Mylène Perderiset

Human RTEL1 deficiency causes Hoyeraal–Hreidarsson syndrome with short telomeres and genome instability

Hoyeraal-Hreidarsson syndrome (HHS), a severe variant of dyskeratosis congenita (DC), is characterized by early onset bone marrow failure, immunodeficiency and developmental defects. Several factors involved in telomere length maintenance and/or protection are defective in HHS/DC, underlining the relationship between telomere dysfunction and these diseases. By combining whole-genome linkage analysis and exome sequencing, we identified compound heterozygous RTEL1 (regulator of telomere elongation helicase 1) mutations in three patients with HHS from two unrelated families. RTEL1 is a DNA helicase that participates in DNA replication, DNA repair and telomere integrity. We show that, in addition to short telomeres, RTEL1-deficient cells from patients exhibit hallmarks of genome instability, including spontaneous DNA damage, anaphase bridges and telomeric aberrations. Collectively, these results identify RTEL1 as a novel HHS-causing gene and highlight its role as a genomic caretaker in humans.

Distinct roles of doublecortin modulating the microtubule cytoskeleton

Doublecortin is a neuronal microtubule‐stabilising protein, mutations of which cause mental retardation and epilepsy in humans. How doublecortin influences microtubule dynamics, and thereby brain development, is unclear. We show here by video microscopy that purified doublecortin has no effect on the growth rate of microtubules. However, it is a potent anti‐catastrophe factor that stabilises microtubules by linking adjacent protofilaments and counteracting their outward bending in depolymerising microtubules. We show that doublecortin‐stabilised microtubules are substrates for kinesin translocase motors and for depolymerase kinesins. In addition, doublecortin does not itself oligomerise and does not bind to tubulin heterodimers but does nucleate microtubules. In cells, doublecortin is enriched at the distal ends of neuronal processes and our data raise the possibility that the function of doublecortin in neurons is to drive assembly and stabilisation of non‐centrosomal microtubules in these doublecortin‐enriched distal zones. These distinct properties combine to give doublecortin a unique function in microtubule regulation, a role that cannot be compensated for by other microtubule‐stabilising proteins and nucleating factors.

Template-free 13-protofilament microtubule–MAP assembly visualized at 8 Å resolution

The high-resolution structure of doublecortin-stabilized microtubules provides unprecedented insight into their in vivo architecture.

Structural Basis for Arf1-Mediated Recruitment of Arhgap21 to Golgi Membranes.

ARHGAP21 is a Rho family GTPase‐activating protein (RhoGAP) that controls the Arp2/3 complex and F‐actin dynamics at the Golgi complex by regulating the activity of the small GTPase Cdc42. ARHGAP21 is recruited to the Golgi by binding to another small GTPase, ARF1. Here, we present the crystal structure of the activated GTP‐bound form of ARF1 in a complex with the Arf‐binding domain (ArfBD) of ARHGAP21 at 2.1 Å resolution. We show that ArfBD comprises a PH domain adjoining a C‐terminal α helix, and that ARF1 interacts with both of these structural motifs through its switch regions and triggers structural rearrangement of the PH domain. We used site‐directed mutagenesis to confirm that both the PH domain and the helical motif are essential for the binding of ArfBD to ARF1 and for its recruitment to the Golgi. Our data demonstrate that two well‐known small GTPase‐binding motifs, the PH domain and the α helical motif, can combine to create a novel mode of binding to Arfs.

Biochemical and Structural Characterization of the Gem GTPase

RGK proteins, encompassing Rad, Gem, Rem1, and Rem2, constitute an intriguing branch of the Ras superfamily; their expression is regulated at the transcription level, they exhibit atypical nucleotide binding motifs, and they carry both large N- and C-terminal extensions. Biochemical and structural studies are required to better understand how such proteins function. Here, we report the first structure for a RGK protein: the crystal structure of a truncated form of the human Gem protein (G domain plus the first part of the C-terminal extension) in complex with Mg·GDP at 2.1 Å resolution. It reveals that the G-domain fold and Mg·GDP binding site of Gem are similar to those found for other Ras family GTPases. The first part of the C-terminal extension adopts an α-helical conformation that extends along the α5 helix and interacts with the tip of the interswitch. Biochemical studies show that the affinities of Gem for GDP and GTP are considerably lower (micromolar range) compared with H-Ras, independent of the presence or absence of N- and C-terminal extensions, whereas its GTPase activity is higher than that of H-Ras and regulated by both extensions. We show how the bulky DXWEX motif, characteristic of the switch II of RGK proteins, affects the conformation of switch I and the phosphate-binding site. Altogether, our data reveal that Gem is a bona fide GTPase that exhibits striking structural and biochemical features that should impact its regulation and cellular activities.

The helicase FBH1 is tightly regulated by PCNA via CRL4(Cdt2)-mediated proteolysis in human cells

During replication, DNA damage can challenge replication fork progression and cell viability. Homologous Recombination (HR) and Translesion Synthesis (TLS) pathways appear as major players involved in the resumption and completion of DNA replication. How both pathways are coordinated in human cells to maintain genome stability is unclear. Numerous helicases are involved in HR regulation. Among them, the helicase FBH1 accumulates at sites of DNA damage and potentially constrains HR via its anti-recombinase activity. However, little is known about its regulation in vivo. Here, we report a mechanism that controls the degradation of FBH1 after DNA damage. Firstly, we found that the sliding clamp Proliferating Cell Nuclear Antigen (PCNA) is critical for FBH1 recruitment to replication factories or DNA damage sites. We then showed the anti-recombinase activity of FBH1 is partially dependent on its interaction with PCNA. Intriguingly, after its re-localization, FBH1 is targeted for degradation by the Cullin-ring ligase 4-Cdt2 (CRL4Cdt2)–PCNA pathway via a PCNA-interacting peptide (PIP) degron. Importantly, expression of non-degradable FBH1 mutant impairs the recruitment of the TLS polymerase eta to chromatin in UV-irradiated cells. Thus, we propose that after DNA damage, FBH1 might be required to restrict HR and then degraded by the Cdt2–proteasome pathway to facilitate TLS pathway.

Bi-directional routing of DNA mismatch repair protein human exonuclease 1 to replication foci and DNA double strand breaks.

Human exonuclease 1 (hEXO1) is implicated in DNA metabolism, including replication, recombination and repair, substantiated by its interactions with PCNA, DNA helicases BLM and WRN, and several DNA mismatch repair (MMR) proteins. We investigated the sub-nuclear localization of hEXO1 during S-phase progression and in response to laser-induced DNA double strand breaks (DSBs). We show that hEXO1 and PCNA co-localize in replication foci. This apparent interaction is sustained throughout S-phase. We also demonstrate that hEXO1 is rapidly recruited to DNA DSBs. We have identified a PCNA interacting protein (PIP-box) region on hEXO1 located in its COOH-terminal ((788)QIKLNELW(795)). This motif is essential for PCNA binding and co-localization during S-phase. Recruitment of hEXO1 to DNA DSB sites is dependent on the MMR protein hMLH1. We show that two distinct hMLH1 interaction regions of hEXO1 (residues 390-490 and 787-846) are required to direct the protein to the DNA damage site. Our results reveal that protein domains in hEXO1 in conjunction with specific protein interactions control bi-directional routing of hEXO1 between on-going DNA replication and repair processes in living cells.

Structural studies of the doublecortin family of MAPs.

Doublecortin (DCX) is a microtubule (MT)-stabilizing protein essential for neuronal migration during human brain development. Missense mutations in DCX cause severe brain defects. This implies that the many other MT-stabilizing proteins in neurons cannot compensate for DCX function. To understand the unusual properties of DCX, we expressed the recombinant human DCX in Sf9 cells and undertook structural characterization of its interaction with MTs using cryo-electron microscopy. DCX specifically nucleates 13-protofilament (13-pf) MTs, the architecture of human MTs in vivo. Cryo-electron tomography (cryo-ET) of DCX-nucleated MTs showed that they are primarily built from B-lattice contacts interrupted by a single discontinuity, the seam. Because of this asymmetry, we used single-particle reconstruction and determined the 8Å structure of DCX-stabilized 13-pf MTs in the absence of a stabilizing drug. The DCX-binding site, at the corner of four tubulin dimers, is ideally suited to stabilize both lateral and longitudinal tubulin lattice contacts. Its precise geometry suggests that DCX is sensitive to the angle between pfs, and thereby provides insight into the specificity of DCX for 13-pf MT architecture. DCXs precise interaction at the corner of four tubulin dimers also means that DCX does not bind the MT seam. Our work has provided mechanistic insight into the evolutionarily conserved DCX family of MT-stabilizing proteins and also into more general regulatory mechanisms of the MT cytoskeleton.

A double-take on MAPs.

Structural characterization of the DCX domains from doublecortin reveals novel mechanisms for microtubule binding in a protein essential for brain development.