BsYetJ is a bacterial homolog of transmembrane BAX inhibitor-1 motif-containing 6 (TMBIM6) membrane protein that plays a key role in the control of calcium homeostasis. However, the BsYetJ (or TMBIM6) structure embedded in a lipid bilayer is uncharacterized, let alone the molecular mechanism of the calcium transport activity. Herein, we report structures of BsYetJ in lipid nanodiscs identified by double electron–electron resonance spectroscopy. Our results reveal that BsYetJ in lipid nanodiscs is structurally different from those crystallized in detergents. We show that BsYetJ conformation is pH-sensitive in apo state (lacking calcium), whereas in a calcium-containing solution it is stuck in an intermediate, inert to pH changes. Only when the transmembrane calcium gradient is established can the calcium-release activity of holo-BsYetJ occur and be mediated by pH-dependent conformational changes, suggesting a dual gating mechanism. Conformational substates involved in the process and a key residue D171 relevant to the gating of calcium are identified. Our study suggests that BsYetJ/TMBIM6 is a pH-dependent, voltage-gated calcium channel.
While activation of BAX is required for initiating mitochondria-mediated apoptosis, the underlying mechanisms remain unsettled. We studied conformations of BAX protein using pressure- and temperature-resolved ESR techniques and obtained the thermodynamic properties of the conformations. We show that inactive BAX is structurally heterogeneous and exists in equilibrium between two major populations of the conformations, UM and UM', of which the former is thermodynamically favored at room temperature. An increase in the population of UM', induced by either pressure or point mutations of BAX, renders BAX susceptible to oligomerization, which leads to cell death. This study uncovers the biological significance of BAX conformations and shows that the pro-apoptotic activity of BAX can be triggered by altering the equilibrium between the two states. It suggests that therapeutic intervention may focus on shifting the balance in the conformational heterogeneity.
The YtfE protein catalyzes the reduction
of NO to N2O, protecting iron–sulfur clusters from
nitrosylation. The
structure of YtfE has a two-domain architecture, with a diiron-containing
C-terminal domain linked to an N-terminal domain, in which the function
of the latter is enigmatic. Here, by using electron spin resonance
(ESR) spectroscopy, we show that YtfE exists in two conformational
states, one of which has not been reported. Under high osmotic stress,
YtfE adopts a homogeneous conformation (C state) similar to the known
crystal structure. In a regular buffer, the N-terminal domain switches
between the C state and a previously unidentified conformation (C′
state), the latter of which has more space at the domain interface
to allow the trafficking of NO molecules and thus is proposed to be
a functionally active state. The conformational switch between the
C and C′ states is pivotal for facilitating NO access to the
diiron core.
BCL-2, a key protein in inhibiting apoptosis, has a 65-residue-long highly flexible loop domain (FLD) located on the opposite side of its ligand-binding groove. In vivo phosphorylation of the FLD enhances the affinity of BCL-2 for pro-apoptotic ligands, and consequently anti-apoptotic activity. However, it remains unknown as to how the faraway, unstructured FLD modulates the affinity. Here we investigate the protein-ligand interactions by fluorescence techniques and monitor protein dynamics by DEER and NMR spectroscopy tools. We show that phosphomimetic mutations on the FLD lead to a reduction in structural flexibility, hence promoting ligand access to the groove. The bound pro-apoptotic ligands can be displaced by the BCL-2-selective inhibitor ABT-199 efficiently, and thus released to trigger apoptosis. We show that changes in structural flexibility on an unstructured loop can activate an allosteric protein that is otherwise structurally inactive.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.