A new potential approach to block HIV-1 replication via protein–protein interaction and strand-transfer inhibition

Therapeutic treatment of AIDS is recently characterized by a crescent effort towards the identification of multiple ligands able to target different steps of HIV-1 life cycle. Taking into consideration our previously obtained SAR information and combining some important chemical structural features we report herein the synthesis of novel benzyl-indole derivatives as anti-HIV agents. Through this work we identified new dual target small molecules able to inhibit both IN-LEDGF/p75 interaction and the IN strand-transfer step considered as two crucial phases of viral life cycle.     

Restriction factors of retroviral replication: the example of Tripartite Motif (TRIM) protein 5α and 22

Viral tropism, replication, and pathogenesis are determined by multiple interactions between the pathogen and the host. In the case of retroviruses, and in particular, the human immunodeficiency virus, the specific interaction of the envelope protein with the host receptors and co-receptors is essential to gain entry in the cells. After entry, the success of retroviruses to complete their life cycle depends on a complex interplay between the virus and host proteins. Indeed, the cell environment is endowed with a number of factors that actively block distinct stage(s) in the microbial life cycle. Among these restriction factors, Tripartite Motif-5α (TRIM5α) has been extensively studied; however, other TRIM family members have been demonstrated to be anti-retroviral effector proteins. This article reviews, in particular, the current knowledge on the anti-retroviral effects of TRIM5α and TRIM22.     

Hydroimidazolone modification of human αA-crystallin: Effect on the chaperone function and protein refolding ability

AlphaA-crystallin is a molecular chaperone; it prevents aggregation of denaturing proteins. We have previously demonstrated that upon modification by a metabolic α-dicarbonyl compound, methylglyoxal (MGO), αA-crystallin becomes a better chaperone. AlphaA-crystallin also assists in refolding of denatured proteins. Here, we have investigated the effect of mild modification of αA-crystallin by MGO (with 20–500 µM) on the chaperone function and its ability to refold denatured proteins. Under the conditions used, mildly modified protein contained mostly hydroimidazolone modifications. The modified protein exhibited an increase in chaperone function against thermal aggregation of β_L- and γ-crystallins, citrate synthase (CS), malate dehydrogenase (MDH) and lactate dehydrogenase (LDH) and chemical aggregation of insulin. The ability of the protein to assist in refolding of chemically denatured β_L- and γ-crystallins, MDH and LDH, and to prevent thermal inactivation of CS were unchanged after mild modification by MGO. Prior binding of catalytically inactive, thermally denatured MDH or the hydrophobic probe, 2-p-toluidonaphthalene-6-sulfonate (TNS) abolished the ability of αA-crystallin to assist in the refolding of denatured MDH. However, MGO modification of chaperone-null TNS-bound αA-crystallin resulted in partial regain of the chaperone function. Taken together, these results demonstrate that: 1) hydroimidazolone modifications are sufficient to enhance the chaperone function of αA-crystallin but such modifications do not change its ability to assist in refolding of denatured proteins, 2) the sites on the αA-crystallin responsible for the chaperone function and refolding are the same in the native αA-crystallin and 3) additional hydrophobic sites exposed upon MGO modification, which are responsible for the enhanced chaperone function, do not enhance αA-crystallin's ability to refold denatured proteins.     

The contribution of surface residues to membrane binding and ligand transfer by the α-tocopherol transfer protein (α-TTP)

Previous work has shown that the α-tocopherol transfer protein (α-TTP) can bind to vesicular or immobilized phospholipid membranes. Revealing the molecular mechanisms by which α-TTP associates with membranes is thought to be critical to understanding its function and role in the secretion of tocopherol from hepatocytes into the circulation. Calculations presented in the Orientations of Proteins in Membranes database have provided a testable model for the spatial arrangement of α-TTP and other CRAL-TRIO family proteins with respect to the lipid bilayer. These calculations predicted that a hydrophobic surface mediates the interaction of α-TTP with lipid membranes. To test the validity of these predictions, we used site-directed mutagenesis and examined the substituted mutants with regard to intermembrane ligand transfer, association with lipid layers and biological activity in cultured hepatocytes. Substitution of residues in helices A8 (F165A and F169A) and A10 (I202A, V206A and M209A) decreased the rate of intermembrane ligand transfer as well as protein adsorption to phospholipid bilayers. The largest impairment was observed upon mutation of residues that are predicted to be fully immersed in the lipid bilayer in both apo (open) and holo (closed) conformations such as Phe165 and Phe169. Mutation F169A, and especially F169D, significantly impaired α-TTP-assisted secretion of α-tocopherol outside cultured hepatocytes. Mutation of selected basic residues (R192H, K211A, and K217A) had little effect on transfer rates, indicating no significant involvement of nonspecific electrostatic interactions with membranes.     

Effect of “osmotic stress” on protein and nucleic acid synthesis in isolated tobacco protoplasts

The incorporation of labeled precursors into RNAs and proteins of isolated tobacco (Nicotiana tabacum L.) leaf protoplasts decreases with increasing osmotic pressure in the incubation medium. The incorporation of precursors into RNA and proteins is linear for 15–18 h after the isolation of the protoplasts, irrespective of the osmolarity of the culture media. The uptake of precursors is also affected by the osmolarity of the medium. However, the osmotic stress-induced inhibition of incorporation of precursors into RNA and proteins is also apparent if the differences in uptake are taken into consideration in the calculation. Incorporation of ³²P into TMV-RNA is also inhibited by osmotic stress. As assayed by the double labeling ratio technique, osmotic stress has less unequivocal effect on TMV protein synthesis.Abbreviations PP protoplast - RNase ribonuclease - rRNA ribosomal ribonucleic acid - SDS sodium dodecyl sulfate - SSC 0.1 M Na-acetate in 0.15 M NaCl - TCA trichloroacetic acid - TMV tobacco mosaic virus     

Heart fatty acid binding protein and Aβ-associated Alzheimer’s neurodegeneration

Background

Epidemiological and molecular findings suggest a relationship between Alzheimer’s disease (AD) and dyslipidemia, although the nature of this association is not well understood.

Results

Using linear mixed effects models, we investigated the relationship between CSF levels of heart fatty acid binding protein (HFABP), a lipid binding protein involved with fatty acid metabolism and lipid transport, amyloid-β (Aβ), phospho-tau, and longitudinal MRI-based measures of brain atrophy among 295 non-demented and demented older individuals. Across all participants, we found a significant association of CSF HFABP with longitudinal atrophy of the entorhinal cortex and other AD-vulnerable neuroanatomic regions. However, we found that the relationship between CSF HABP and brain atrophy was significant only among those with low CSF Aβ_1–42 and occurred irrespective of phospho-tau_181p status.

Conclusions

Our findings indicate that Aβ-associated volume loss occurs in the presence of elevated HFABP irrespective of phospho-tau. This implicates a potentially important role for fatty acid binding proteins in Alzheimer’s disease neurodegeneration.

     

Rosmarinic acid prevents fibrillization and diminishes vibrational modes associated to β sheet in tau protein linked to Alzheimer’s disease

Alzheimer’s disease is a common tauopathy where fibril formation and aggregates are the hallmark of the disease. Efforts targeting amyloid-β plaques have succeeded to remove plaques but failed in clinical trials to improve cognition; thus, the current therapeutic strategy is at preventing tau aggregation. Here, we demonstrated that four phenolic diterpenoids and rosmarinic acid inhibit fibrillization. Since, rosmarinic acid was the most active compound, we observe morphological changes in atomic force microscopy images after treatment. Hence, rosmarinic acid leads to a decrease in amide regions I and III, indicating that rosmarinic acid prevents β-sheet assembly. Molecular docking study inside the steric zipper model of the hexapeptide ³⁰⁶VQIVYK³¹¹ involved in fibrillization and β sheet formation, suggests that rosmarinic acid binds to the steric zipper with similar chemical interactions with respect to those observed for orange G, a known pharmacofore for amyloid.     

Differential deuterium isotope shifts and one-bond 1H−13C scalar couplings in the conformational analysis of protein glycine residues

Summary The one-bond deuterium isotope shift effect for glycine C resonances exhibits a conformational dependence comparable to that of the corresponding ¹J_HC scalar coupling in both magnitude (11 Hz at 14.1 T) and dihedral angle dependence. The similarity in the conformational dependence of the ¹J_HC and deuterium isotope shift values suggests a common physical basis. Given the known distribution of (,) main-chain dihedral angles for glycine residues, the deuterium isotope shifts and the ¹J_HC scalar couplings can determine conformations in the left-and right-handed helical-to-bridge regions of the (,) plane to an accuracy of approximately 13°. In the absence of stereochemical assignments, the differential deuterium isotope shifts and the ¹J_HC scalar couplings can be combined with limited independent structural information (e.g., the sign of ) to determine the chirality of the deuterium substitution.     

Localization of fatty acid binding protein of epidermal type common to dendritic cells and presumptive macrophages in Peyer’s patches and epithelial M cells of mouse intestine

Fatty acid binding protein of epidermal type (E-FABP) was expressed/localized in most, if not all, populations of the dendritic cells in the subepithelial domes, follicles and interfollicular regions of Peyer’s patches and presumptive macrophages in their germinal centers, and all M cells in the follicle-associated epithelium of mouse intestine. The immunoreactivity in both of the cell populations makes it easy to recognize the accumulation of DCs in the subepithelial domes in close proximity to the base of M cells, which is essential for luminal antigens to be transported to Peyer’s patches. E-FABP may play some important roles in the mucosal immune reaction through Peyer’s patches and associated structures.     

Val 70,Phe 72 and the last seven amino acid residues of C—terminal are essential to the function of norepinephrine transporter

The norepinephrine transporter(NET) is a member of the Na^ /Cl^- dependent neurotransmitter transporter family and constitutes the target of several clinically important antidepressants.To delineate the critical amino acid residues and the function of C-terminal in regulating transport activity of NET,here we constructed two site mutants (V70F,F72V;V70I,F72V) and one C-terminal truncated mutant (Δ 611-617).The wild type and mutants of NET were expressed in Xenopus oocytes by injection of their cRNA.We found that all of these mutants lost their transport activity.These results indicate that the amino acid residues of V70 and F72,and the last seven amino acids of C-terminal are essential to the transport activity of NET.     

194 Energetics and dynamics of adenine protonation in HIV-1’s dimerization initiation site

HIV-1, like most retroviruses, packages two homologous copies of its RNA genome. The two RNA strands are non-covalently linked near their 5’ends. The proposed dimerisation initiation site is a 35-nucleotide (nt) stem loop capable of forming loop–loop interactions (a kissing dimer) via its highly conserved 6-nt loop palindrome. In a structural transformation affected by temperature, salt concentration, and by the HIV-1 nucleocapsid protein, the initial, kinetically-stable kissing dimer (KD) converts to a thermodynamically-stable extended dimer. It has been suggested that this in vitro observed rearrangement is associated with the in vivo viral genome maturation. Mihailescu et al. demonstrated enhanced rearrangement dynamics triggered by the protonation of a specific adenine residue at the genome sequence location 272 (A272) (Mihailescu, 2004). They suggested that the local environment of A272 caused its N1 atom’s pK_a to shift upwards (more basic) by approximately 2.5 pH units when compared with 5’-adenosine monophosphate (5’-AMP). In this work, we investigated the dynamics and energetics of protonating A272’s N1 atom with explicit solvent molecular dynamics (MD) simulations, Thermodynamic Integration (TI), and the Poisson–Boltzmann equation (PB). Two initial structures were used, an NMR solution structure (PDB ID: 2D19) and an X-ray crystal structure (PDB ID: 1XP7), where A272 was found inside (NMR) and outside (X-ray) the helical axis respectively. MD simulations showed when A272 started,it remained inside the KD’s axis, and when outside, it attempted to insert itself within the axis. Calculated pK_a shifts obtained from solving the PB equation were approximately?+?2.2 and?+?1.0 pH units for the NMR and X-ray structures respectively; while TI calculations performed with the NMR structure yielded a shift of approximately?+?2.5 pH units. Our simulations confirmed the strong influence of A272's local environment on its calculated pK_a when inserted in the helical axis. A272's N1 atom was approximately 200 times more likely protonated when compared with 5'-AMP. Also, protonated A272s were more energetically favoured in the kissing dimer versus an isolated monomer due to a diminished positive electrostatic potential near A272, while in the dimer. Overall, our computational investigations affirm the experimental suggestion that A272 in the kissing dimer is more likely to be protonated at physiological conditions and this protonation may trigger the structural rearrangement of the initial kissing dimer to form the extended dimer.     

Using Chou’s pseudo amino acid composition based on approximate entropy and an ensemble of AdaBoost classifiers to predict protein subnuclear location

The knowledge of subnuclear localization in eukaryotic cells is essential for understanding the life function of nucleus. Developing prediction methods and tools for proteins subnuclear localization become important research fields in protein science for special characteristics in cell nuclear. In this study, a novel approach has been proposed to predict protein subnuclear localization. Sample of protein is represented by Pseudo Amino Acid (PseAA) composition based on approximate entropy (ApEn) concept, which reflects the complexity of time series. A novel ensemble classifier is designed incorporating three AdaBoost classifiers. The base classifier algorithms in three AdaBoost are decision stumps, fuzzy K nearest neighbors classifier, and radial basis-support vector machines, respectively. Different PseAA compositions are used as input data of different AdaBoost classifier in ensemble. Genetic algorithm is used to optimize the dimension and weight factor of PseAA composition. Two datasets often used in published works are used to validate the performance of the proposed approach. The obtained results of Jackknife cross-validation test are higher and more balance than them of other methods on same datasets. The promising results indicate that the proposed approach is effective and practical. It might become a useful tool in protein subnuclear localization. The software in Matlab and supplementary materials are available freely by contacting the corresponding author.     

Differential localization of α’ and β subunits of protein kinase CK2 during rat spermatogenesis

Protein kinase CK2 is a serine/threonine kinase expressed in organisms from yeast to human and is composed of a catalytic subunit (α or α’) and a regulatory subunit (β) forming a holoenzyme with the possible subunit combinations α₂β₂, α’₂β₂, or αα’β₂. This kinase has been shown to be involved in embryonic development and gametogenesis. We have studied the expression of the CK2α’ and CK2β subunits during the first wave of spermatogenesis and in adult testis in the rat. Western blot analyses have demonstrated that both CK2α’ and CK2β are expressed in testes from birth to adulthood. A more detailed study of the protein localization of CK2α’ and CK2β by immunohistochemistry suggests that CK2α’ and CK2β are localized in the nuclei of Sertoli cells in 5-day-old rats, whereas they appear to have a cytoplasmic localization in older animals. In adult testes, CK2α’ and CK2β subunits are present in spermatocytes. Both subunits exhibit a similar expression pattern with the highest level in spermatocytes at stages VIII-XIV. Interestingly, CK2β is highly expressed in spermatogonia, whereas CK2α’ is barely detectable. Mature epididymal spermatozoa express CK2α’ in the acrosome and CK2β in the flagellum. This new evidence therefore indicates that protein kinase CK2 has a possible role at various stages during mammalian spermatogenesis, a process that involves proliferation, meiosis, apoptosis, and differentiation. CK2 might thus emerge as a new pivotal control enzyme at various levels in mammalian spermatogenesis.     

A role for the Parkinson’s disease protein DJ-1 as a chaperone and antioxidant in the anhydrobiotic nematode Panagrolaimus superbus

Mutations in the human DJ-1/PARK7 gene are associated with familial Parkinson’s disease. DJ-1 belongs to a large, functionally diverse family with homologues in all biological kingdoms. Several activities have been demonstrated for DJ-1: an antioxidant protein, a redox-regulated molecular chaperone and a modulator of multiple cellular signalling pathways. The majority of functional studies have focussed on human DJ-1 (hDJ-1), but studies on DJ-1 homologues in Drosophila melanogaster, Caenorhabditis elegans, Dugesia japonica and Escherichia coli also provide evidence of a role for DJ-1 as an antioxidant. Here, we show that dehydration is a potent inducer of a dj-1 gene in the anhydrobiotic nematode Panagrolaimus superbus. Our secondary structure and homology modelling analyses shows that recombinant DJ-1 protein from P. superbus (PsuDJ-1.1) is a well-folded protein, which is similar in structure to the hDJ-1. PsuDJ-1.1 is a heat stable protein; with T_1/2 unfolding transition values of 76 and 70 °C obtained from both circular dichroism (CD) and Fourier transform infrared spectroscopy (FTIR) measurements respectively. We found that PsuDJ-1.1 is an efficient antioxidant that also functions as a ‘holdase’ molecular chaperone that can maintain its chaperone function in a reducing environment. In addition to its chaperone activity, PsuDJ-1.1 may also be an important non-enzymatic antioxidant, capable of providing protection to P. superbus from oxidative damage when the nematodes are in a desiccated, anhydrobiotic state.

Electronic supplementary material

The online version of this article (doi:10.1007/s12192-014-0531-6) contains supplementary material, which is available to authorized users.     

Differential selection in HIV-1 gp120 between subtype B and East Asianvariant B’

HIV-1 evolves strongly and undergoes geographic differentiation as it spreads in diverse host populations around the world.For instance,distinct genomic backgrounds can be observed between the pandemic subtype B,prevalent in Europe and North-America,and its offspring clade B' in East Asia.Here we ask whether this differentiation affects the selection pressure experienced by the virus.To answer this question we evaluate selection pressure on the HIV-1 envelope protein gp120at the level of individual codons using a simple and fast estimation method based on the ratio k_alk_s of amino acid changes to synonymous changes.To validate the approach we compare results to those from a state-of-the-art mixed-effect method.The agreement is acceptable,but the analysis also demonstrates some limitations of the simpler approach.Further,we find similar distributions of codons under stabilizing and directional selection pressure in gp120 for subtypes B and B' with more directional selection pressure in variable loops and more stabilizing selection in the constant regions.Focusing on codons with increased k_alk_s values in B',we show that these codons are scattered over the whole of gp120,with remarkable clusters of higher density in regions flanking the variable loops.We identify a significant statistical association of glycosylation sites and codons with increased k_alk_s values.     

Differential Effects of Tra2? Isoforms on HIV-1 RNA Processing and Expression

Balanced processing of HIV-1 RNA is critical to virus replication and is regulated by host factors. In this report, we demonstrate that overexpression of either Tra2α or Tra2β results in a marked reduction in HIV-1 Gag/ Env expression, an effect associated with changes in HIV-1 RNA accumulation, altered viral splice site usage, and a block to export of HIV-1 genomic RNA. A natural isoform of Tra2β (Tra2ß3), lacking the N-terminal RS domain, also suppressed HIV-1 expression but had different effects on viral RNA processing. The functional differences between the Tra2β isoforms were also observed in the context of another RNA substrate indicating that these factors have distinct functions within the cell. Finally, we demonstrate that Tra2ß depletion results in a selective reduction in HIV-1 Env expression as well as an increase in multiply spliced viral RNA. Together, the findings indicate that Tra2α/β can play important roles in regulating HIV-1 RNA metabolism and expression.