Abstract

Phytochromes are dimeric biliprotein photoreceptors exhibiting characteristic red/far-red photocycles. Full-length cyanobacterial phytochrome Cph1 from Synechocystis 6803 is soluble initially but tends to aggregate in a concentration-dependent manner, hampering attempts to solve the structure using NMR and crystallization methods. Otherwise, the Cph1 sensory module (Cph1Δ2), photochemically indistinguishable from the native protein and used extensively in structural and other studies, can be purified to homogeneity in >10 mg amounts at mM concentrations quite easily. Bulk precipitation of full-length Cph1 by ammonium sulfate (AmS) was expected to allow us to produce samples for solid-state magic-angle spinning (MAS) NMR from dilute solutions before significant aggregation began. It was not clear, however, what effects the process of partial dehydration might have on the molecular structure. Here we test this by running solid-state MAS NMR experiments on AmS-precipitated Cph1Δ2 in its red-absorbing Pr state carrying uniformly 13C/15N-labeled phycocyanobilin (PCB) chromophore. 2D 13C–13C correlation experiments allowed a complete assignment of 13C responses of the chromophore. Upon precipitation, 13C chemical shifts for most of PCB carbons move upfield, in which we found major changes for C4 and C6 atoms associated with the A-ring positioning. Further, the broad spectral lines seen in the AmS 13C spectrum reflect primarily the extensive inhomogeneous broadening presumably due to an increase in the distribution of conformational states in the protein, in which less free water is available to partake in the hydration shells. Our data suggest that the effect of dehydration process indeed leads to changes of electronic structure of the bilin chromophore and a decrease in its mobility within the binding pocket, but not restricted to the protein surface. The extent of the changes induced differs from the freezing process of the solution samples routinely used in previous MAS NMR and crystallographic studies. AmS precipitation might nevertheless provide useful protein structure/functional information for full-length Cph1 in cases where neither X-ray crystallography nor conventional NMR methods are available.

Highlights

  • Phytochromes modulate various biological responses to light in almost all phases of plant development (Franklin and Quail, 2010)

  • The 13C assignment of two photoconvert between red-absorbing (Pr) spectra of the precipitated Cph1 2 (Figure 1) is based on our previous dipolar-assisted rotational resonance (DARR) data from its frozen solution (Rohmer et al, 2008): preliminary assignment achieved by analysis of direct correlations between 13C spins and validated by indirect correlations originated from weak polarization transfers among isolated 13C spins

  • These assignments are confirmed by multi-bond correlation peaks involving non-propionate carbons such as C7 (125.2 ppm)/C71 (8.7 ppm)–C81/C82/C83, C10 (111.8 ppm)/C11 (126.5 ppm)–C121, C13 (126.2 ppm)–C121/C122/C123, and C131 (10.7 ppm)–C122/C123 resolved in the 28-ms DARR mixing spectrum (Figure 1, purple)

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Summary

Introduction

Phytochromes modulate various biological responses to light in almost all phases of plant development (Franklin and Quail, 2010). Phytochromes typically photoconvert between red-absorbing (Pr) and far-red-absorbing (Pfr) states via a C15-Z/E isomerization of their covalently bound linear tetrapyrrole (bilin) chromophores (Rockwell et al, 2006; Hughes, 2010; Rockwell and Lagarias, 2010; Song et al, 2011a; Yang et al, 2011). The bilin chromophore such as phycocyanobilin (PCB), phytochromobilin (P B), or biliverdin (BV) is buried in a conserved pocket formed in the GAF (cGMP phosphodiesterase, adenylate cyclase, FhlA) domain which is part of a knotted N-terminal photosensory module comprising PAS (Period/ARNT/Single-minded) and PHY (phytochrome-specific) domains. Neither the photochromic absorbance properties nor its mechanistic connection to signaling are well understood,

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