gp120似乎促进艾滋病患者的CD4破坏

National Jewish Center for Immunology and Respiratory Medicine(Denver,CO)的 Terri Finkel 提出问题:用病毒表面蛋白 gp120制成的 HIV 疫苗实际上在加速病程发展吗?她认为,答案恐怕是肯定的。Finkel 在其最近发表的一份研究报告中指出,由 gp120或抗-gp120抗体交联的 CD_4 T 细胞可通过一种“apoptosis”机制自身破坏。一旦 T 细胞被触发,此过程即发生,因为 apoptosis 与细胞的靶抗原有关。     

Discovery of a small molecule inhibitor through interference with the gp120–CD4 interaction

A series of piperazine derivatives were designed and synthesised as gp120–CD4 inhibitors. SAR studies led to the discovery of potent inhibitors in a cell based anti viral assay represented by compounds 9 and 28. The rat pharmacokinetic and antiviral profiles of selected compounds are also presented.     

Human immunodeficiency virus protein gp120 interferes with β-adrenergic receptor-mediated protein phosphorylation in cultured rat cortical astrocytes

Summary 1. We have previously shown that acute exposure to the HIV coat protein gp120 interferes with the -adrenergic regulation of astroglial and microglial cells (Leviet al., 1993). In particular, exposure to 100 pM gp120 for 30 min depressed the phosphorylation of vimentin and glial fibrillary acidic protein (GFAP) induced by isoproterenol in rat cortical astrocyte cultures. In the present study we have extended our analysis on the effects of gp120 on astroglial protein phosphorylation.2. We found that chronic (3-day) treatment of the cells with 100 pM gp120 before exposure to isoproterenol was substantially more effective than acute treatment in depressing the stimulatory effect of the -adrenergic agonist on vimentin and GFAP phosphorylation.3. Even after chronic treatment with gp120, no differences were found in the levels and solubility of these proteins.4. Besides stimulating the phosphorylation of intermediate filament proteins, isoproterenol inhibited the incorporation of³²P into a soluble acidic protein of 80,000M _r , which was only minimally present in Triton X-100-insoluble extracts.5. Treatment of astrocytes with a phorbol ester or exposure to³H-myristic acid indicated that the acidic 80,000M _r protein is a substrate for protein kinase C (PKC) and is myristoylated, thus suggesting that it is related to the MARCKS family of PKC substrates.6. Acute (30-min) treatment with 100 pM gp120 totally prevented the inhibitory effect of isoproterenol on the phorphorylation of the 80,000M _r MARCKS-like protein.7. Our studies corroborate the hypothesis that viral components may contribute to the neuropathological changes observed in AIDS through the alteration of signal transduction systems in glial cells.     

重组艾滋病疫苗gp120

美国Genentech公司和Southwest生物医学研究基金会用黑猩猩证明利用基因重组生产的部分疫苗对艾滋病病毒有抑制效果.用于攻击试验的病毒株与作为疫苗使用的病毒同样具有相关基因.艾滋病疫苗的最大麻烦之一是不能适应抗原的变异.用黑猩猩证明利用基因工程生产的部分疫苗的有效性,还是第一例.该公司在《Nature》杂志上发表了     

Are CD4 and Fas peptide identities of gp120 relevant to the molecular basis of AIDS pathogenesis?

The release of virions from HIV-1-infected CD4 cells, although occurring readily as a result of immune activation, does not appear to be the only mechanism mediating T-cell loss in AIDS. Three other interacting HIV-1-induced immune disorders in association with viral release (the source of gp120 molecules) may also account for the constitutive T-cell depletion and functional immune suppression: 1. gp120-induced CD4(+) cell anergy, which can be reproduced in cultures of immune activated normal T-cells in the presence of gp120 or gp120 peptide containing the SLWDQ sequence identity to the CD4 molecule; 2. overproduction of IFNalpha and gamma, 3. activation-driven apoptosis of non infected T-cells. Apoptosis of T-cells could also be: 1. induced by effector components - particularly CTL and lymphotoxins produced by helper T-cells of the anti-Fas autoimmune reaction triggered by gp120 epitopes shared with the Fas/APO-1 molecule; 2. enhanced by IFN overproduction. These molecular mechanisms stress the importance in the progression to AIDS of both the viral load and HIV-induced cytokine dysregulation, including overproduction of IFNalpha, which should be considered as targets in the development of strategies for AIDS prophylaxis and immunotherapy.     

Molecular docking guided structure based design of symmetrical N,N′-disubstituted urea/thiourea as HIV-1 gp120–CD4 binding inhibitors

Induced fit molecular docking studies were performed on BMS-806 derivatives reported as small molecule inhibitors of HIV-1 gp120–CD4 binding. Comprehensive study of protein–ligand interactions guided in identification and design of novel symmetrical N,N′-disubstituted urea and thiourea as HIV-1 gp120–CD4 binding inhibitors. These molecules were synthesized in aqueous medium using microwave irradiation. Synthesized molecules were screened for their inhibitory ability by HIV-1 gp120–CD4 capture enzyme-linked immunosorbent assay (ELISA). Designed compounds were found to inhibit HIV-1 gp120–CD4 binding in micromolar (0.013–0.247 μM) concentrations.     

Comparative mapping of host–pathogen protein–protein interactions

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Phospho-tyrosine dependent protein–protein interaction network

Post-translational protein modifications, such as tyrosine phosphorylation, regulate protein–protein interactions (PPIs) critical for signal processing and cellular phenotypes. We extended an established yeast two-hybrid system employing human protein kinases for the analyses of phospho-tyrosine (pY)-dependent PPIs in a direct experimental, large-scale approach. We identified 292 mostly novel pY-dependent PPIs which showed high specificity with respect to kinases and interacting proteins and validated a large fraction in co-immunoprecipitation experiments from mammalian cells. About one-sixth of the interactions are mediated by known linear sequence binding motifs while the majority of pY-PPIs are mediated by other linear epitopes or governed by alternative recognition modes. Network analysis revealed that pY-mediated recognition events are tied to a highly connected protein module dedicated to signaling and cell growth pathways related to cancer. Using binding assays, protein complementation and phenotypic readouts to characterize the pY-dependent interactions of TSPAN2 (tetraspanin 2) and GRB2 or PIK3R3 (p55γ), we exemplarily provide evidence that the two pY-dependent PPIs dictate cellular cancer phenotypes.     

Scoring functions for protein–protein interactions

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Bispecific chimeric antigen receptors targeting the CD4 binding site and high-mannose Glycans of gp120 optimized for anti–human immunodeficiency virus potency and breadth with minimal immunogenicity

Background aims

Chimeric antigen receptors (CARs) offer great potential toward a functional cure of human immunodeficiency virus (HIV) infection. To achieve the necessary long-term virus suppression, we believe that CARs must be designed for optimal potency and anti-HIV specificity, and also for minimal probability of virus escape and CAR immunogenicity. CARs containing antibody-based motifs are problematic in the latter regard due to epitope mutation and anti-idiotypic immune responses against the variable regions.

Direct molecular fishing in molecular partners investigation in protein–protein and protein–peptide interactions

An original experimental method of direct molecular fishing has been developed for identification of potential partners of protein–protein and protein–peptide interactions. It is based on combination of surface plasmon resonance technology (SPR), size exclusion and affinity chromatography and mass spectrometric identification of proteins (LC-MS/MS). Previously, we demonstrated applicability of this method for protein interactomics using experimental model system, as well as in the pilot study in the frame of the Human Proteome Project (HPP). In the present paper, this method was successfully applied to identify possible molecular partners of 7 target proteins encoded by genes of 18 chromosome (also in the frame of the HPP). Fishing on the affinity sorbents with immobilized target proteins as ligands was carried out using total lysate of human liver tissue as well as pooled sets of fractions (individual for each bait-protein) obtained by means of a combination of size exclusion chromatography and SPR analysis for the presence of potential prey-proteins in each fraction. As a result we obtained lists of possible molecular partners of all 7 proteins and performed a comparative evaluation of direct fishing specificity for these target proteins. Direct molecular fishing was also successfully used for search of potential protein partners interacting with different isoforms of amyloid-beta peptide, playing a key role in the development of Alzheimer’s disease. The synthetic peptides that are analogues of the metal-binding domain isoforms of beta-amyloid were used as molecular baits and the fishing was performed in various fractions of immortalized human neural cells. As a result, 13 potential partner proteins were identified in the cytosol fraction of the cells by fishing on amyloid-beta peptide (1-16).     

PCS-based structure determination of protein–protein complexes

A simple and fast nuclear magnetic resonance method for docking proteins using pseudo-contact shift (PCS) and ¹H^N/¹⁵N chemical shift perturbation is presented. PCS is induced by a paramagnetic lanthanide ion that is attached to a target protein using a lanthanide binding peptide tag anchored at two points. PCS provides long-range (~40 Å) distance and angular restraints between the lanthanide ion and the observed nuclei, while the ¹H^N/¹⁵N chemical shift perturbation data provide loose contact-surface information. The usefulness of this method was demonstrated through the structure determination of the p62 PB1-PB1 complex, which forms a front-to-back 20 kDa homo-oligomer. As p62 PB1 does not intrinsically bind metal ions, the lanthanide binding peptide tag was attached to one subunit of the dimer at two anchoring points. Each monomer was treated as a rigid body and was docked based on the backbone PCS and backbone chemical shift perturbation data. Unlike NOE-based structural determination, this method only requires resonance assignments of the backbone ¹H^N/¹⁵N signals and the PCS data obtained from several sets of two-dimensional ¹⁵N-heteronuclear single quantum coherence spectra, thus facilitating rapid structure determination of the protein–protein complex.     

Structure-based method for analyzing protein–protein interfaces

Hydrogen bond, hydrophobic and vdW interactions are the three major non-covalent interactions at protein–protein interfaces. We have developed a method that uses only these properties to describe interactions between proteins, which can qualitatively estimate the individual contribution of each interfacial residue to the binding and gives the results in a graphic display way. This method has been applied to analyze alanine mutation data at protein–protein interfaces. A dataset containing 13 protein–protein complexes with 250 alanine mutations of interfacial residues has been tested. For the 75 hot-spot residues (G1.5 kcal mol^-1), 66 can be predicted correctly with a success rate of 88%. In order to test the tolerance of this method to conformational changes upon binding, we utilize a set of 26 complexes with one or both of their components available in the unbound form. The difference of key residues exported by the program is 11% between the results using complexed proteins and those from unbound ones. As this method gives the characteristics of the binding partner for a particular protein, in-depth studies on protein–protein recognition can be carried out. Furthermore, this method can be used to compare the difference between protein–protein interactions and look for correlated mutation. Figure Key interaction grids at the interface between barnase and barstar. Key interaction grid for barnase and barstar are presented in one figure according to their coordinates. In order to distinguish the two proteins, different icons were assigned. Crosses represent key grids for barstar and dots represent key grids for barnase. The four residues in ball and stick are Asp40 in barstar and Arg83, Arg87, His102 in barnase.     

Molecular glues to stabilise protein–protein interactions

Targeting protein–protein interactions (PPIs) has become a common approach to tackle various diseases whose pathobiology is driven by their mis-regulation in important signalling pathways. Modulating PPIs has tremendous untapped therapeutic potential and different approaches can be used to modulate PPIs. Initially, therapeutic effects were mostly sought by inhibiting PPIs. However, by gaining insight in the mode of action of certain therapeutic compounds, it became clear that stabilising (i.e. enhancing) PPIs can also be useful. The latter strategy is recently gaining a lot of attention, as stabilising physiologic, or even inducing novel interactions of a target protein with E3 ubiquitin ligases forms the basis of the targeted protein degradation (TPD) approach. An emerging additional example for drug discovery based on PPI stabilisation are the 14-3-3 proteins, a family of regulatory proteins, which engages in many protein–protein interactions, some of which might become therapeutical targets.     

Predicting protein–protein interactions from protein sequences using meta predictor

A novel method is proposed for predicting protein–protein interactions (PPIs) based on the meta approach, which predicts PPIs using support vector machine that combines results by six independent state-of-the-art predictors. Significant improvement in prediction performance is observed, when performed on Saccharomyces cerevisiae and Helicobacter pylori datasets. In addition, we used the final prediction model trained on the PPIs dataset of S. cerevisiae to predict interactions in other species. The results reveal that our meta model is also capable of performing cross-species predictions. The source code and the datasets are available at     

Accuracy modulating mutations of the ribosomal protein S4-S5 interface do not necessarily destabilize the rps4-rps5 protein–protein interaction

During the process of translation, an aminoacyl tRNA is selected in the A site of the decoding center of the small subunit based on the correct codon–anticodon base pairing. Though selection is usually accurate, mutations in the ribosomal RNA and proteins and the presence of some antibiotics like streptomycin alter translational accuracy. Recent crystallographic structures of the ribosome suggest that cognate tRNAs induce a “closed conformation” of the small subunit that stabilizes the codon–anticodon interactions at the A site. During formation of the closed conformation, the protein interface between rpS4 and rpS5 is broken while new contacts form with rpS12. Mutations in rpS12 confer streptomycin resistance or dependence and show a hyperaccurate phenotype. Mutations reversing streptomycin dependence affect rpS4 and rpS5. The canonical rpS4 and rpS5 streptomycin independent mutations increase translational errors and were called ribosomal ambiguity mutations (ram). The mutations in these proteins are proposed to affect formation of the closed complex by breaking the rpS4-rpS5 interface, which reduces the cost of domain closure and thus increases translational errors. We used a yeast two-hybrid system to study the interactions between the small subunit ribosomal proteins rpS4 and rpS5 and to test the effect of ram mutations on the stability of the interface. We found no correlation between ram phenotype and disruption of the interface.