Asparagine and glutamine differ in their propensities to form specific side chain-backbone hydrogen bonded motifs in proteins
Prema G. Vasudev
Molecular Biophysics Unit, Indian Institute of Science, Bangalore 560012, India
Search for more papers by this authorMousumi Banerjee
Molecular Biophysics Unit, Indian Institute of Science, Bangalore 560012, India
Search for more papers by this authorC. Ramakrishnan
Molecular Biophysics Unit, Indian Institute of Science, Bangalore 560012, India
Search for more papers by this authorCorresponding Author
P. Balaram
Molecular Biophysics Unit, Indian Institute of Science, Bangalore 560012, India
Molecular Biophysics Unit, Indian Institute of Science, Bangalore 560012, India===Search for more papers by this authorPrema G. Vasudev
Molecular Biophysics Unit, Indian Institute of Science, Bangalore 560012, India
Search for more papers by this authorMousumi Banerjee
Molecular Biophysics Unit, Indian Institute of Science, Bangalore 560012, India
Search for more papers by this authorC. Ramakrishnan
Molecular Biophysics Unit, Indian Institute of Science, Bangalore 560012, India
Search for more papers by this authorCorresponding Author
P. Balaram
Molecular Biophysics Unit, Indian Institute of Science, Bangalore 560012, India
Molecular Biophysics Unit, Indian Institute of Science, Bangalore 560012, India===Search for more papers by this authorAbstract
Short range side chain-backbone hydrogen bonded motifs involving Asn and Gln residues have been identified from a data set of 1370 protein crystal structures (resolution ≤ 1.5 Å). Hydrogen bonds involving residues i − 5 to i + 5 have been considered. Out of 12,901 Asn residues, 3403 residues (26.4%) participate in such interactions, while out of 10,934 Gln residues, 1780 Gln residues (16.3%) are involved in these motifs. Hydrogen bonded ring sizes (Cn, where n is the number of atoms involved), directionality and internal torsion angles are used to classify motifs. The occurrence of the various motifs in the contexts of protein structure is illustrated. Distinct differences are established between the nature of motifs formed by Asn and Gln residues. For Asn, the most highly populated motifs are the C10 (COδi …NHi + 2), C13 (COδi …NHi + 3) and C17 (NδHi …COi − 4) structures. In contrast, Gln predominantly forms C16 (COεi …NHi − 3), C12 (NεHi …COi − 2), C15 (NεHi …COi − 3) and C18 (NεHi …COi − 4) motifs, with only the C18motif being analogous to the Asn C17structure. Specific conformational types are established for the Asn containing motifs, which mimic backbone β-turns and α-turns. Histidine residues are shown to serve as a mimic for Asn residues in side chain-backbone hydrogen bonded ring motifs. Illustrative examples from protein structures are considered. Proteins 2012; © 2011 Wiley Periodicals, Inc.
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REFERENCES
- 1 BartlettGJ,PorterCT,BorkakotiN,ThorntonJM. Analysis of catalytic residues in enzyme active sites. J Mol Biol 2002; 324: 105–121.
- 2 BakerEN,HubbardRE. Hydrogen bonding in globular proteins. Prog Biophys Mol Biol 1984; 44: 97–179.
- 3 StickleDF,PrestaLG,DillKA,RoseGD. Hydrogen bonding in globular proteins. J Mol Biol 1992; 226: 1143–1159.
- 4 PrestaLG,RoseGD. Helix signals in proteins. Science 1988; 240: 1632–1641.
- 5 HarperET,RoseGD. Helix stop signals in proteins and peptides: the capping box. Biochemistry 1993; 32: 7605–7609.
- 6 AuroraR,RoseGD. Helix capping. Protein Sci 1998; 7: 21–38.
- 7 DasguptaS,BellJA. Design of helix ends. Amino acid preferences, hydrogen bonding and electrostatic interactions. Int J Pept Protein Res 1993; 41: 499–511.
- 8 SerranoL,FershtAR. Capping and α-helix stability. Nature 1989; 342: 296–299.
- 9 DoigAJ,MacarthurMW,StapleyBJ,ThorntonJM. Structures of N-termini of helices in proteins. Protein Sci 1997; 6: 147–155.
- 10 RichardsonJS,RichardsonDC. Amino acid preferences for specific locations at the ends of α-helices. Science 1988; 240: 1648–1652.
- 11 ChakrabartyA,DoigAJ,BaldwinRL. Helix capping propensities in peptides parallel those in proteins. Proc Natl Acad Sci USA 1993; 90: 11332–11336.
- 12 Questel JYL,MorrisDG,MaccallumPH,PoetR,Milner-WhiteEJ. Common ring motifs in proteins involving asparagine and glutamine amide groups hydrogen bonded to main chain atoms. J Mol Biol 1993; 231: 888–896.
- 13 DuddyWJ,NissinkJWM,AllenFH,Milner-WhiteEJ. Mimicry by Asx and ST-turns of the four main types of β-turn in proteins. Protein Sci 2004; 13: 3051–3055.
- 14 WanW-Y,Milner-WhiteEJ. A natural grouping of motifs with an aspartate or asparagine residue forming two hydrogen bonds to Residues ahead in sequence: their occurrence at α-helical N-termini and in other situations. J Mol Biol 1999; 286: 1633–1649.
- 15 EswarN,RamakrishnanC. Deterministic features of side-chain main chain hydrogen bonds in globular protein structures. Protein Eng 2000; 13: 227–238.
- 16 EswarN,RamakrishnanC. Secondary structures without backbone: an analysis of backbone mimicry by polar side chains in protein structures. Protein Eng 1999; 12: 447–455.
- 17
VijayakumarM,QianH,ZhouHX.
Hydrogen bonds between short polar side chains and peptide backbone: prevalence in proteins and effects on helix-forming propensities.
Proteins Struct Funct Gen
1999;
34:
497–507.
10.1002/(SICI)1097-0134(19990301)34:4<497::AID-PROT9>3.0.CO;2-G CAS PubMed Web of Science® Google Scholar
- 18 BordoD,ArgosP. The role of side-chain hydrogen bonds in the formation and stabilization of secondary structure in soluble proteins. J Mol Biol 1994; 243: 504–519.
- 19 RichardsonJS. The anatomy and taxonomy of protein structure. Adv Protein Chem 1981; 34; 167–339.
- 20 NagarajaramHA,SowdhaminiR,RamakrishnanC.BalaramP. Termination of right-handed helices in proteins by residues in left-handed helical conformation. FEBS Lett 1993; 321: 79–83.
- 21 SrinivasanN,AnuradhaVS,RamakrishnanC,SowdhaminiR.BalaramP. Conformational characteristics of asparaginyl residues in proteins. Int J Pept Protein Res 1994; 44: 112–122.
- 22 TakanoK,YamagataY,YutaniK. Role of non-Glycine residues in left-handed helical conformation for the conformational stability of human lysozyme. Proteins: Struct Funct Gen 2001; 44: 233–243.
- 23 EneaV,EllisJ,ZavalaF,ArgotDE,AsavanichA,MasudaA,QuakyiI,NussenzweigRS. DNA cloning of Plasmodium falciparum circumspozoite gene. Amino acid sequence of repetitive epitope. Science 1984; 225: 628–630.
- 24 StahlHD,BiancoAE,CrewtherPE,BurkotT,CoppelRL,BrownGV,AndersRF,KempDJ. An asparagine-rich protein from blood stages of Plasmodium falciparum shares determinants with sporozoites. Nucleic Acids Res 1986; 14: 3089–3102.
- 25 WahlgrenM,AslundL,FranzénL,SundvallM,WåhlinB,BerzinsK,McNicolLA,BjörkmanA,WigzellH,PerlmannP,PetterssonU. A Plasmodium falciparum antigen containing clusters of asparagine residues. Proc Natl Acad Sci USA 1986; 83: 2677–2681.
- 26 GibsonKD,ScheragaHA. Predicted conformations for the immunodominant region of the circumsporozoite protein of the human malaria parasite Plasmodium falciparum. Proc Natl Acad Sci USA 1986; 83: 5649–5653.
- 27 PerutzMF. Glutamine repeats and neurodegenerative disorders. Mol Aspects Trends Biochem Sci 1999; 24: 58–63.
- 28 TrottierY,LutzY,StevaninG,ImbertG,DevysD,CancelG,SaudouF,WeberC,DavidG,ToraL,AgidY,BriceA,MandelJ-L. Polyglutamine expansion as a pathological epitope in Huntington's disease and four dominant cerebellar ataxias. Nature 1995; 378: 403–406.
- 29 PanovAV,GutekunstC-A,LeavittBR,HaydenMR,BurkeJR,StrittmatterWJ,GreenamyreJT. Early mitochondrial calcium defects in Huntington's disease are a direct effect of polyglutamines. Nat Neurosci 2002; 5: 731–736.
- 30 ScherzingerA,SittlerA,SchweigerK,HeiserV,LurzR,HasenbankR,BatesGP,LehrachH,WankerEE. Self-assembly of polyglutamine containing huntingtin fragments into amyloid-like fibrils: implications for Huntington's disease pathology. Proc Natl Acad Sci USA 1999; 96: 4604–4609.
- 31 ScherzingerA,LurzR,TurmaineM,MangiariniL,HollenbachB,HasenbankR,BatesGP,DaviesSW,LehrachH,WankerEE. Huntingtin-encoded polyglutamine expansions form amyloid-like protein aggregates in vitro and in vivo. Cell 1997; 90: 549–558.
- 32 SawayaMR,SambashivanS,NelsonR,IvanovaMI,SieversSA,ApostolMI,ThompsonMJ,BalbirnieM,WiltziusJJW,McFarlaneHT,MadsenAO,RiekelC,EisenbergD. Atomic structures of amyloid cross-β spines reveal varied steric zippers. Nature 2007; 447: 453–457.
- 33 BanerjeeM,BalaramH,BalaramP. Structural effects of a dimer interface mutation on catalytic activity of triosephosphate isomerase. The role of conserved residues and complementary mutations. FEBS J 2009; 276: 4169–4183.
- 34 JoglG,RozovskyS,McDermottAE,TongL. Optimal alignment for enzymatic proton transfer: structure of the Michaelis complex of triosephosphate isomerase at 1.2Å resolution. Proc Natl Acad Sci USA 2003; 100: 50–55.
- 35
MaesD,ZeelenJP,ThankiN,BeaucampN,AlvarezM,ThiMHD,BackmannJ,MartialJA,WynsL,JaenickeR,WierengaRK.
The crystal structure of triosephosphate isomerase (TIM) from Thermotoga maritima: a comparative thermostability structural analysis of ten different TIM structures.
Proteins Struct Funct Bioinf
1999;
37:
441–453.
10.1002/(SICI)1097-0134(19991115)37:3<441::AID-PROT11>3.0.CO;2-7 CAS PubMed Web of Science® Google Scholar
- 36 BorchertTV,AbagyanR,KishanKV,ZeelanJP,WierengaRK. The crystal structure of an engineered monomeric triosephosphate isomerase, monoTIM: the correct modelling of an eight-residue loop. Structure 1993; 1: 205–213.
- 37 WorthCL,BlundellT. On the evolutionary conservation of hydrogen bonds made by buried polar amino acids: the hidden joists, braces and trusses of protein architecture. BMC Evol Biol 2010; 10: 161–171.
- 38 McDonaldIK,ThorntonJM. The application of hydrogen bonding analysis in X-ray crystallography to help orientate asparagin, glutamine and histidine side chains. Protein Eng 1994; 8: 217–224.
- 39 LovellSC,WordJM,RichardsonJS,RichardsonDC. Asparagine and glutamine rotamers: B-factor cutoff and correction of amide flips yield distinct clustering. Proc Natl Acad Sci USA 1999; 96: 400–405.
- 40 WordJM,LovellSC,RichardsonJS,RichardsonDC. Asparagine and glutamine: using hydrogen atom contacts in the choice of side-chain amide orientation. J Mol Biol 1999; 285: 1735–1747.
- 41 WeichenbergerCX,SipplMJ. NA-Flipper: recognition and correction of erroneous asparagine and glutamine side-chain rotamers in protein structures. Nucleic Acids Res 2007; 35: W403–W406.
- 42 VenkatachalamCM. Stereochemical criteria for polypeptides and proteins. V. Conformation of a system of three linked peptide units. Biopolymers 1968; 6: 1425–1436.
- 43 WilmotCM.ThorntonJM. Analysis and prediction of the different types of β-turn in proteins. J Mol Biol 1988; 203: 221–232.
- 44 NatarajDV,SrinivasanN,SowdhaminiR,RamakrishnanC. α-turns in protein structures. Curr Sci 1995; 69: 434–447.
- 45 SchellmanC. The αL -conformation at the ends of helices. In: R Jaenicke, editor. Protein folding. North-Holland New York: Elsevier; 1980. pp 53–61.
- 46 GunasekaranK,NagarajaramHA,RamakrishnanC,BalaramP. Stereochemical punctuation marks in protein structures: glycine and proline containing helix stop signals. J Mol Biol 1998; 275: 917–932.
- 47 GhasparinA,MoehleK,LindenA,RobinsonJA. Crystal structure of an NPNA-repeat motif from the circumsporozoite protein of malaria parasite, Plasmodium falciparum. Chem Commun 2006: 174–176.
- 48 PerutzMF,FinchJT,BerrimanJ,LeskA. Amyloid fibres are water-filled nanotubes. Proc Natl Acad Sci USA 2002; 99: 5591–5595.
- 49 LaghaeiR,MousseauN. Spontaneous formation of polyglutamine nanotubes with molecular dynamics simulations. J Chem Phys 2010; 132: 165102–165109.
- 50 ZhangS. Fabrication of novel biomaterials through molecular self-assembly. Nature Biotech 2003; 21: 1171–1178.
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