Molecular principles of bidirectional signalling between membranes and small <scp>GTPases</scp>

Nawrotek, Agata; Dubois, Pavlina; Zeghouf, Mahel; Cherfils, Jacqueline

doi:10.1002/1873-3468.14585

Cited by 6 publications

(4 citation statements)

References 78 publications

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“…We do not favor this interpretation. First, DOCK GEFs have never been shown to activate RHO-1 [ 53 – 55 ]. Second, the structure for DOCK/ELMO/Rac1 argues against this.…”

Section: Discussionmentioning

confidence: 99%

CED-5/CED-12 (DOCK/ELMO) can promote and inhibit F-actin formation via distinct motifs that may target different GTPases

Venkatachalam,

Mannimala,

Pulijala

et al. 2024

PLoS Genet

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Coordinated activation and inhibition of F-actin supports the movements of morphogenesis. Understanding the proteins that regulate F-actin is important, since these proteins are mis-regulated in diseases like cancer. Our studies of C. elegans embryonic epidermal morphogenesis identified the GTPase CED-10/Rac1 as an essential activator of F-actin. However, we need to identify the GEF, or Guanine-nucleotide Exchange Factor, that activates CED-10/Rac1 during embryonic cell migrations. The two-component GEF, CED-5/CED-12, is known to activate CED-10/Rac1 to promote cell movements that result in the engulfment of dying cells during embryogenesis, and a later cell migration of the larval Distal Tip Cell. It is believed that CED-5/CED-12 powers cellular movements of corpse engulfment and DTC migration by promoting F-actin formation. Therefore, we tested if CED-5/CED-12 was involved in embryonic migrations, and got a contradictory result. CED-5/CED-12 definitely support embryonic migrations, since their loss led to embryos that died due to failed epidermal cell migrations. However, CED-5/CED-12 inhibited F-actin in the migrating epidermis, the opposite of what was expected for a CED-10 GEF. To address how CED-12/CED-5 could have two opposing effects on F-actin, during corpse engulfment and cell migration, we investigated if CED-12 harbors GAP (GTPase Activating Protein) functions. A candidate GAP region in CED-12 faces away from the CED-5 GEF catalytic region. Mutating a candidate catalytic Arginine in the CED-12 GAP region (R537A) altered the epidermal cell migration function, and not the corpse engulfment function. We interfered with GEF function by interfering with CED-5’s ability to bind Rac1/CED-10. Mutating Serine-Arginine in CED-5/DOCK predicted to bind and stabilize Rac1 for catalysis, resulted in loss of both ventral enclosure and corpse engulfment. Genetic and expression studies strongly support that the GAP function likely acts on different GTPases. Thus, we propose CED-5/CED-12 support the cycling of multiple GTPases, by using distinct domains, to both promote and inhibit F-actin nucleation.

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“…We do not favor this interpretation. First, DOCK GEFs have never been shown to activate RHO-1 [ 53 – 55 ]. Second, the structure for DOCK/ELMO/Rac1 argues against this.…”

Section: Discussionmentioning

confidence: 99%

CED-5/CED-12 (DOCK/ELMO) can promote and inhibit F-actin formation via distinct motifs that may target different GTPases

Venkatachalam,

Mannimala,

Pulijala

et al. 2024

PLoS Genet

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show abstract

“…ELMO1 NTD appeared disordered in the DOCK5/ELMO1/Rac1 complex, whereas in the DOCK2/ELMO1/Rac1 complex, it was structured into an S-shaped open conformation ( 21 ). In the S-shaped conformation of ELMO1 NTD , the symmetric DOCK2/ELMO1 dimer and RhoG cannot simultaneously interact with the membrane ( 25 ). Therefore, it remains unclear how the DOCK/ELMO complex is activated by membrane-localized RhoG.…”

mentioning

confidence: 99%

RhoG facilitates a conformational transition in the guanine nucleotide exchange factor complex DOCK5/ELMO1 to an open state

Kukimoto-Niino,

Katsura,

Ishizuka-Katsura

et al. 2024

Journal of Biological Chemistry

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“…Arf GTPases, which are major regulators of most aspects of cellular traffic, form a more remote subfamily (to which Sar GTPases and possibly the Rag GTPases and bacterial mutual gliding‐motility protein A [MglA] are related), characterized by a unique allosteric mechanism whereby the nucleotide‐binding site communicates with the membrane [14]. Nawrotek, Cherfils, and co‐workers present an overview of the various ways in which Arfs and their GEFs exchange bidirectional information with the membrane [9]. Accordingly, they define a framework to analyze the interactions of other regulators and effectors of small GTPases with membranes, exemplified by a structure‐based perspective of the activation of DOCK GEFs on membranes.…”

mentioning

confidence: 99%

“…We are now delighted to present 13 articles that highlight how integrated structural, biochemical, and biophysical approaches have allowed to shed light on the mechanisms of fundamental functions of major members of this superfamily. Notably, these reviews show how several experimental approaches that were rarely used a decade ago, are now taking center stage in moving the field forward: reconstitutions of small GTPase systems in artificial membranes [5][6][7][8][9], single particle cryo-electron microscopy [5][6][7][9][10][11][12], 3D electron tomography reconstructions [12], or optogenetics [13]. Of these, Loose and coauthors present a great overview of the power and inherent difficulties of in vitro reconstitutions using biomimetic membranes, and how they have revealed in a quantitative manner the inner workings of intricate small GTPase networks, which would have been unattainable in vivo [8].…”

mentioning

confidence: 99%

Molecular principles of bidirectional signalling between membranes and small GTPases

Cited by 6 publications

References 78 publications

CED-5/CED-12 (DOCK/ELMO) can promote and inhibit F-actin formation via distinct motifs that may target different GTPases

CED-5/CED-12 (DOCK/ELMO) can promote and inhibit F-actin formation via distinct motifs that may target different GTPases

RhoG facilitates a conformational transition in the guanine nucleotide exchange factor complex DOCK5/ELMO1 to an open state

Small GTPase signaling hubs at the surface of cellular membranes in physiology and disease

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