Toward a high-resolution mechanism of intrinsically disordered protein self-assembly.

Membraneless organelles formed via the self-assembly of intrinsically disordered proteins (IDPs) play a crucial role in regulating various physiological functions. Elucidating the mechanisms behind IDP self-assembly is of great interest not only from a biological perspective but also for understanding how amino acid mutations in IDPs contribute to the development of neurodegenerative diseases and other disorders. Currently, two proposed mechanisms explain IDP self-assembly: (1) the sticker-and-spacer framework, which considers amino acid residues as beads to simulate the intermolecular interactions, and (2) the cross-ß hypothesis, which focuses on the ß-sheet interactions between the molecular surfaces constructed by multiple residues. This review explores the advancement of new models that provide higher resolution insights into the IDP self-assembly mechanism based on new findings obtained from structural studies of IDPs.

Importin alpha family NAAT/IBB domain: Functions of a pleiotropic long chameleon sequence.

Nuclear transport is essential for eukaryotic cell survival and regulates the movement of functional molecules in and out of the nucleus via the nuclear pore. Transport is facilitated by protein-protein interactions between cargo and transport receptors, which contribute to the expression and regulation of downstream genetic information. This chapter focuses on the molecular basis of the multifunctional nature of the importin α family, the representative transport receptors that bring proteins into the nucleus. Importin α performs multiple functions during the nuclear transport cycle through interactions with multiple molecules by a single domain called the IBB domain. This domain is a long chameleon sequence, which can change its conformation and binding mode depending on the interaction partners. By considering the evolutionarily conserved biochemical/physicochemical propensities of the amino acids constituting the functional complex interfaces, together with their structural properties, the mechanisms of switching between multiple complexes formed via IBB and the regulation of downstream functions are examined in detail. The mechanism of regulation by IBB indicates that the time has come for a paradigm shift in the way we view the molecular mechanisms by which proteins regulate downstream functions through their interactions with other molecules.

ALS mutations in the TIA-1 prion-like domain trigger highly condensed pathogenic structures.

T cell intracellular antigen-1 (TIA-1) plays a central role in stress granule (SG) formation by self-assembly via the prion-like domain (PLD). In the TIA-1 PLD, amino acid mutations associated with neurodegenerative diseases, such as amyotrophic lateral sclerosis (ALS) or Welander distal myopathy (WDM), have been identified. However, how these mutations affect PLD self-assembly properties has remained elusive. In this study, we uncovered the implicit pathogenic structures caused by the mutations. NMR analysis indicated that the dynamic structures of the PLD are synergistically determined by the physicochemical properties of amino acids in units of five residues. Molecular dynamics simulations and three-dimensional electron crystallography, together with biochemical assays, revealed that the WDM mutation E384K attenuated the sticky properties, whereas the ALS mutations P362L and A381T enhanced the self-assembly by inducing ß-sheet interactions and highly condensed assembly, respectively. These results suggest that the P362L and A381T mutations increase the likelihood of irreversible amyloid fibrillization after phase-separated droplet formation, and this process may lead to pathogenicity.

Biochemical propensity mapping for structural and functional anatomy of importin α IBB domain.

Importin α has been described as a nuclear protein transport receptor that enables proteins synthesized in the cytoplasm to translocate into the nucleus. Besides its function in nuclear transport, an increasing number of studies have examined its non-nuclear transport functions. In both nuclear transport and non-nuclear transport, a functional domain called the IBB domain (importin ß binding domain) plays a key role in regulating importin α behavior, and is a common interacting domain for multiple binding partners. However, it is not yet fully understood how the IBB domain interacts with multiple binding partners, which leads to the switching of importin α function. In this study, we have distinguished the location and propensities of amino acids important for each function of the importin α IBB domain by mapping the biochemical/physicochemical propensities of evolutionarily conserved amino acids of the IBB domain onto the structure associated with each function. We found important residues that are universally conserved for IBB functions across species and family members, in addition to those previously known, as well as residues that are presumed to be responsible for the differences in complex-forming ability among family members and for functional switching.

Importin α2 association with chromatin: Direct DNA binding via a novel DNA-binding domain.

The nuclear transport of proteins is important for facilitating appropriate nuclear functions. The importin α family proteins play key roles in nuclear transport as transport receptors for copious nuclear proteins. Additionally, these proteins possess other functions, including chromatin association and gene regulation. However, these nontransport functions of importin α are not yet fully understood, especially their molecular-level mechanisms and consequences for functioning with chromatin. Here, we report the novel molecular characteristics of importin α binding to diverse DNA sequences in chromatin. We newly identified and characterized a DNA-binding domain-the Nucleic Acid Associating Trolley pole domain (NAAT domain)-in the N-terminal region of importin α within the conventional importin ß binding (IBB) domain that is necessary for nuclear transport of cargo proteins. Furthermore, we found that the DNA binding of importin α synergistically coupled the recruitment of its cargo protein to DNA. This is the first study to delineate the interaction between importin α and chromatin DNA via the NAAT domain, indicating the bifunctionality of the importin α N-terminal region for nuclear transport and chromatin association.

Semagacestat Is a Pseudo-Inhibitor of γ-Secretase.

γ-secretase inhibitors (GSI) are drugs developed to decrease amyloid-ß peptide (Aß) production by inhibiting intramembranous cleavage of ß-amyloid protein precursor (ßAPP). However, a large phase 3 trial of semagacestat, a potential non-transition state analog (non-TSA) GSI, in patients with Alzheimer's disease (AD) was terminated due to unexpected aggravation of cognitive deficits and side effects. Here, we show that some semagacestat effects are clearly different from a phenotype caused by a loss of function of presenilins, core proteins in the γ-secretase complex. Semagacestat increases intracellular byproduct peptides, produced along with Aß through serial γ-cleavage of ßAPP, as well as intracellular long Aß species, in cell-based and in vivo studies of AD model mice. Other potential non-TSA GSIs, but not L685,458, a TSA GSI, have similar effects. Furthermore, semagacestat inhibits release of de novo intramembranous γ-byproducts to the soluble space. Thus, semagacestat is a pseudo-GSI, and therefore, the semagacestat clinical trial did not truly test the Aß hypothesis.

Transcriptome analysis of distinct mouse strains reveals kinesin light chain-1 splicing as an amyloid-ß accumulation modifier.

Alzheimer's disease (AD) is characterized by the accumulation of amyloid-ß (Aß). The genes that govern this process, however, have remained elusive. To this end, we combined distinct mouse strains with transcriptomics to directly identify disease-relevant genes. We show that AD model mice (APP-Tg) with DBA/2 genetic backgrounds have significantly lower levels of Aß accumulation compared with SJL and C57BL/6 mice. We then applied brain transcriptomics to reveal the genes in DBA/2 that suppress Aß accumulation. To avoid detecting secondarily affected genes by Aß, we used non-Tg mice in the absence of Aß pathology and selected candidate genes differently expressed in DBA/2 mice. Additional transcriptome analysis of APP-Tg mice with mixed genetic backgrounds revealed kinesin light chain-1 (Klc1) as an Aß modifier, indicating a role for intracellular trafficking in Aß accumulation. Aß levels correlated with the expression levels of Klc1 splice variant E and the genotype of Klc1 in these APP-Tg mice. In humans, the expression levels of KLC1 variant E in brain and lymphocyte were significantly higher in AD patients compared with unaffected individuals. Finally, functional analysis using neuroblastoma cells showed that overexpression or knockdown of KLC1 variant E increases or decreases the production of Aß, respectively. The identification of KLC1 variant E suggests that the dysfunction of intracellular trafficking is a causative factor of Aß pathology. This unique combination of distinct mouse strains and model mice with transcriptomics is expected to be useful for the study of genetic mechanisms of other complex diseases.

γ-secretase modulators and presenilin 1 mutants act differently on presenilin/γ-secretase function to cleave Aß42 and Aß43.

Deciphering the mechanism by which the relative Aß42(43) to total Aß ratio is regulated is central to understanding Alzheimer disease (AD) etiology; however, the mechanisms underlying changes in the Aß42(43) ratio caused by familial mutations and γ-secretase modulators (GSMs) are unclear. Here, we show in vitro and in living cells that presenilin (PS)/γ-secretase cleaves Aß42 into Aß38, and Aß43 into Aß40 or Aß38. Approximately 40% of Aß38 is derived from Aß43. Aß42(43) cleavage is involved in the regulation of the Aß42(43) ratio in living cells. GSMs increase the cleavage of PS/γ-secretase-bound Aß42 (increase k(cat)) and slow its dissociation from the enzyme (decrease k(b)), whereas PS1 mutants and inverse GSMs show the opposite effects. Therefore, we suggest a concept to describe the Aß42(43) production process and propose how GSMs act, and we suggest that a loss of PS/γ-secretase function to cleave Aß42(43) may initiate AD and might represent a therapeutic target.

The production ratios of AICDε51 and Aß42 by intramembrane proteolysis of ßAPP do not always change in parallel.

BACKGROUND: During intramembrane proteolysis of ß-amyloid protein precursor (ßAPP) by presenilin (PS)/γ-secretase, ε-cleavages at the membrane-cytoplasmic border precede γ-cleavages at the middle of the transmembrane domain. Generation ratios of Aß42, a critical molecule for Alzheimer's disease (AD) pathogenesis, and the major Aß40 species might be associated with ε48 and ε49 cleavages, respectively. Medicines to downregulate Aß42 production have been investigated by many pharmaceutical companies. Therefore, the ε-cleavages, rather than the γ-cleavage, might be more effective upstream targets for decreasing the relative generation of Aß42. Thus, one might evaluate compounds by analyzing the generation ratio of the ßAPP intracellular domain (AICD) species (ε-cleavage-derived), instead of that of Aß42. METHODS: Cell-free γ-secretase assays were carried out to observe de novo AICD production. Immunoprecipitation/MALDI-TOF MS analysis was carried out to detect the N-termini of AICD species. Aß and AICD species were measured by ELISA and immunoblotting techniques. RESULTS: Effects on the ε-cleavage by AD-associated pathological mutations around the ε-cleavage sites (i.e., ßAPP V642I, L648P and K649N) were analyzed. The V642I and L648P mutations caused an increase in the relative ratio of ε48 cleavage, as expected from previous reports. Cells expressing the K649N mutant, however, underwent a major ε-cleavage at the ε51 site. These results suggest that ε51, as well as ε48 cleavage, is associated with Aß42 production. Only AICDε51, though, and not Aß42 production, dramatically changed with modifications to the cell-free assay conditions. Interestingly, the increase in the relative ratio of the ε51 cleavage by the K649N mutation was not cancelled by these changes. CONCLUSION: Our current data show that the generation ratio of AICDε51 and Aß42 do not always change in parallel. Thus, to identify compounds that decrease the relative ratio of Aß42 generation, measurement of the relative level of Aß42-related AICD species (i.e., AICDε48 and AICDε51) might not be useful. Further studies to reveal how the ε-cleavage precision is decided are necessary before it will be possible to develop drugs targeting ε-cleavage as a means for decreasing Aß42 production.

The 28-amino acid form of an APLP1-derived Abeta-like peptide is a surrogate marker for Abeta42 production in the central nervous system.

Surrogate markers for the Alzheimer disease (AD)-associated 42-amino acid form of amyloid-beta (Abeta42) have been sought because they may aid in the diagnosis of AD and for clarification of disease pathogenesis. Here, we demonstrate that human cerebrospinal fluid (CSF) contains three APLP1-derived Abeta-like peptides (APL1beta) that are generated by beta- and gamma-cleavages at a concentration of approximately 4.5 nM. These novel peptides, APL1beta25, APL1beta27 and APL1beta28, were not deposited in AD brains. Interestingly, most gamma-secretase modulators (GSMs) and familial AD-associated presenilin1 mutants that up-regulate the relative production of Abeta42 cause a parallel increase in the production of APL1beta28 in cultured cells. Moreover, in CSF from patients with pathological mutations in presenilin1 gene, the relative APL1beta28 levels are higher than in non-AD controls, while the relative Abeta42 levels are unchanged or lower. Most strikingly, the relative APL1beta28 levels are higher in CSF from sporadic AD patients (regardless of whether they are at mild cognitive impairment or AD stage), than those of non-AD controls. Based on these results, we propose the relative level of APL1beta28 in the CSF as a candidate surrogate marker for the relative level of Abeta42 production in the brain.

Characterization of distamycin A binding to damaged DNA.

We previously reported that distamycin A, a natural antibiotic known as a minor groove binder, could bind to DNA duplexes containing the (6-4) photoproduct formed at its target site, whereas the binding was not observed for duplexes containing the cis-syn cyclobutane pyrimidine dimer in the same sequence context. In this study, we have further analyzed the binding of this drug to lesion-containing duplexes to elucidate its damaged-DNA recognition mechanism. Surface plasmon resonance measurements using various types of DNA showed that distamycin A could bind to several types of lesion-containing DNA. Curve fitting of the CD titration data revealed that the complex formation occurred with K(d) values around 10(-6) and a stoichiometry of 1:1. The results obtained in this study suggested that distamycin A binds to damaged DNA in the same way as to the normal target site, by recognizing the chemical structure of the minor groove.

Chirality of camphor derivatives by density functional theory.

Infrared (IR) and vibrational circular dichroism (VCD) spectra of chiral camphor, camphorquinone and camphor-10-sulfonic acid (CSA), known as standard compounds for electronic circular dichroism (ECD) spectroscopy, are measured and their vibrational frequencies, infrared intensities, and rotational strengths are calculated using density functional theory (DFT). The observed IR and VCD spectra of chiral camphor and camphorquinone in carbon tetrachloride solution are reproduced by the DFT calculations, but those of CSA are not. DFT calculations of hydration models, where an anionic CSA specifically binds a few water molecules, are carried out. The average of the simulated VCD spectra in the hydration models is more consistent with the observed spectra. In addition, the wavelengths and dipole and rotational strengths for chiral camphor, camphorquinone, anionic CSA, and the hydration models were calculated by time-dependent DFT. In the region of 280-300 nm, the calculated wavelengths of the ECD bands for chiral camphor and camphorquinone coincide with the observed wavelengths that have been reported, and the calculated wavelengths for the hydration models are closer to the observed wavelengths reported than are those calculated for chiral anionic CSA. Consequently, the analysis combined with VCD and ECD spectroscopy using DFT calculations can elucidate the chirality of optically active molecules, even in an aqueous solution.

Electronic and vibrational circular dichroism of aromatic amino acids by density functional theory.

Structures of model compounds mimicking aromatic amino acid residues in proteins are optimized by density functional theory (DFT), assuming that the main-chain conformation was a random coil. Excitation energies and dipole and rotational strengths for the optimized structures were calculated based on time-dependent DFT (TD-DFT). The electronic circular dichroism (ECD) bands of the models were significantly affected by side-chain conformations. Hydration models of the aromatic residues were also subjected to TD-DFT calculations, and the ECD bands of these models were found to be highly perturbed by the hydration of the main-chain amide groups. In addition to calculating the random-coil conformation, we also performed TD-DFT calculations of the aromatic residue models, assuming that the main-chain conformation was an alpha-helix or beta-strand. As expected, the overall feature of the ECD bands was also perturbed by the main-chain conformations. Moreover, vibrational circular dichroism (VCD) spectra of the hydration models in a random-coil structure were simulated by DFT, which showed that the VCD spectra are more sensitive to the side-chain conformations than the ECD spectra. The present results show that analyses combining ECD and VCD spectroscopy and using DFT calculations can elucidate the main- and side-chain conformations of aromatic residues in proteins.

Spectroscopic analyses of the binding kinetics of 15d-PGJ2 to the PPARgamma ligand-binding domain by multi-wavelength global fitting.

PPARgamma (peroxisome proliferator-activated receptor gamma) is a nuclear receptor that is activated by natural lipid metabolites, including 15d-PGJ2 (15-deoxy-Delta(12,14)-prostaglandin J2). We previously reported that several oxidized lipid metabolites covalently bind to PPARgamma through a Michael-addition to activate transcription. To separate the ligand-entering (dock) and covalent-binding (lock) steps in PPARgamma activation, we investigated the binding kinetics of 15d-PGJ2 to the PPARgamma LBD (ligand-binding domain) by stopped-flow spectroscopy. We analysed the spectral changes of 15d-PGJ2 by multi-wavelength global fitting based on a two-step chemical reaction model, in which an intermediate state represents the 15d-PGJ2-PPARgamma complex without covalent binding. The extracted spectrum of the intermediate state in wild-type PPARgamma was quite similar to the observed spectrum of 15d-PGJ2 in the C285S mutant, which cannot be activated by 15d-PGJ2, indicating that the complex remains in the inactive, intermediate state in the mutant. Thus 'lock' rather than 'dock' is one of the critical steps in PPARgamma activation by 15d-PGJ2.

Alpha,beta-unsaturated ketone is a core moiety of natural ligands for covalent binding to peroxisome proliferator-activated receptor gamma.

Peroxisome proliferator-activated receptor gamma (PPARgamma) functions in various biological processes, including macrophage and adipocyte differentiation. Several natural lipid metabolites have been shown to activate PPARgamma. Here, we report that some PPARgamma ligands, including 15-deoxy-Delta12,14-prostaglandin J2, covalently bind to a cysteine residue in the PPARgamma ligand binding pocket through a Michael addition reaction by an alpha,beta-unsaturated ketone. Using rhodamine-maleimide as well as mass spectroscopy, we showed that the binding of these ligands is covalent and irreversible. Consistently, mutation at the cysteine residue abolished abilities of these ligands to activate PPARgamma, but not of BRL49653, a non-covalent synthetic agonist, indicating that covalent binding of the alpha,beta-unsaturated ketone in the natural ligands was required for their transcriptional activities. Screening of lipid metabolites containing the alpha,beta-unsaturated ketone revealed that several other oxidized metabolites of hydroxyeicosatetraenoic acid, hydroxyeicosadecaenoic acid, and prostaglandins can also function as novel covalent ligands for PPARgamma. We propose that PPARgamma senses oxidation of fatty acids by recognizing such an alpha,beta-unsaturated ketone as a common moiety.

Rational discovery of a novel interface for a coactivator in the peroxisome proliferator-activated receptor gamma: theoretical implications of impairment in type 2 diabetes mellitus.

The peroxisome proliferator-activated receptor gamma (PPARgamma) is important to adipocyte differentiation and glucose homeostasis, and mutations in the gene have been observed in type 2 diabetes mellitus. The mutated residues, V290 and P467, bind to neither ligands nor a coactivator peptide in the reported crystal structures of the PPARgamma ligand binding domain. To understand the mechanism of type 2 diabetes mellitus caused by germline mutations in the PPARgamma ligand-binding domain, theoretical models of the PPARgamma-ligand-coactivator complex were built at an atomic resolution. In the models, the secondary coactivator peptide was docked next to the conventional coactivator peptide, which both contain the LXXLL motif. The secondary interface in PPARgamma for the secondary coactivator peptide has not been demonstrated by experiments. Binding energy calculations of the complex, considering the solvent effect, revealed that the secondary coactivator peptide, derived from nuclear receptor box 1 of steroid receptor coactivator 1, can be favorably bound to the secondary interface. The secondary coactivator peptide forms hydrogen bonds and a hydrophobic core with PPARgamma and the primary coactivator peptide. Next, we applied mutations to PPARgamma in silico and found that the V290M mutation, observed in type 2 diabetes mellitus, adversely affected the binding of the secondary peptide. Thus, our model provides structural insight into the impairment of PPARgamma function in type 2 diabetes mellitus.

Binding of distamycin A to UV-damaged DNA.

We have found that distamycin A can bind to DNA duplexes containing the (6-4) photoproduct, one of the major UV lesions in DNA, despite the changes, caused by photoproduct formation, in both the chemical structure of the base moiety and the local tertiary structure of the helix. A 20-mer duplex containing the target site, AATT.AATT, was designed, and then one of the TT sequences was changed to the (6-4) photoproduct. Distamycin binding to the photoproduct-containing duplex was detected by CD spectroscopy, whereas specific binding did not occur when the TT site was changed to a cyclobutane pyrimidine dimer, another type of UV lesion. Distamycin binding was analyzed in detail using 14-mer duplexes. Curve fitting of the CD titration data and induced CD difference spectra revealed that the binding stoichiometry changed from 1:1 to 2:1 with photoproduct formation. Melting curves of the drug-DNA complexes also supported this stoichiometry.

Domain architectures and characterization of an RNA-binding protein, TLS.

Translocated in liposarcoma (TLS) is an important protein component of the heterogeneous nuclear ribonucleoprotein complex involved in the splicing of pre-mRNA and the export of fully processed mRNA to the cytoplasm. We examined the domain organization of human TLS by a combined approach using limited proteolysis, matrix-assisted laser desorption ionization time-of-flight mass spectrometry, circular dichroism, inductively coupled plasma atomic emission spectroscopy, and NMR spectroscopy. We found that the RNA recognition motif (RRM) and zinc finger-like domains exclusively form protease-resistant core structures within the isolated TLS protein fragments, while the remaining regions, including the Arg-Gly-Gly repeats, appear to be completely unstructured. Thus, TLS contains the unstructured N-terminal half followed by the RRM and zinc finger-like domains, which are connected to each other by a flexible linker. We also carried out NMR analyses to obtain more detailed insights into the individual RRM and zinc finger-like domains. The 113Cd NMR analysis of the zinc finger-like domain verified that zinc is coordinated with four cysteines in the C4 type scheme. We also investigated the interaction of each domain with an oligo-RNA containing the GGUG sequence, which appears to be critical for the TLS function in splicing. The backbone amide NMR chemical shift perturbation analyses indicated that the zinc finger domain binds GGUG-containing RNA with a dissociation constant of about 1.0 x 10(-5) m, whereas the RRM domain showed no observable interaction with this RNA. This surprising result implies that the zinc finger domain plays a more predominant role in RNA recognition than the RRM domain.

Analysis of distamycin A binding to UV-damaged DNA.

We have found that distamycin A can bind to DNA duplexes containing the (6-4) photoproduct, one of the major UV lesions in DNA, in spite of the changes caused by photoproduct formation in the chemical structure of the base moiety and the local tertiary structure of the duplex. Distamycin binding was analyzed in detail using 14-mer duplexes. Curve fitting of the CD titration data and induced CD difference Spectra revealed that the binding stoichiometry changed from 1:1 to 2:1 with the photoproduct formation. Melting curves of the drug-DNA complexes also supported this stoichiometry.