Structural Model for the Cooperative Assembly of HIV-1 Rev Multimers on the RRE as Deduced from Analysis of Assembly-Defective Mutants

Jain, Chaitanya; Belasco, Joel G.

doi:10.1016/s1097-2765(01)00207-6

Cited by 96 publications

(207 citation statements)

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“…Biochemical fractionation studies showed that p13 is indeed inserted as integral membrane protein in the inner mitochondrial membrane (see below; [6]). The high flexibility score of the PPTSSRP motif (residues [42][43][44][45][46][47][48] suggests that this might represent a hinge region. The C-terminal region (residues 65-75) is predicted to fold as a b-sheet structure.…”

Section: Amino Acid Sequence and Structural Features Of Htlv-1 P13mentioning

confidence: 99%

Effects of human T‐cell leukemia virus type 1 (HTLV‐1) p13 on mitochondrial K⁺ permeability: A new member of the viroporin family?

et al. 2010

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a b s t r a c tHuman T-cell leukemia virus type-1 (HTLV-1) encodes a mitochondrial protein named p13. p13 mediates an inward K + current in isolated mitochondria that leads to mitochondrial swelling, depolarization, increased respiratory chain activity and reactive oxygen species (ROS) production. These effects trigger the opening of the permeability transition pore and are dependent on the presence of K + and on the amphipathic alpha helical domain of p13. In the context of cells, p13 acts as a sensitizer to selected apoptotic stimuli. Although it is not known whether p13 influences the activity of endogenous K + channels or forms a channel itself, it shares some structural and functional analogies with viroporins, a class of small integral membrane proteins that form pores and alter membrane permeability.

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Section: Amino Acid Sequence and Structural Features Of Htlv-1 P13mentioning

confidence: 99%

Effects of human T‐cell leukemia virus type 1 (HTLV‐1) p13 on mitochondrial K⁺ permeability: A new member of the viroporin family?

et al. 2010

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“…Rev binds to an elaborate RNA structure, the Rev-response element (RRE), and promotes nuclear export of RRE-containing mRNAs that encode gag/pol and env (Pollard & Malim, 1998). Regions required for RNA binding, trans-activation and multimerization have been mapped within Rev (Daly et al, 1989;Malim & Cullen, 1991;Malim et al, 1989 Malim et al, , 1990Olsen et al, 1990;Pollard & Malim, 1998), but the precise features that determine the specificity and stability of the Rev-multimerization process have yet to be defined fully.An elegant genetic selection was used to identify Rev mutants with deficiencies in the Rev multimeric-assembly pathway (Jain & Belasco, 2001). Three classes of multimerization defect were resolved.…”

mentioning

confidence: 99%

“…Amino acid residues 11-32 of the amino-terminal helix constitute multimerization domain I (MD-I), whereas aa 52-67, which constitute multimerization domain II (MD-II), are part of a second, longer helical region that also includes the Rev RNA-binding domain. The helical regions of MD-I and -II are held together through hydrophobic interactions and amino acid residues comprising the dimerization and trimerization interfaces map to opposite, solvent-exposed sides of the antiparallel helices (Jain & Belasco, 2001). …”

mentioning

confidence: 99%

“…The helical regions of MD-I and -II are held together through hydrophobic interactions and amino acid residues comprising the dimerization and trimerization interfaces map to opposite, solvent-exposed sides of the antiparallel helices (Jain & Belasco, 2001). The genetic screen used to resolve Rev-multimerization defects was based on Rev-dependent translational repression of a target RNA in bacteria (Jain & Belasco, 2001). To date, the phenotype of Rev trimerization-interface mutants has not been examined in a mammalian cell system capable of recapitulating Rev-dependent gene expression.…”

mentioning

confidence: 99%

“…An elegant genetic selection was used to identify Rev mutants with deficiencies in the Rev multimeric-assembly pathway (Jain & Belasco, 2001). Three classes of multimerization defect were resolved.…”

mentioning

confidence: 99%

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Phenotypic analysis of human immunodeficiency virus type 1 Rev trimerization-interface mutants in human cells

Trikha

Brighty

2005

Journal of General Virology

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Nuclear export of unspliced and incompletely spliced human immunodeficiency virus type 1 mRNA is mediated by the viral Rev protein. Rev binds to a structured RNA motif known as the Rev-response element (RRE), which is present in all Rev-dependent transcripts, and thereby promotes entry of the ribonucleoprotein complex into the nuclear-export pathway. Recent evidence indicates that a dimerization interface and a genetically separable 'trimerization' interface are required for multimeric assembly of Rev on the RRE. In this report, the effect of mutations within the trimerization interface on Rev function was examined in mammalian cells. All trimerization-defective Rev molecules had profoundly compromised Rev function and a range of localization defects was observed. However, despite the potential for formation of heterodimers between functional and non-functional Rev proteins, trimerization-defective Rev mutants were unable to inhibit wild-type Rev function in a trans-dominant-negative manner.The human immunodeficiency virus (HIV) rev gene product is a prototypic example of a class of functionally diverse, arginine-rich, sequence-specific RNA-binding proteins. Rev binds to an elaborate RNA structure, the Rev-response element (RRE), and promotes nuclear export of RRE-containing mRNAs that encode gag/pol and env (Pollard & Malim, 1998). Regions required for RNA binding, trans-activation and multimerization have been mapped within Rev (Daly et al., 1989;Malim & Cullen, 1991;Malim et al., 1989 Malim et al., , 1990Olsen et al., 1990;Pollard & Malim, 1998), but the precise features that determine the specificity and stability of the Rev-multimerization process have yet to be defined fully.An elegant genetic selection was used to identify Rev mutants with deficiencies in the Rev multimeric-assembly pathway (Jain & Belasco, 2001). Three classes of multimerization defect were resolved. Class one Rev mutants bind to the RRE as monomers, but are defective in their ability to form dimers; consequently, these mutants do not form multimers readily on the RRE. Moreover, class three mutants exhibit defects at all stages of RRE binding and Rev dimerization and multimerization and are probably structurally defective. In contrast, and perhaps most interestingly, class two mutants are competent for dimerization and RNA binding, but show greatly reduced multimerization properties. Thus, Jain & Belasco (2001) were able to genetically separate the process of dimerization from the subsequent process of multimeric Rev assembly. The refined molecular model (Jain & Belasco, 2001) suggests that there are two Rev-interaction surfaces; one surface is required for Rev-Rev dimerization, whereas the second is required for trimerization and higher-order assembly (Fig. 1a).Considerable evidence suggests that the amino-terminal half of Rev adopts a helix-loop-helix motif (Hope et al., 1990;Jain & Belasco, 2001;Madore et al., 1994;Pollard & Malim, 1998;Thomas et al., 1998;Zapp et al., 1991). Amino acid residues 11-32 of the amino-terminal helix cons...

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Stabilization of an α Helix by β‐Sheet‐Mediated Self‐Assembly of a Macrocyclic Peptide

2009

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The a helix is an essential secondary structural motif in proteins. In particular, a helices at the outer surface of proteins play an important role in specific biomolecular recognition events, such as in protein-DNA, protein-RNA, and protein-protein interactions. [1] The a-helical structures are well stabilized in the context of intact proteins. However, an a-helix-forming segment, when isolated from the protein as a short peptide, is rarely helical in solution owing to its inherent thermodynamic instability. [2] Because the stabilization of active folded forms of peptide is important for maintaining the unique functions of protein, extensive research into stabilized a-helical peptides has been carried out. [3] Peptide helix stabilization approaches include the covalent cross-linking of amino acids located at the same face of an a helix, [3a,b] hydrogen-bond surrogates, [2a] metal coordination, [3c] salt bridge formation, [3d] helix nucleation, [3e] helix capping, [3f] and synthetic a-helix receptors. [3g] These minimalist approaches have advantages with regard to simplicity and cost efficiency. However, when considering many a-helix-mediated interactions occurring in a multivalent fashion, [4] the inherent limitation of such monomeric ahelix approaches is that the complex and multivalent biological interactions cannot be effectively targeted.Herein, we describe a simple but effective supramolecular approach in which multiple a-helix-coated artificial proteins can be constructed by the self-assembly of simple peptides. Bottom-up self-assembly of functional supramolecular building blocks is a cost-efficient way of constructing bioactive multivalent structures. [5] To substantiate this goal, a building block was designed in such a way that both an a-helical peptide segment and a self-assembling segment are located within a single macrocyclic structure (peptide 4, Figure 1 a). As the self-assembling segment, a b-sheet peptide with predictable and well-known self-assembly behavior was selected. The a-helix-forming segment is an alanine-based peptide. Lysines are located within the stretch of alanines to increase water solubility and to prevent aggregation. [6] The bsheet peptide segment is a repeat of hydrophobic and of positively or negatively charged amino acids. Such combination of amino acids promotes b-sheet hydrogen bonding and subsequent self-assembly into bilayered ribbon-like fibrous nanostructures. [7] Oligoethylene glycol-based linker segments are placed between the a-helical-and b-sheet-forming sequences to decouple both segments. The peptide macrocycle was designed based on the hypotheses that 1) a cyclic structure will partially stabilize the helical structure by decreasing conformational entropy of the unfolded state, [8] and 2) a self-assembly-induced coil-to-rod transition in the bsheet segment will further constrain and stabilize the helical structure (Figure 1 b). The cyclization reaction was performed while protected peptide was still bound to the resin to achieve a pseudo-dilution ...

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Structural Model for the Cooperative Assembly of HIV-1 Rev Multimers on the RRE as Deduced from Analysis of Assembly-Defective Mutants

Cited by 96 publications

References 33 publications

Effects of human T‐cell leukemia virus type 1 (HTLV‐1) p13 on mitochondrial K⁺ permeability: A new member of the viroporin family?

Effects of human T‐cell leukemia virus type 1 (HTLV‐1) p13 on mitochondrial K⁺ permeability: A new member of the viroporin family?

Phenotypic analysis of human immunodeficiency virus type 1 Rev trimerization-interface mutants in human cells

Stabilization of an α Helix by β‐Sheet‐Mediated Self‐Assembly of a Macrocyclic Peptide

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Structural Model for the Cooperative Assembly of HIV-1 Rev Multimers on the RRE as Deduced from Analysis of Assembly-Defective Mutants

Cited by 96 publications

References 33 publications

Effects of human T‐cell leukemia virus type 1 (HTLV‐1) p13 on mitochondrial K+ permeability: A new member of the viroporin family?

Effects of human T‐cell leukemia virus type 1 (HTLV‐1) p13 on mitochondrial K+ permeability: A new member of the viroporin family?

Phenotypic analysis of human immunodeficiency virus type 1 Rev trimerization-interface mutants in human cells

Stabilization of an α Helix by β‐Sheet‐Mediated Self‐Assembly of a Macrocyclic Peptide

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Product

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Effects of human T‐cell leukemia virus type 1 (HTLV‐1) p13 on mitochondrial K⁺ permeability: A new member of the viroporin family?

Effects of human T‐cell leukemia virus type 1 (HTLV‐1) p13 on mitochondrial K⁺ permeability: A new member of the viroporin family?