Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0021051 (immunodeficiency)
 71,517 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A search for highly amphiphilic alpha-helices has been made in a data base of protein sequences, using the helical hydrophobic moment as a criterion of amphiphilicity. The protein segments of largest hydrophobic moment have been analyzed. For the segments whose structures are known, they are in fact alpha-helices. Two of the segments having very large hydrophobic moments are from the smaller C-terminal portion of the human immunodeficiency virus (HIV) envelope glycoprotein gp41. Also, among segments having large hydrophobic moments, but not among the most extreme, are lytic peptides such as melittin. Melittin seeks surfaces between polar and apolar phases, including the membrane-water interface. It is conceivable that the gp41 segments of extreme hydrophobic moment may participate in one of the membrane-related functions of the HIV virus.
Biopolymers 1990 Jan
PMID:The most highly amphiphilic alpha-helices include two amino acid segments in human immunodeficiency virus glycoprotein 41. 232 85

A dynamical model for an N-terminal fragment of the human CD4 protein has been determined by computer simulation. The protein has been studied both in vacuo and in solution. Data from both simulations agree moderately well with each other and with the crystal structure. All elements of secondary structure were retained during simulation. Point mutation and sequence replacement studies have shown that a loop in CD4, residues 40-52 is involved in binding with gp120, the human immunodeficiency virus surface glycoprotein. Our results show that the gp120-binding loop and a few regions which bind to monoclonal antibodies and class II MHC molecules are the most highly motile areas of the protein. These results are consistent with the suggestion that CD4 binds to target molecules by using induced-fit contacts.
Biopolymers 1994 Sep
PMID:Molecular dynamics studies of the human CD4 protein. 794 28

We have used the molecular dynamics (MD) simulation package AMBER4 to search the conformation of a peptide predicted as a leucine zipper motif for the human immunodeficiency virus type 1 integrase protein (HIV IN-LZM). The peptide is composed of 22 amino acid residues and its location is from Val 151 to Leu 172. The searching procedure also includes two known alpha-helices that served as positive controls--namely, a 22-residue GCN4-p1 (LZM) and a 20-residue poly (L-alanine) (PLA). A 21-residue peptide extracted from a cytochrome C crystal (CCC-t) with determined conformation as a beta-turn is also included as a negative control. At the beginning of the search, two starting conformations--namely, the standard right-handed alpha-helix and the fully stretched conformations--are generated for each peptide. Structures generated as standard alpha-helix are equilibrated at room temperature for 90 ps while structures generated as a fully stretched one are equilibrated at 600 K for 120 ps. The CCC-t and PLA helices are nearly destroyed from the beginning of equilibration. However, for both the HIV IN-LZM and the GCN4-p1 LZM structures, there is substantial helicity being retained throughout the entire course of equilibration. Although helix propagation profiles calculated indicate that both peptides possess about the same propensity to form an alpha-helix, the HIV IN-LZM helix appears to be more stable than the GCN4-p1 one as judged by a variety of analyses on both structures generated during the equilibration course. The fact that predicted HIV IN-LZM can exist as an alpha-helix is also supported by the results of high temperature equilibration run on the fully stretched structures generated. In this run, the RMS deviations between the backbone atoms of the structures with the lowest potential energy (PE) identified within every 2 ps and the structure with the lowest PE searched in the same course of simulation are calculated. For both the HIV IN-LZM and the GCN4-p1 LZM, these rms values decrease with the decrease of PE, which indicates that both structures are closer in conformations as their PEs are moved deeper into the PE well.
Biopolymers 1994 Aug
PMID:Molecular dynamics simulation of a leucine zipper motif predicted for the integrase of human immunodeficiency virus type 1. 807 85

A mathematical frame has been established to generally formulate the correlating properties of peptides. The formulation can be used to study the specificity of multisite enzymes, particularly in predicting the susceptible sites in proteins by human immunodeficiency virus (HIV) proteases, and hence can serve as a supplementary means in designing HIV protease inhibitors as potential drugs against acquired immunodeficiency syndrome.
Biopolymers 1993 Sep
PMID:A formulation for correlating properties of peptides and its application to predicting human immunodeficiency virus protease-cleavable sites in proteins. 840 33

The human immunodeficiency (HIV) codes for an aspartic protease known to be essential for retroviral maturation and replication. The HIV protease can recognize Phe-Pro and Tyr-Pro sequences as the virus-specific cleavage site. These features provided a basis for the rational design of selective HIV protease-targeted drugs for the treatment of acquired immunodeficiency syndrome (AIDS). HIV protease is formed from two identical 99 amino acid peptides. We replaced the two Cys residues by L-Ala to synthesize [Ala67,95]-HIV-1 protease by the solid phase method and then prepared [Tyr6,42, Nle36,46, (NHCH2COSCH2CO)51-52, Ala67,95] HIV-1 protease (NY-5 isolate) using the thioester chemical ligation method. Based on the substrate transition state, we designed and synthesized a novel class of HIV protease inhibitors containing an unnatural amino acid, (2S, 3S)-3-amino-2-hydroxy-4-phenylbutyric acid, named allophenylnorstatine (Apns) with a hydroxymethylcarbonyl (HMC) isostere. Among them, the conformationally constrained tripeptide kynostatin (KNI)-272 (iQoa-Mta-Apns-Thz-NHBut) was a highly selective and superpotent HIV protease inhibitor (Ki = 0.0055 nM). KNI-272 exhibited potent antiviral activities against both AZT-sensitive and -insensitive clinical HIV-1 isolates as well as HIV-2 with low cytotoxicity. After i.d. administration, bioavailability of KNI-272 was 42.3% in rats. Also, KNI-272 exhibited in vivo anti-HIV activities in human PBMC-SCID mice. The x-ray crystallography and molecular modeling studies showed that the HMC group in KNI-272 interacted excellently with the aspartic acid carboxyl groups of HIV protease active site in the essentially same hydrogen-bonding mode as the transition state. This result implies that the HMC isostere is an ideal transition-state mimic and contributes to the high activity of KNI-272.
Biopolymers 1996
PMID:Design and synthesis of substrate-based peptidomimetic human immunodeficiency virus protease inhibitors containing the hydroxymethylcarbonyl isostere. 878 65

CD and nmr characterizations are reported for the 23-mer peptide CMC3, corresponding to residues 577-599 of gp41, the transmembrane glycoprotein of the human immunodeficiency virus 1. Concentration, temperature, and pH dependencies of CD and nmr spectra are indicative of self-association with a consequent stabilization of secondary structural elements in water. The addition to the water solution of small amounts of trifluoroethanol induces a secondary structure, mostly due to the presence of helical elements. The amphipathic character of the helix and the presence of three hydrophobic 4/3 heptad repeats suggest that the peptide could be structured in a symmetric association of helices, such as in a coiled-coil structure. This behavior is discussed in terms of a possible role of this segment in the gp41 envelope oligomerization.
Biopolymers 1996 Mar
PMID:NMR and CD studies on the conformation of a synthetic peptide containing epitopes of the human immunodeficiency virus 1 transmembrane protein gp41. 890 76

The nucleocapsid protein NCp7, which is the major genomic RNA binding protein of human immunodeficiency virus type 1, plays an important role in several key steps of the viral life cycle. Many of the NCp7 activities, notably the nucleic acid annealing and the genomic RNA wrapping ones, are thought to be linked to a nonspecific binding of NCp7 to its nucleic acid targets. The mechanism of these activities is still debated but several clues are in favor of an intermediate aggregation of nucleic acids by NCp7. To check and characterize the nucleic acid aggregating properties of NCp7, we investigated the interaction of NCp7 with the model RNA homopolymer, polyA, by quasielastic light scattering and optical density measurements. The ordered growth of monodisperse large particles independently of the nucleic acid size and the almost complete covering of polyA by NCp7 strongly suggested an ordered aggregation mechanism. The aggregate kinetics of growth in the optimum protein concentration range (> or = 2 microM) were governed by a so-called Ostwald ripening mechanism limited by transfer of NCp7-covered polyA complexes from small to large aggregates. The aggregation process was strongly dependent on both Na+ and Mg2+ concentrations, the optimum concentrations being in the physiological range. Similar conclusions held true when polyA was replaced by 16S + 23S ribosomal RNA, suggesting that the NCp7 aggregating properties were only poorly dependent on the nucleic acid sequence and structure. Finally, as in the NCp7 annealing activities, the basic regions of NCp7, but not the zinc fingers, were found critical in nucleic acid aggregation. Taken together, our data indicate that NCp7 is a highly efficient nucleic acid aggregating agent and strengthen the hypothesis that aggregation may constitute a transient step in various NCp7 functions.
Biopolymers 1997 Mar
PMID:Ordered aggregation of ribonucleic acids by the human immunodeficiency virus type 1 nucleocapsid protein. 905 95

The conformation of the DNA and the interactions of the nucleic acid with the protein in a complex of human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) and 19-mer/18-mer double-stranded DNA template-primer (dsDNA) are described. The structure of this HIV-1 RT complex with dsDNA serves as a useful paradigm for studying aspects of nucleotide polymerases such as catalysis, fidelity, drug inhibition, and drug resistance. The bound dsDNA has a bend of approximately 41 degrees at the junction of an A-form region (first five base pairs near the polymerase active site) and a B-form region (the last nine base pairs toward the RNase H active site). The 41 degrees bend occurs smoothly over the four base pairs between the A-form portion and the B-form portion in the vicinity of helices alpha H and alpha I of the p66 thumb subdomain. The interactions between the dsDNA and protein primarily involve the sugar-phosphate backbone of the nucleic acid and structural elements of the palm, thumb, and RNase H of p66, and are not sequence specific. Amino acid residues from the polymerase active site region, including amino acid residues of the conserved Tyr-Met-Asp-Asp (YMDD) motif and the "primer grip," interact with 3'-terminal nucleotides of the primer strand and are involved in positioning the primer terminal nucleotide and its 3'-OH group at the polymerase active site. Amino acid residues of the "template grip" have close contacts with the template strand and aid in positioning the template strand near the polymerase active site. Helix alpha H of the p66 thumb is partly inserted into the minor groove of the dsDNA and helix alpha I is directly adjacent to the backbone of the template strand. Amino acid residues of beta 1', alpha A', alpha B', and the loop containing His539 of the RNase H domain interact with the primer strand of the dsDNA.
Biopolymers 1997
PMID:Protein-nucleic acid interactions and DNA conformation in a complex of human immunodeficiency virus type 1 reverse transcriptase with a double-stranded DNA template-primer. 935 57

NCp7, the nucleocapsid protein of the human immunodeficiency virus type 1, induces an ordered aggregation of RNAs, a mechanism that is thought to be involved in the NCp7-induced promotion of nucleic acid annealing. To further investigate this aggregation the morphology and the properties of the NCp7-induced aggregates of the model RNA homoribopolymer, polyA, were investigated by electron microscopy in various conditions. In almost all the tested conditions, the aggregates were spherical and consisted of a central dense core surrounded by a less dense halo made of NCp7-covered polyA molecules. The formation of these aggregates with a narrow distribution of sizes constitutes a distinctive feature of NCp7 over other single-stranded nucleic acid binding proteins. In most conditions, at the shortest times that can be reached experimentally, all the polyA molecules were already incorporated in small aggregates, suggesting that the nucleation step and the first aggregation events took place rapidly. The aggregates then orderly grew with time by fusion of the smaller aggregates to give larger ones. The aggregate halo was important in the fusion process by initiating the bridging between the colliding aggregates. In the presence of an excess of protein, the aggregates grew rapidly but were loosely packed and dissociated easily, suggesting adverse protein-protein interactions in the aggregates obtained in these conditions. In the presence of an excess of nucleotides, the presence of both amorphous nonspherical and slowly growing spherical aggregates suggested some changes in the mechanism of aggregate growth due to an incomplete covering of polyA molecules by NCp7. Finally, we showed that in the absence of added salt, the aggregate fusions were unfavored but not the initial events giving the first aggregates, the reverse being true in the presence of high salt concentrations (> or = 300 mM).
Biopolymers 1998 Mar
PMID:Properties and growth mechanism of the ordered aggregation of a model RNA by the HIV-1 nucleocapsid protein: an electron microscopy investigation. 946 85

A ubiquitious class of RNA-binding proteins is distinguished by an arginine-rich motif. Such proteins function in transcription, translation, RNA trafficking, and packaging. Peptide models are derived from viral regulatory proteins, including the virulence factors Tat and Rev of mammalian immunodeficiency viruses. Structures of model peptide-RNA complexes exhibit diverse strategies of recognition based in each case on structural transitions. Induced RNA structures contain noncanonical elements such as purine-purine mismatches, base triples, and flipped bases. Such elements enlarge and extend the RNA major groove to create specific peptide-binding pockets and surfaces. The repertoire of bound peptide structures--beta-hairpin, alpha-helix, and helix-bend-helix-reflects the diversity of induced RNA architectures. This repertoire, reminiscent of primordial exon-encoded peptides, may recapitulate early events in the transition between RNA and protein worlds. Peptide-directed changes in modern RNA structures can provide a mechanism of signaling in higher-order RNA-protein assemblies.
Biopolymers 1998
PMID:RNA recognition by arginine-rich peptide motifs. 1033 44


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