Conservation of polar residues as hot spots at protein interfaces

Hu, Zhijuan; Ma, Buyong; Wolfson, Haim J.; Nussinov, Ruth

doi:10.1002/(sici)1097-0134(20000601)39:4<331::aid-prot60>3.3.co;2-1

Cited by 49 publications

(69 citation statements)

References 16 publications

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“…Incorporated into proteins, Arg is important for recognizing anionic biological entities such as phosphates (Hirsch et al 2007), glycosaminoglycans (Blaum et al 2010), and others (Chakrabarti 1994). Furthermore, Arg is responsible for the cell penetration activity of Arg-containing proteins/peptides (Wender et al 2000(Wender et al , 2008Mitchell et al 2000), and is frequently observed at protein-protein interaction interfaces and hotspots (Janin et al 1988;Argos 1988;Jones and Thornton 1995;Tsai et al 1997;Bogan and Thorn 1998;Hu et al 2000). For technological advantages, Arg derivatives have been covalently attached to carbohydrates to enhance the detection sensitivity of oligosaccharides in MALDI (matrix-assisted laser desorption ionization) mass spectrometry analysis (Zhao et al 1997;Shinohara et al 2004;Baumgart et al 2004;Nishikaze and Takayama 2006;Northern et al 2008).…”

Section: Introductionmentioning

confidence: 99%

Helix formation and capping energetics of arginine analogs with varying side chain length

et al. 2011

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Arginine (Arg) has been used for recognizing negatively charged biological molecules, cell penetration, and oligosaccharide mass signal enhancement. The versatility of Arg has inspired the need to develop Arg analogs and to research the structural effects of incorporating Arg analogs. Accordingly, we investigated the effect of Arg side chain length on helix formation by studying 12 Ala-based peptides containing the Arg analogs (S)-2-amino-6-guanidino-hexanoic acid (Agh), (S)-2-amino-4-guanidinobutyric acid (Agb), and (S)-2-amino-3-guanidinopropionic acid (Agp). Solid phase guanidinylation with orthogonal protection strategies was necessary to synthesize Agb- and Agp-containing peptides using Fmoc-based chemistry. The fraction helix for the peptides was determined by circular dichroism spectroscopy, and used to derive the statistical mechanical parameters and energetics for N-capping, C-capping, and helix propagation (propensity). All four Arg analogs were unfavorable for N-capping. The C-cap parameter followed the trend AgpAgh, highlighting the uniqueness of the Arg side chain length in helix formation. Molecular mechanics calculations and a survey on protein structures were consistent with the experimental results. Furthermore, calculations and survey both showed that the g- conformation for the χ1 dihedral was present for the first two residues at the N-terminus of helices, but not favored in the center or C-terminus of helices due to sterics. These results should serve as the foundation for developing Arg-related bioactive compounds and technologies.

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Section: Introductionmentioning

confidence: 99%

Helix formation and capping energetics of arginine analogs with varying side chain length

et al. 2011

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“…Hotspots previously identified by alanine scanning had the strictest requirements for substitution, with the wild-type amino acid being most favorable [24]. This conclusion is supported by a meta-analysis of alanine-scanning data from the literature, which concluded that evolutionarily conserved residues at interfaces are more likely to be hotspots [25].…”

Section: Hotspots At Interfacesmentioning

confidence: 78%

Protein Recognition

Mansfield

Cross

Matthews

et al. 2009

Amino Acids, Peptides and Proteins in Organic Chemistry

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Proteins function by making and breaking interactions with other molecules. The identities of these molecules cover the full spectrum of substances that one might find in an organism, illustrating the astounding structural and functional diversity that can be obtained from different combinations of roughly 20 amino acids. Thus, proteins are able to form functional interactions with partners ranging from metal ions and small diatomic molecules, such as oxygen and nitric oxide, through to typical organic molecules and macromolecules, such as nucleic acid polymers, polysaccharides, and of course other proteins. Given the enormous breadth of these interactions and the functions that they bring about, we have chosen in this chapter to focus on capturing a few of the general principles underlying protein recognition. As other chapters in this volume deal in depth with enzymes and enzyme-substrate interactions, we focus here on protein-protein and protein-DNA recognition.First, we discuss the general physicochemical nature of the interfaces made between proteins and their partners, the strength of these interactions, and methods for measuring their strength. Next, we describe two areas of protein recognition that have recently received much attention: coupled folding and binding, in which at least one of the partners in a protein interaction is disordered in the absence of its partner, and the regulation of protein interactions by post-translational modification (PTM) -a phenomenon that underlies diverse biological processes such as signaling and gene regulation. Finally, we look at progress that has been made in exploiting our understanding of protein recognition to either inhibit protein-protein interactions or to engineer new interactions for research or therapeutic purposes.

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“…In general, molecular recognition takes place as a result of a complex interplay of different noncovalent interactions established between the binding partners that, globally, need to overcome those established with the solvent in the unbound state. Nonetheless, the relative weight of each of the interacting forces might be different depending on the specific characteristics of the system (for example, electrostatic interactions seem to play a more important role in protein binding than in protein folding) [16,17]. A detailed description of the nature of noncovalent interactions and the experimental procedures available to estimate their strength and range can be found in [18][19][20].…”

Section: Intermolecular Forces In Protein Recognitionmentioning

confidence: 99%

Biophysics of Protein–Protein Interactions

Luque¹

2010

Protein Surface Recognition

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Conservation of polar residues as hot spots at protein interfaces

Cited by 49 publications

References 16 publications

Helix formation and capping energetics of arginine analogs with varying side chain length

Helix formation and capping energetics of arginine analogs with varying side chain length

Protein Recognition

Biophysics of Protein–Protein Interactions

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