Role of Cholesterol and Its Immediate Biosynthetic Precursors in Membrane Dynamics and Heterogeneity: Implications for Health and Disease.

Cholesterol is an indispensible component of cellular membranes in higher eukaryotes and plays a vital role in many cellular functions. 7-Dehydrocholesterol (7-DHC) and desmosterol represent two immediate biosynthetic precursors of cholesterol in the Kandutsch-Russell and Bloch pathways of cholesterol biosynthesis, respectively. Although 7-DHC and desmosterol differ from cholesterol merely by a double bond, accumulation of these two immediate biosynthetic precursors due to defective cholesterol biosynthesis leads to severe developmental and neurological disorders. In this context, we explored the role of cholesterol and its immediate biosynthetic precursors (7-DHC and desmosterol) on the dynamics and heterogeneity of fluid phase POPC (1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine) and gel phase DPPC (1,2-dipalmitoyl-sn-glycero-3-phosphocholine) membranes, using fluorescence lifetime distribution analysis of Nile Red (9-diethylamino-5H-benzo[α]phenoxazine-5-one) using the maximum entropy method (MEM). We show here that the membrane interfacial dynamic heterogeneity, manifested as the width of the fluorescence lifetime distribution of Nile Red, exhibited by 7-DHC and desmosterol vastly differ from that displayed by cholesterol, particularly in fluid phase membranes. We conclude that a subtle alteration in sterol structure could considerably alter dynamic membrane heterogeneity, which could have implications in pathogenicity associated with defective cholesterol biosynthesis.

p53 amyloid formation leading to its loss of function: implications in cancer pathogenesis.

The transcriptional regulator p53 has an essential role in tumor suppression. Almost 50% of human cancers are associated with the loss of p53 functions, where p53 often accumulates in the nucleus as well as in cytoplasm. Although it has been previously suggested that amyloid formation could be a cause of p53 loss-of-function in subset of tumors, the characterization of these amyloids and its structure-function relationship is not yet established. In the current study, we provide several evidences for the presence of p53 amyloid formation (in human and animal cancer tissues); along with its isolation from human cancer tissues and the biophysical characterization of these tissue-derived fibrils. Using amyloid seed of p53 fragment (P8, p53(250-257)), we show that p53 amyloid formation in cells not only leads to its functional inactivation but also transforms it into an oncoprotein. The in vitro studies further show that cancer-associated mutation destabilizes the fold of p53 core domain and also accelerates the aggregation and amyloid formation by this protein. Furthermore, we also show evidence of prion-like cell-to-cell transmission of different p53 amyloid species including full-length p53, which is induced by internalized P8 fibrils. The present study suggests that p53 amyloid formation could be one of the possible cause of p53 loss of function and therefore, inhibiting p53 amyloidogenesis could restore p53 tumor suppressor functions.

Arginase of Helicobacter Gastric Pathogens Uses a Unique Set of Non-catalytic Residues for Catalysis.

Helicobacter pylori arginase, a bimetallic enzyme, is crucial for pathogenesis of the bacterium in human stomach. Despite conservation of the signature motifs in all arginases, the H. pylori homolog has a non-conserved motif (153ESEEKAWQKLCSL165), whose role was recently shown to be critical for its stability and function. The sequence analysis also reveals the presence of this motif with critical residues in the homolog of other Helicobacter gastric pathogens. However, the underlying mechanism for its significance in catalytic function is not clearly understood. Using H. pylori arginase, our studies reveal that the interactions of His122 and Tyr125 with Trp159 are indispensable for tertiary structural intactness through optimal positioning of the motif and thus for the catalytic function. The single and double mutants of His122 and Tyr125 not only enhanced the solvent accessibility and conformational flexibility of Trp159 in the holo protein, but also showed complete loss of catalytic activity. An intact bimetallic center and unaltered substrate binding indicate that proper positioning of the motif by aromatic-aromatic contact is vital for the generation of a catalytically active conformation. Additionally, the metal ions provide higher stability to the holo protein. We also identified the presence of these two residues exclusively in arginase of other Helicobacter gastric pathogens, which may have similar function. Therefore, to the best of our knowledge, these findings highlight for the first time that arginase of all Helicobacter gastric pathogens utilizes a unique non-catalytic triad for catalysis, which could be exploited for therapeutics.

Depth-Dependent Membrane Ordering by Hemagglutinin Fusion Peptide Promotes Fusion.

Membrane fusion, one of the most fundamental processes in life, occurs when two separate lipid membranes merge into a single continuous bilayer. Membrane fusion is essential for the entry of lipid-sheathed viruses such as influenza and HIV. Influenza virus is internalized via receptor-mediated endocytosis and then fuses with the endosomal membrane at low pH. Hemagglutinin, a glycoprotein found on the surface of influenza virus, is responsible for the fusion of the viral sheath with the endosomal membrane. The ∼20 amino acid long N-terminus of hemagglutinin, known as the fusion peptide, plays a crucial role in the viral fusion process. Although there exists vast literature on the importance and role of the fusion peptide in promoting membrane fusion, there is no consensus on the mechanism by which it promotes fusion. A recent report suggested that the fusion peptide occupies and orders space in the outer leaflets of contacting bilayers so as to promote acyl chain protrusion into interbilayer space and promote fusion "stalk" formation. We report here the effect of the wild type, G1S, G1V, and W14A mutants of hemagglutinin fusion peptide on depth-dependent ordering of model membranes along the bilayer normal. We utilized fluorescence anisotropy, lifetime measurements, and lifetime distribution analyses of different anthroyloxy stearic acid probes (n-AS) in order to examine the effect of fusion peptides at various depths along the bilayer normal. Wild type peptide uniquely ordered a region ∼12 Šfrom the bilayer midpoint, W14A and G1S mutants mainly ordered the bilayer interface, while G1V had little ordering influence. On the basis of recent analysis of the effects of these peptides on fusion, ordering of the mid-upper region of the bilayer appears to promote fusion pore formation, while ordering of the bilayer interface inhibits it.

Depth-Dependent Organization and Dynamics of Archaeal and Eukaryotic Membranes: Development of Membrane Anisotropy Gradient with Natural Evolution.

The lipid composition of archaea is unique and has been correlated with increased stability under extreme environmental conditions. In this article, we have focused on the evolution of membrane organization and dynamics with natural evolution. Dynamic anisotropy along the membrane normal (i.e., gradients of mobility, polarity, and heterogeneity) is a hallmark of fluid phase diester or diether phospholipid membranes. We monitored gradients of mobility, polarity, and heterogeneity along the membrane normal in membranes made of a representative archaeal lipid using a series of membrane depth-dependent fluorescent probes, and compared them to membranes prepared from a typical diether lipid from higher organisms (eukaryotes). Our results show that the representative dynamic anisotropy gradient along the membrane normal is absent in membranes made from archaeal lipids. We hypothesize that the dynamic gradient observed in membranes of diester and diether phospholipids is a consequence of natural evolution of membrane lipids in response to the requirement of carrying out complex cellular functions by membrane proteins.

Familial Parkinson disease-associated mutations alter the site-specific microenvironment and dynamics of α-synuclein.

Human α-synuclein (α-Syn) is a natively unstructured protein whose aggregation into amyloid fibrils is associated with Parkinson disease (PD) pathogenesis. Mutations of α-Syn, E46K, A53T, and A30P, have been linked to the familial form of PD. In vitro aggregation studies suggest that increased propensity to form non-fibrillar oligomers is the shared property of these familial PD-associated mutants. However, the structural basis of the altered aggregation propensities of these PD-associated mutants is not yet clear. To understand this, we studied the site-specific structural dynamics of wild type (WT) α-Syn and its three PD mutants (A53T, E46K, and A30P). Tryptophan (Trp) was substituted at the N terminus, central hydrophobic region, and C terminus of all α-Syns. Using various biophysical techniques including time-resolved fluorescence studies, we show that irrespective of similar secondary structure and early oligomerization propensities, familial PD-associated mutations alter the site-specific microenvironment, solvent exposure, and conformational flexibility of the protein. Our results further show that the common structural feature of the three PD-associated mutants is more compact and rigid sites at their N and C termini compared with WT α-Syn that may facilitate the formation of a partially folded intermediate that eventually leads to their increased oligomerization propensities.

Elucidating the role of disulfide bond on amyloid formation and fibril reversibility of somatostatin-14: relevance to its storage and secretion.

The storage of protein/peptide hormones within subcellular compartments and subsequent release are crucial for their native function, and hence these processes are intricately regulated in mammalian systems. Several peptide hormones were recently suggested to be stored as amyloids within endocrine secretory granules. This leads to an apparent paradox where storage requires formation of aggregates, and their function requires a supply of non-aggregated peptides on demand. The precise mechanism behind amyloid formation by these hormones and their subsequent release remain an open question. To address this, we examined aggregation and fibril reversibility of a cyclic peptide hormone somatostatin (SST)-14 using various techniques. After proving that SST gets stored as amyloid in vivo, we investigated the role of native structure in modulating its conformational dynamics and self-association by disrupting the disulfide bridge (Cys(3)-Cys(14)) in SST. Using two-dimensional NMR, we resolved the initial structure of somatostatin-14 leading to aggregation and further probed its conformational dynamics in silico. The perturbation in native structure (S-S cleavage) led to a significant increase in conformational flexibility and resulted in rapid amyloid formation. The fibrils formed by disulfide-reduced noncyclic SST possess greater resistance to denaturing conditions with decreased monomer releasing potency. MD simulations reveal marked differences in the intermolecular interactions in SST and noncyclic SST providing plausible explanation for differential aggregation and fibril reversibility observed experimentally in these structural variants. Our findings thus emphasize that subtle changes in the native structure of peptide hormone(s) could alter its conformational dynamics and amyloid formation, which might have significant implications on their reversible storage and secretion.

A folding transition underlies the emergence of membrane affinity in amyloid-ß.

Small amyloid-ß (Aß) oligomers have much higher membrane affinity compared to the monomers, but the structural origin of this functional change is not understood. We show that as monomers assemble into small n-mers (n < 10), Aß acquires a tertiary fold that is consistent with the mature fibrils. This is an early and defining transition for the aggregating peptide, and possibly underpins its altered bioactivity.

Organization and dynamics of the N-terminal domain of chemokine receptor CXCR1 in reverse micelles: effect of graded hydration.

Water plays a fundamental role in the folding, structure, dynamics, and function of proteins and peptides. The extracellular N-terminal domain of chemokine receptors is crucial in mediating binding affinity, receptor selectivity, and regulating function. The flexible N-terminal domain becomes ordered in membranes and membrane-mimetic assemblies, thereby indicating that the membrane could play an important role in regulating CXC chemokine receptor 1 (CXCR1) function. In view of the role of hydration in lipid-protein interactions in membranes, we explored the organization and dynamics of a 34-mer peptide of the CXCR1 N-terminal domain in reverse micelles by utilizing a combination of fluorescence-based approaches and circular dichroism spectroscopy. Our results show that the secondary structure adopted by the CXCR1 N-domain is critically dependent on hydration. The tryptophan residues of the CXCR1 N-domain experience motional restriction and exhibit red edge excitation shift (REES) upon incorporation in reverse micelles. REES and fluorescence lifetime exhibit reduction with increasing reverse micellar hydration. Time-resolved fluorescence anisotropy measurements reveal the effect of hydration on peptide rotational dynamics. Taken together, these results constitute the first report demonstrating modulation in the organization and dynamics of the N-terminal domain of a chemokine receptor in a membrane-like environment of varying hydration. We envisage that these results are relevant in the context of hydration in the function of G protein-coupled receptors.

Membrane organization and dynamics of "inner pair" and "outer pair" tryptophan residues in gramicidin channels.

The linear ion channel peptide gramicidin serves as an excellent prototype for monitoring the organization, dynamics, and function of membrane-spanning channels. The tryptophan residues in gramicidin channels are crucial for establishing and maintaining the structure and function of the channel in the membrane bilayer. In order to address the basis of differential importance of tryptophan residues in the gramicidin channel, we monitored the effects of pairwise substitution of two of the four gramicidin tryptophans, the inner pair (Trp-9 and -11) and the outer pair (Trp-13 and -15), using a combination of steady state and time-resolved fluorescence approaches and circular dichroism spectroscopy. We show here that these double tryptophan gramicidin analogues adopt different conformations in membranes, suggesting that the conformational preference of double tryptophan gramicidin analogues is dictated by the positions of the tryptophans in the sequence. These results assume significance in the context of recent observations that the inner pair of tryptophans (Trp-9 and -11) is more important for gramicidin channel formation and channel conductance. These results could be potentially useful in analyzing the effect of tryptophan substitution on the functioning of ion channels and membrane proteins.

Depth-Dependent Heterogeneity in Membranes by Fluorescence Lifetime Distribution Analysis.

Biological membranes display considerable anisotropy due to differences in composition, physical characteristics, and packing of membrane components. In this Letter, we have demonstrated the environmental heterogeneity along the bilayer normal in a depth-dependent manner using a number of anthroyloxy fatty acid probes. We employed fluorescence lifetime distribution analysis utilizing the maximum entropy method (MEM) to assess heterogeneity. Our results show that the fluorescence lifetime heterogeneity varies considerably depending on fluorophore location along the membrane normal (depth), and it is the result of the anisotropic environmental heterogeneity along the bilayer normal. Environmental heterogeneity is reduced as the reporter group is moved from the membrane interface to a deeper hydrocarbon region. To the best of our knowledge, our results constitute the first experimental demonstration of anisotropic heterogeneity in bilayers. We conclude that such graded environmental heterogeneity represents an intrinsic characteristics of the membrane bilayer and envisage that it has a role in the conformation and orientation of membrane proteins and their function.

Oligomerization of the serotonin(1A) receptor in live cells: a time-resolved fluorescence anisotropy approach.

The serotonin(1A) receptor is a representative member of the G-protein coupled receptor (GPCR) superfamily and serves as an important target in the development of therapeutic agents for neuropsychiatric disorders. Oligomerization of GPCRs is an important contemporary issue since it is believed to be a crucial determinant for cellular signaling. In this work, we monitored the oligomerization status of the serotonin(1A) receptor tagged to enhanced yellow fluorescent protein (5-HT(1A)R-EYFP) in live cells utilizing time-resolved fluorescence anisotropy decay. We interpret the unresolved fast component of the observed anisotropy decay as fluorescence resonance energy transfer (FRET) between 5-HT(1A)R-EYFP molecules (homo-FRET). Homo-FRET enjoys certain advantages over hetero-FRET in the analysis of receptor oligomerization. Our results reveal the presence of constitutive oligomers of the serotonin(1A) receptor in live cells. We further show that the oligomerization status of the receptor is independent of ligand stimulation and sphingolipid depletion. Interestingly, acute (but not chronic) cholesterol depletion appears to enhance the oligomerization process. Importantly, our results are independent of receptor expression level, thereby ruling out complications arising due to high expression. These results have potential implications in future therapeutic strategies in pathophysiological conditions in which serotonin(1A) receptors are implicated.

Nature of the amyloid-beta monomer and the monomer-oligomer equilibrium.

The monomer to oligomer transition initiates the aggregation and pathogenic transformation of Alzheimer amyloid-ß (Aß) peptide. However, the monomeric state of this aggregation-prone peptide has remained beyond the reach of most experimental techniques, and a quantitative understanding of this transition is yet to emerge. Here, we employ single-molecule level fluorescence tools to characterize the monomeric state and the monomer-oligomer transition at physiological concentrations in buffers mimicking the cerebrospinal fluid (CSF). Our measurements show that the monomer has a hydrodynamic radius of 0.9 ± 0.1 nm, which confirms the prediction made by some of the in silico studies. Surprisingly, at equilibrium, both Aß(40) and Aß(42) remain predominantly monomeric up to 3 µm, above which it forms large aggregates. This concentration is much higher than the estimated concentrations in the CSF of either normal or diseased brains. If Aß oligomers are present in the CSF and are the key agents in Alzheimer pathology, as is generally believed, then these must be released in the CSF as preformed entities. Although the oligomers are thermodynamically unstable, we find that a large kinetic barrier, which is mostly entropic in origin, strongly impedes their dissociation. Thermodynamic principles therefore allow the development of a pharmacological agent that can catalytically convert metastable oligomers into nontoxic monomers.

Monitoring membrane protein conformational heterogeneity by fluorescence lifetime distribution analysis using the maximum entropy method.

Due to the inherent difficulty in crystallizing membrane proteins, approaches based on fluorescence spectroscopy have proved useful in elucidating their conformational characteristics. The ion channel peptide gramicidin serves as an excellent prototype for monitoring membrane protein conformation and dynamics due to a number of reasons. We have analyzed conformational heterogeneity in membrane-bound gramicidin using fluorescence lifetime distribution analysis of tryptophan residues by the maximum entropy method (MEM). MEM represents a model-free and robust approach for analyzing fluorescence lifetime distribution. In this paper, we show for the first time, that fluorescence lifetime distribution analysis using MEM could be a convenient approach to monitor conformational heterogeneity in membrane-bound gramicidin in particular and membrane proteins in general. Lifetime distribution analysis by MEM therefore provides a novel window to monitor conformational transitions in membrane proteins.

Fluorescence characterization of the structural heterogeneity of polytene chromosomes.

Studies on the physical nature of the structural heterogeneity of chromatin in their native states are few. The eukaryotic chromatin as observed by dye staining studies is of heterogeneous intensity when observed by fluorescent stains, where less and more bright regions apparently correspond to euchromatin and heterochromatin respectively. These are also associated with differential gene expression where it is believed that euchromatin is transcriptionally more active due to increased flexibility. Unfixed squashed preparations of polytene chromosomes of Drosophila were stained with a dsDNA specific dye PicoGreen and fluorescence lifetimes as well as fluorescence anisotropy decay kinetics were measured. Here we report a positive correlation between fluorescence lifetimes and fluorescence intensities, and show that less bright regions corresponding to euchromatin have shorter lifetimes, whereas more bright regions corresponding to heterochromatin have longer lifetimes. We interpret this as less bright regions being more dynamic, a conclusion also supported by fluorescence anisotropy decay kinetics. We infer that the comparatively higher flexibility associated with euchromatin can be directly measured by fluorescence lifetimes and fluorescence anisotropy decay kinetics.

Site-specific dynamics in TAT triplex DNA as revealed by time-domain fluorescence of 2-aminopurine.

Triple helices of DNA are finding increasing level of applications in several areas, including antigene therapy and gene regulation. We have probed site-specific dynamic aspects of TAT triple helices of DNA by using steady-state and time-domain fluorescence of 2-aminopurine (2-AP), a fluorescent analog of adenine. TAT triplexes were formed from repeats of adenine and thymine with 2-AP incorporated at various locations in the polyadenine strand. We find an overall decrease in the level of near-neighbor base-stacking interaction in the TAT triplex when compared to AT duplex as reported by fluorescence decay kinetics of 2-AP. More strikingly, we have observed a stark asymmetry in both the level of base stacking and motional dynamics of the bases in the two ends of TAT triplexes, namely, the 5' end having a higher level of base stacking and segmental dynamics when compared to the 3' end. The possible implications of this asymmetry, which reflects the asymmetry in the strength of Hoogstein base-pairing with the 3' end having stronger Hoogstein pairing when compared to the 5' end, is discussed.

Enhanced DNA dynamics due to cationic reagents, topological states of dsDNA and high mobility group box 1 as probed by PicoGreen.

We report a study of dynamics with a dsDNA-specific dye called PicoGreen bound to plasmid DNA (3.4 kb), and show that at low dye/DNA phosphate ratios (1 : 100 and below), PicoGreen dynamics reflect the motional dynamics of dsDNA. We further evaluated the usefulness of this probe by measuring the time-resolved fluorescence dynamics of PicoGreen bound to dsDNA in the presence of cationic reagents that affect DNA dynamics [MgCl2 and polyethyleneimine (PEI)] and also with plasmid DNA in different topological states. Among these conditions, MgCl2, PEI and the supercoiled form of plasmid resulted in increases in the very short component (0.2-0.4 ns) of the rotational correlation time. Separately, HMGB1 protein enhanced DNA dynamics, as observed from the rotational correlation times of very short (0.2-0.4 ns) and short (2-4 ns) rotational correlation timescale components. By studying the effect of specific deletion mutants HMGB1-DeltaA (deletion of 98 N-terminal amino acids) and HMGB1-DeltaC (deletion of 30 C-terminal amino acids), we show that the acidic C-terminal tail is required for enhancement of DNA dynamics. We then discuss the possible mechanisms and implications of HMGB1-mediated flexibility of DNA in the context of formation of large nucleoprotein complexes.

Dynamics and heterogeneity of bovine hippocampal membranes: role of cholesterol and proteins.

The structural and dynamic consequence of alterations in membrane lipid composition (specifically cholesterol) in neuronal membranes is poorly understood. Previous work from our laboratory has established bovine hippocampal membranes as a convenient natural source for studying neuronal receptors. In this paper, we have explored the role of cholesterol and proteins in the dynamics and heterogeneity of bovine hippocampal membranes using fluorescence lifetime distribution analysis of the environment-sensitive fluorescent probe Nile Red incorporated into such membranes by the maximum entropy method (MEM), and time-resolved fluorescence anisotropy measurements. The peak position and the width of the lifetime distribution of Nile Red show a progressive reduction with increasing cholesterol depletion from native hippocampal membranes indicating that the extent of heterogeneity decreases with decrease in membrane cholesterol content. This is accompanied by a concomitant decrease of the fluorescence anisotropy and rotational correlation time. Our results point out that the microenvironment experienced by Nile Red is relatively insensitive to the presence of proteins in hippocampal membranes. Interestingly, Nile Red lifetime distribution in liposomes of lipid extracts is similar to that of native membranes indicating that proteins do not contribute significantly to the high level of heterogeneity observed in native membranes. These results could be relevant in understanding the neuronal diseases characterized by defective membrane lipid metabolism.

Fluorescence dynamics of DNA condensed by the molecular crowding agent poly(ethylene glycol).

Condensation of extended DNA into compact structures is encountered in a variety of situations, both natural and artificial. While condensation of DNA has been routinely carried out by the use of multivalent cations, cationic lipids, detergents, and polyvalent cationic polymers, the use of molecular crowding agents in condensing DNA is rather striking. In this work, we have studied the dynamics of plasmid DNA condensed in the presence of a molecular crowding agent, polyethylene glycol (PEG). Steady-state and time-resolved fluorescence of the recently established condensation-indicating DNA binder, YOYO-1 [G. Krishnamoorthy, G. Duportail, and Y. Mely (2002), Biochemistry 41, 15277-15287] was used in inferring the dynamic aspects of DNA condensates. It is shown that DNA condensed by PEG is more flexible and less compact when compared to DNA condensed by binding agents such as polyethyleneimine. The relevance of such differences in dynamics toward functional aspects of condensed DNA is discussed.