f Cell migration is a fundamental biological function, critical during development and regeneration, whereas deregulated migration underlies neurological birth defects and cancer metastasis. MARCKS-like protein 1 (MARCKSL1) is widely expressed in nervous tissue, where, like Jun N-terminal protein kinase (JNK), it is required for neural tube formation, though the mechanism is unknown. Here we show that MARCKSL1 is directly phosphorylated by JNK on C-terminal residues (S120, T148, and T183). This phosphorylation enables MARCKSL1 to bundle and stabilize F-actin, increase filopodium numbers and dynamics, and retard migration in neurons. Conversely, when MARCKSL1 phosphorylation is inhibited, actin mobility increases and filopodium formation is compromised whereas lamellipodium formation is enhanced, as is cell migration. We find that MARCKSL1 mRNA is upregulated in a broad range of cancer types and that MARCKSL1 protein is strongly induced in primary prostate carcinomas. Gene knockdown in prostate cancer cells or in neurons reveals a critical role for MARCKSL1 in migration that is dependent on the phosphorylation state; phosphomimetic MARCKSL1 (MARCKSL1 S120D,T148D,T183D ) inhibits whereas dephospho-MARCKSL1 S120A,T148A,T183A induces migration. In summary, these data show that JNK phosphorylation of MARCKSL1 regulates actin homeostasis, filopodium and lamellipodium formation, and neuronal migration under physiological conditions and that, when ectopically expressed in prostate cancer cells, MARCKSL1 again determines cell movement. M ARCKS-like protein 1 (MARCKSL1) is an actin binding protein that is predominantly expressed in immature brain (1, 27). The MARCKSL1 homologue MARCKS has been more extensively studied and has been shown to bind actin with a stoichiometry of 1:2, thereby facilitating cross-linking (56; reviewed in reference 39). Binding to actin occurs via an effector domain (ED) that is 87% identical to the corresponding domain of MARCKSL1. Surprisingly, however, full-length MARCKSL1 does not cross-link F-actin (49; reviewed in reference 39), although the MARCKSL1 effector domain alone interacts with actin. This indicates that in a physiological context, another level of regulation is required for MARCKSL1 to regulate actin bundling. The only known critical function of MARCKSL1 is in early development of the nervous system, as genetic disruption of MARCKSL1 results in neural tube closure defects (5, 51), events that depend on coordinated control of actin functions, cell shape, and cell migration. MARCKSL1 is also associated with cell spreading (23); however, the mechanism whereby MARCKSL1 regulates F-actin in a cellular context has remained obscure.c-Jun N-terminal kinase 1 (JNK1) and JNK2, like MARCKSL1, are required for neural tube closure (20,36). However, the identity of the JNK effectors mediating this event remains unresolved. JNK activity is highly elevated in neuronal cells (8,42), and although initially unexpected (7,8,53), it is now accepted that a number of important physiological substrates fo...
