Whittaker S B, Boetzel R, MacDonald C, Lian L Y, Pommer A J, Reilly A, James R, Kleanthous C, Moore G R
School of Chemical Sciences, University of East Anglia, Norwich, U.K.
J Biomol NMR. 1998 Jul;12(1):145-59. doi: 10.1023/a:1008272928173.
The cytotoxic activity of the secreted bacterial toxin colicin E9 is due to a non-specific DNase housed in the C-terminus of the protein. Double-resonance and triple-resonance NMR studies of the 134-amino acid 15N- and 13C/15N-labelled DNase domain are presented. Extensive conformational heterogeneity was evident from the presence of far more resonances than expected based on the amino acid sequence of the DNase, and from the appearance of chemical exchange cross-peaks in TOCSY and NOESY spectra. EXSY spectra were recorded to confirm that slow chemical exchange was occurring. Unambiguous sequence-specific resonance assignments are presented for one region of the protein, Pro65-Asn72, which exists in two slowly exchanging conformers based on the identification of chemical exchange cross-peaks in 3D 1H-1H-15N EXSY-HSQC, NOESY-HSQC and TOCSY-HSQC spectra, together with C alpha and C beta chemical shifts measured in triple-resonance spectra and sequential NH NOEs. The rates of conformational exchange for backbone amide resonances in this stretch of amino acids, and for the indole NH of either Trp22 or Trp58, were determined from the intensity variation of the appropriate diagonal and chemical exchange cross-peaks recorded in 3D 1H-1H-15N NOESY-HSQC spectra. The data fitted a model in which this region of the DNase has two conformers, NA and NB, which interchange at 15 degrees C with a forward rate constant of 1.61 +/- 0.5 s-1 and a backward rate constant of 1.05 +/- 0.5 s-1. Demonstration of this conformational equilibrium has led to a reappraisal of a previously proposed kinetic scheme describing the interaction of E9 DNase with immunity proteins [Wallis et al. (1995) Biochemistry, 34, 13743-13750 and 13751-13759]. The revised scheme is consistent with the specific inhibitor protein for the E9 DNase, Im9, associating with both the NA and NB conformers of the DNase and with binding only to the NB conformer detected because the rate of dissociation of the complex of Im9 and the NA conformer, NAI. is extremely rapid. In this model stoichiometric amounts of Im9 convert, the E9 DNase is converted wholly into the NBI form. The possibility that cis-trans isomerisation of peptide bonds preceding proline residues is the cause of the conformational heterogeneity is discussed. E9 DNase contains 10 prolines, with two bracketing the stretch of amino acids that have allowed the NA [symbol: see text] NB interconversion to be identified, Pro65 and Pro73. The model assumes that one or both of these can exist in either the cis or trans form with strong Im9 binding possible to only one form.
分泌型细菌毒素大肠杆菌素E9的细胞毒性活性归因于该蛋白质C末端所含的一种非特异性DNA酶。本文介绍了对134个氨基酸的15N和13C/15N标记的DNA酶结构域进行的双共振和三共振核磁共振研究。基于DNA酶的氨基酸序列,共振峰数量远超预期,以及在TOCSY和NOESY谱中出现化学交换交叉峰,均表明存在广泛的构象异质性。记录EXSY谱以确认发生了缓慢的化学交换。给出了蛋白质一个区域(Pro65 - Asn72)明确的序列特异性共振归属,该区域基于在3D 1H - 1H - 15N EXSY - HSQC、NOESY - HSQC和TOCSY - HSQC谱中化学交换交叉峰的识别,以及在三共振谱中测量的Cα和Cβ化学位移和序列NH NOE,以两种缓慢交换的构象存在。根据在3D 1H - 1H - 15N NOESY - HSQC谱中记录的适当对角线峰和化学交换交叉峰的强度变化,确定了这段氨基酸中主链酰胺共振以及Trp22或Trp58的吲哚NH的构象交换速率。数据符合一个模型,即DNA酶的该区域有两个构象体,NA和NB,它们在15℃下相互转换,正向速率常数为1.61±0.5 s-1,反向速率常数为1.
