Abstract
Leucine-zipper transcription regulator 1 (LZTR1) is a highly mutated tumor suppressor gene, involved in the pathogenesis of several cancer types and developmental disorders. In proteasomal degradation, it acts as an adaptor protein responsible for the recognition and recruitment of substrates to be ubiquitinated in Cullin3-RING ligase E3 (CRL3) machinery. LZTR1 belongs to the BTB-Kelch family, a multi-domain protein where the Kelch propeller plays as the substrate recognition region and for which no experimental structure has been solved. Recently, large effort mutational analyses pointed to the role of disease-associated LZTR1 mutations in the RAS/MAPK signaling pathway and RIT1, a small Ras-related GTPase protein, has been identified by mass spectroscopy to interact with LZTR1. Hence, a better understanding of native structure, molecular mechanism, and substrate specificity would help clarifying the role of LZTR1 in pathological diseases, thus promoting advancement in the development of novel therapeutic strategies. Here, we address the interaction model between adaptor LZTR1 and substrate RIT1 by applying an integrated computational approach, including molecular modeling and docking techniques. We observe that the interaction model LZTR1-RIT1 is stabilized by an electrostatic bond network established between the two protein surfaces, which is reminiscent of homologous ubiquitin ligases complexes. Then, running MD simulations, we characterize differential conformational dynamics of the multi-domain LZTR1, offering interesting implications on the mechanistic role of specific point mutations. We identify G248R and R283Q as damaging mutations involved in the recognition process of the substrate RIT1 and R412C as a possible allosteric mutation from the Kelch to the C-term BTB-domain. Our findings provide important structural insights on targeting CRL3s for drug discovery.
Highlights
Glioblastoma (GBM) is the most common primary intrinsic malignant brain tumor; the identification of genetic alterations that drive the tumor initiation and progression, together with the functional consequences, is crucial to develop effective therapies
While several theoretical efforts have been made to model single domain Leucine-zipper transcription regulator 1 (LZTR1) and reproduce the structural interaction between BTB-Back and Cullin 3, this is the very first attempt to characterize the full-length model structure aimed at investigating the Kelch recognition mechanism and its mode of interaction with E3 ligase substrates.[1,3,6,28,29]
We modeled the three-dimensional structure of the full-length LZTR1 adaptor protein as a fully elongated multi-domain structure whereby the N-terminal Kelch domain appears well separated from the two following BTB-Back domains
Summary
Glioblastoma (GBM) is the most common primary intrinsic malignant brain tumor; the identification of genetic alterations that drive the tumor initiation and progression, together with the functional consequences, is crucial to develop effective therapies. In light of direct structure−activity relationships, a deeper knowledge of its molecular shape and the definition of molecular parameters characteristic of the protein− protein interaction are essential points. All this information can serve to discriminate among different molecular states, to identify the “active” form of the tumor suppressor capable of substrate recruitment, and to foresee other potential interactors
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