Abstract
Self-assembling processes occur in a variety of compounds such as peptides, proteins and DNA. These processes have been linked to pathologies and have as well been exploited for designing responsive contrast agents for disease detection. Novel methods to investigate and detect self-assembly therefore hold promise to obtain more insights into disease progression or open pathways to the design of novel self-assembling materials. In this article we are introducing nuclear singlet states to probe self-assembly in the dipeptide isoleucine-phenylalanine (IF) as a thermoresponsive on/off switch for nuclear magnetic resonance (NMR). We have investigated the relaxation and singlet state properties of the β-protons of phenylalanine in the IF dipeptide in aqueous solutions. At IF concentrations of 2 wt% and above 308 K, a long lived nuclear singlet state, as compared to the longitudinal relaxation, was observed. At 308 K the dipeptide starts forming a gel and no singlet state is accessible at lower temperatures. Upon heating, the gel disassembles and an isotropic liquid forms making the singlet state accessible again. This demonstrates the thermoresponsive on-off character of the nuclear spin singlet state in the IF dipeptide.
Highlights
In this work we have explored the feasibility of utilizing nuclear singlet states as on/off switches and demonstrate that such a behaviour can be observed in b-protons of the dipeptide isoleucine–phenylalanine (IF), which is shown in Fig. 1 together
For the investigation of nuclear singlet states in a weakly coupled spin system, we introduce a filter that is offset independent
We have introduced an extension of the T00 filter that can be utilized for weakly coupled spin systems
Summary
In this work we have explored the feasibility of utilizing nuclear singlet states as on/off switches and demonstrate that such a behaviour can be observed in b-protons of the dipeptide isoleucine–phenylalanine (IF), which is shown in Fig. 1 together. The sequence can be applied to weakly coupled spin systems (as it is the case here) and includes an extension of the previously published T00-filter.[61] We show that the dipeptide acts as a thermoresponsive switch for singlet states, which can be populated (turned on) at a temperature of 308 K and are not accessible below this temperature (turned off). This is due to the fact that below the critical temperature a hydrogel[62] is formed in which the correlation time is significantly increased. Our investigations on this molecule and its behaviour are presented in the following
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