Large Multidomain Protein NMR: HIV-1 Reverse Transcriptase Precursor in Solution.

Teresa Brosenitsch,Nicolas Sluis-Cremer,Rieko Ishima,Zhaoyong Xi,Tatiana V. Ilina

doi:10.3390/ijms21249545

Teresa Brosenitsch, Nicolas Sluis-Cremer + Show 3 more

Open Access

https://doi.org/10.3390/ijms21249545

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Abstract

NMR studies of large proteins, over 100 kDa, in solution are technically challenging and, therefore, of considerable interest in the biophysics field. The challenge arises because the molecular tumbling of a protein in solution considerably slows as molecular mass increases, reducing the ability to detect resonances. In fact, the typical 1H-13C or 1H-15N correlation spectrum of a large protein, using a 13C- or 15N-uniformly labeled protein, shows severe line-broadening and signal overlap. Selective isotope labeling of methyl groups is a useful strategy to reduce these issues, however, the reduction in the number of signals that goes hand-in-hand with such a strategy is, in turn, disadvantageous for characterizing the overall features of the protein. When domain motion exists in large proteins, the domain motion differently affects backbone amide signals and methyl groups. Thus, the use of multiple NMR probes, such as 1H, 19F, 13C, and 15N, is ideal to gain overall structural or dynamical information for large proteins. We discuss the utility of observing different NMR nuclei when characterizing a large protein, namely, the 66 kDa multi-domain HIV-1 reverse transcriptase that forms a homodimer in solution. Importantly, we present a biophysical approach, complemented by biochemical assays, to understand not only the homodimer, p66/p66, but also the conformational changes that contribute to its maturation to a heterodimer, p66/p51, upon HIV-1 protease cleavage.

Highlights

Many retroviruses translate their proteins as large precursor polyproteins from which individual proteins are cleaved to become their mature functional forms [1]
We focus on reverse transcriptase (RT) from human immunodeficiency virus-1 (HIV-1), which is initially expressed as a 66 kDa protein (p66) in a Gag-Pol polyprotein and contains five domains in itself
We reTchoerdIleed- 11Ha-n13dCMHeMt- QmCetshpyelctHraMoQf CIlee-xδp1emrimetehnytl, saisgndaislcsuosfsepd66th/pu6s6fainr, tihsehiinghhliybistoenr-sfirteiveefoarnmd, tthheerNefNorReT, Iin-bfoourmndatifvoermw,haenndcthhaorsaectweriitzhin/wgiltahroguet ptRroNteAinLsysi3n[1s2o8lu],tiaonkn[1o0w5n,11p2r–im11e6r,1f2o1r,1t2h2e],redvueersteo the fast three-site jump of methyl groups [117,118,119,120], and the transverse relaxation optimized spectroscopy (TROSY) effect, which is a consequence of the methyl group C-H dipolar cross-correlations [110,111]

Summary

Introduction

Many retroviruses translate their proteins as large precursor polyproteins from which individual proteins are cleaved to become their mature functional forms [1]. We focus on reverse transcriptase (RT) from human immunodeficiency virus-1 (HIV-1), which is initially expressed as a 66 kDa protein (p66) in a Gag-Pol polyprotein and contains five domains in itself. P66 is cleaved by the HIV-1 protease (PR) to form a functional heterodimer, comprising p66 and p51 subunits (p66/p51) [13,14]. With the advancement of recombinant protein expression and purification, studies to structurally characterize p66/p66 have become possible during the past several years. We will highlight how the 132 kDa dimeric protein has been studied by solution NMR and how other biophysics/biochemistry methods have been used to verify or validate the results

Function and Structure of the Mature HIV-1 RT

Characteristics of Methyl vs Amide NMR When Domain Motion Exists