TPP1 mutagenesis screens unravel shelterin interfaces and functions in hematopoiesis
Sherilyn Grill, Shilpa Padmanaban, Ann Friedman, Eric Perkey, Frederick Allen, Valerie M. Tesmer, Jennifer Chase, Rami Khoriaty, Catherine E. Keegan, Ivan Maillard, Jayakrishnan Nandakumar
Sherilyn Grill, Shilpa Padmanaban, Ann Friedman, Eric Perkey, Frederick Allen, Valerie M. Tesmer, Jennifer Chase, Rami Khoriaty, Catherine E. Keegan, Ivan Maillard, Jayakrishnan Nandakumar
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Research Article Genetics Hematology

TPP1 mutagenesis screens unravel shelterin interfaces and functions in hematopoiesis

Abstract

Telomerase catalyzes chromosome end replication in stem cells and other long-lived cells. Mutations in telomerase or telomere-related genes result in diseases known as telomeropathies. Telomerase is recruited to chromosome ends by the ACD/TPP1 protein (TPP1 hereafter), a component of the shelterin complex that protects chromosome ends from unwanted end joining. TPP1 facilitates end protection by binding shelterin proteins POT1 and TIN2. TPP1 variants have been associated with telomeropathies but remain poorly characterized in vivo. Disease variants and mutagenesis scans provide efficient avenues to interrogate the distinct physiological roles of TPP1. Here, we conduct mutagenesis in the TIN2- and POT1-binding domains of TPP1 to discover mutations that dissect TPP1’s functions. Our results extend current structural data to reveal that the TPP1-TIN2 interface is more extensive than previously thought and highlight the robustness of the POT1-TPP1 interface. Introduction of separation-of-function mutants alongside known TPP1 telomeropathy mutations in mouse hematopoietic stem cells (mHSCs) lacking endogenous TPP1 demonstrated a clear phenotypic demarcation. TIN2- and POT1-binding mutants were unable to rescue mHSC failure resulting from end deprotection. In contrast, TPP1 telomeropathy mutations sustained mHSC viability, consistent with their selectively impacting end replication. These results highlight the power of scanning mutagenesis in revealing structural interfaces and dissecting multifunctional genes.

Authors

Sherilyn Grill, Shilpa Padmanaban, Ann Friedman, Eric Perkey, Frederick Allen, Valerie M. Tesmer, Jennifer Chase, Rami Khoriaty, Catherine E. Keegan, Ivan Maillard, Jayakrishnan Nandakumar

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Figure 3

Mutations in the TPP1TBM, TPP1TBM-ext, or TIN2 disrupt cooperativity of the TPP1-TIN2-TRF2 interaction.

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Mutations in the TPP1TBM, TPP1TBM-ext, or TIN2 disrupt cooperativity of ...
(A) Anti-Myc antibody–bound Myc-TIN2 was pulled down on protein A/G agarose beads with transiently expressed FLAG-TRF2 and indicated FLAG-TPP1 construct. (B) Sequence conservation of a portion of the TIN2 TRFH domain. TIN2 residues examined in this study are labeled above the sequence alignment, with red denoting amino acids whose mutation impaired the TPP1-TIN2 interaction and black denoting amino acids whose mutation did not affect TPP1-TIN2 binding. Asterisks, colons, and periods beneath the sequence lineups represent identical residues, strongly conserved residues, and weakly conserved residues, respectively, as described by the MUSCLE algorithm. (C) Pulldown of indicated FLAG-TIN2 construct on anti-FLAG–conjugated beads with WT Myc-TRF2 and Myc-TPP1. (D) Structure of the TIN2TRFH (gray)-TPP1TBM (pink)- TRF2TBM (lilac) complex (PDB: 5XYF, ref. 36). TIN2 residues whose mutation impacts binding to TPP1 and that likely contact the TPP1TBM-ext are shown in yellow, TIN2K160A is shown in green, and TPP1TBM mutants are shown in red. Data in A and C are representative of at least 5 independent transfections and coimmunoprecipitations (co-IPs) (n = 5).