

Investigating the structural impact of the glutamine repeat in huntingtin assembly.

Acquiring detailed structural information about the various aggregation states of the huntingtin-exon1 protein (Htt-exon1) is crucial not only for identifying the true nature of the neurotoxic species responsible for Huntington's disease (HD) but also for designing effective therapeutics. Using time-resolved small-angle neutron scattering (TR-SANS), we followed the conformational changes that occurred during fibrillization of the pathologic form of Htt-exon1 (NtQ42P10) and compared the results with those obtained for the wild-type (NtQ22P10). Our results show that the aggregation pathway of NtQ22P10 is very different from that of NtQ42P10, as the initial steps require a monomer to 7-mer transition stage.

Structural formation of huntingtin exon 1 aggregates probed by small-angle neutron scattering.

In several neurodegenerative disorders, including Huntington's disease, aspects concerning the earliest of protein structures that form along the aggregation pathway have increasingly gained attention because these particular species are likely to be neurotoxic. We used time-resolved small-angle neutron scattering to probe in solution these transient structures formed by peptides having the N-terminal sequence context of mutant huntingtin exon 1. We obtained snapshots of the formed aggregates as the kinetic reaction ensued to yield quantitative information on their size and mass.

Imaging polyglutamine deposits in brain tissue.

The formation of polyglutamine aggregates occupies a central role in the pathophysiology of neurodegenerative diseases caused by expanded trinucleotide repeats encoding the amino acid glutamine. This chapter describes sensitive histological methods for detection of tissue sites that are capable of further recruitment of polyglutamine and for sites rich in polyglutamine defined immunohistochemically. These methods have been found to be applicable in a number of diseases and animal models of disease.

Screening for modulators of aggregation with a microplate elongation assay.

Many protein misfolding or conformational diseases, a number of which are neurodegenerative, are associated with the presence of proteinaceous deposits in the form of amyloid/amyloid-like fibrils/aggregates in tissues. Little is known about the exact mechanisms by which fibrillar aggregates are formed and can impair cellular functions leading to cell death. Small molecules that can modulate aggregate formation and/or structure can be powerful tools for studying the aggregate assembly mechanism and toxicity and may also prove to be therapeutic.

Structural properties of Abeta protofibrils stabilized by a small molecule.

Metastable oligomeric and protofibrillar forms of amyloidogenic proteins have been implicated as on-pathway assembly intermediates in amyloid formation and as the major toxic species in a number of amyloid diseases including Alzheimer's disease. We describe here a chemical biology approach to structural analysis of Abeta protofibrils. Library screening yielded several molecules that stimulate Abeta aggregation.

Amyloid-like features of polyglutamine aggregates and their assembly kinetics.

The repeat length-dependent tendency of the polyglutamine sequences of certain proteins to form aggregates may underlie the cytotoxicity of these sequences in expanded CAG repeat diseases such as Huntington's disease. We report here a number of features of various polyglutamine (polyGln) aggregates and their assembly pathways that bear a resemblance to generally recognized defining features of amyloid fibrils. PolyGln aggregation kinetics displays concentration and length dependence and a lag phase that can be abbreviated by seeding.

A microtiter plate assay for polyglutamine aggregate extension.

Polyglutamine (polyGln) aggregates are neuropathological markers of expanded CAG repeat disorders, and may also play a critical role in the development of these diseases. We have established a highly sensitive, fast, reproducible, and specific assay capable of monitoring aggregate-dependent deposition of polyglutamine peptides. This assay allows detailed studies on various aspects of aggregation kinetics, and also makes possible the detection and quantitation of low levels of "extension-competent" aggregates.

Polyglutamine aggregation behavior in vitro supports a recruitment mechanism of cytotoxicity.

In expanded CAG repeat diseases such as Huntington's disease, proteins containing polyglutamine (poly(Gln)) sequences with repeat lengths of about 37 residues or more are associated with development of both disease symptoms and neuronal intranuclear inclusions (NIIs). Disease physiology in animal and cellular models does not always correlate with NII formation, however, and the mechanism by which aggregate formation might lead to cytotoxicity is unknown. To help evaluate various possible mechanisms, we determined the biophysical properties of a series of simple poly(Gln) peptides.

Probing ligand-induced conformational changes of human CD38.

The lymphoid surface antigen CD38 is basically a NAD+glycohydrolase, which is also involved in the metabolism of cyclic ADP-ribose. Besides, this ecto-enzyme has potential signalling roles in T- and B-cells. Such multiple functions prompted us to study the molecular dynamics of the CD38 protein and especially the relationship between its ecto-enzymatic active site and its epitope, i.

Human CD38 is an authentic NAD(P)+ glycohydrolase.

The leucoyte surface antigen CD38 has been shown to be an ecto-enzyme with multiple catalytic activities. It is principally a NAD+ glycohydrolase that transforms NAD+ into ADP-ribose and nicotinamide. CD38 is also able to produce small amounts of cyclic ADP-ribose (ADP-ribosyl cyclase activity) and to hydrolyse this cyclic metabolite into ADP-ribose (cyclic ADP-ribose hydrolase activity).

Coordinated regulation in human T cells of nucleotide-hydrolyzing ecto-enzymatic activities, including CD38 and PC-1. Possible role in the recycling of nicotinamide adenine dinucleotide metabolites.

The human leukocyte surface Ag CD38 was recently identified as a nicotinamide adenine dinucleotide (NAD)(+)-glycohydrolase ecto-enzyme, degrading NAD into nicotinamide and ADP-ribose. We show here that expression of CD38 is increased in the Jurkat T cell line after treatment with agents that augment intracellular cAMP, with the permeant cAMP analogue dibutyryl-cAMP (db-cAMP), and also with PMA, which activates protein kinase C. Treatment of human PBL T cells with db-cAMP or submitogenic doses of PMA also increased CD38 expression.

Distortion after monofunctional alkylation by mitomycin C of a dodecamer containing its major binding site.

The structural distortions of the duplex dodecamer d(ATTAACGTTAAT)2 monofunctionally alkylated by mitomycin C have been studied by the use of chemical probes reactivity and resonance Raman spectroscopy. This sequence contains the 5'-ACGT sequence for which mitomycin C was determined to present the best affinity (S. Kumar, R.