Alex W. Wilkinson scite author profile

Deregulation in lysine methylation signaling has emerged as a common etiologic factor in cancer pathogenesis, with inhibitors of several histone lysine methyltransferases (KMTs) being developed as chemotherapeutics1. The largely cytoplasmic KMT SMYD3 (SET and MYND domain containing protein 3) is overexpressed in numerous human tumors2-4. However, the molecular mechanism by which SMYD3 regulates cancer pathways and its relationship to tumorigenesis in vivo are largely unknown. Here we show that methylation of MAP3K2 by SMYD3 increases MAP Kinase signaling and promotes the formation of Ras-driven carcinomas. Using mouse models for pancreatic ductal adenocarcinoma (PDAC) and lung adenocarcinoma (LAC), we found that abrogating SMYD3 catalytic activity inhibits tumor development in response to oncogenic Ras. We employed protein array technology to identify the MAP3K2 kinase as a target of SMYD3. In cancer cell lines, SMYD3-mediated methylation of MAP3K2 at lysine 260 potentiates activation of the Ras/Raf/MEK/ERK signaling module. Finally, the PP2A phosphatase complex, a key negative regulator of the MAP Kinase pathway, binds to MAP3K2 and this interaction is blocked by methylation. Together, our results elucidate a new role for lysine methylation in integrating cytoplasmic kinase-signaling cascades and establish a pivotal role for SMYD3 in the regulation of oncogenic Ras signaling.

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A molecular wound response program associated with regeneration initiation in planarians

Wenemoser¹,

Lapan²,

Wilkinson³

et al. 2012

Genes Dev.

234

347

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Planarians are capable of regenerating any missing body part and present an attractive system for molecular investigation of regeneration initiation. The gene activation program that occurs at planarian wounds to coordinate regenerative responses remains unknown. We identified a large set of wound-induced genes during regeneration initiation in planarians. Two waves of wound-induced gene expression occurred in differentiated tissues. The first wave includes conserved immediate early genes. Many second-wave genes encode conserved patterning factors required for proper regeneration. Genes of both classes were generally induced by wounding, indicating that a common initial gene expression program is triggered regardless of missing tissue identity. Planarian regeneration uses a population of regenerative cells (neoblasts), including pluripotent stem cells. A class of wound-induced genes was activated directly within neoblasts, including the Runx transcription factor-encoding runt-1 gene. runt-1 was required for specifying different cell types during regeneration, promoting heterogeneity in neoblasts near wounds. Wound-induced gene expression in neoblasts, including that of runt-1, required SRF (serum response factor) and sos-1. Taken together, these data connect wound sensation to the activation of specific cell type regeneration programs in neoblasts. Most planarian wound-induced genes are conserved across metazoans, and identified genes and mechanisms should be important broadly for understanding wound signaling and regeneration initiation.

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SETD3 is an actin histidine methyltransferase that prevents primary dystocia

Wilkinson

Diep

Dai

et al. 2018

Nature

135

249

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For over fifty years, the methylation of mammalian actin at histidine 73 (actin-H73me) has been known to exist 1 . Beyond mammals, we find that actin-H73me is conserved in several additional model animal and plant organisms. Despite the pervasiveness of H73me, its function is enigmatic, and the enzyme generating this modification is unknown. Here, we identify SETD3 ( SET d omain protein 3 ) as the physiologic actin histidine 73 methyltransferase. Structural studies reveal that an extensive network of interactions clamps the actin peptide on the SETD3 surface to properly orient H73 within the catalytic pocket and facilitate methyl transfer. H73me reduces the nucleotide exchange rate on actin monomers and modestly accelerates actin filament assembly. Mice lacking SETD3 show complete loss of actin-H73me in multiple tissues and quantitative proteomics singles out actin-H73 as the principal physiologic SETD3 substrate. SETD3 deficient female mice have severely decreased litter sizes due to primary maternal dystocia that is refractory to ecbolic induction agents. Further, depletion of SETD3 impairs signal-induced contraction in primary human uterine smooth muscle cells. Together, our results identify the first mammalian protein histidine methyltransferase and uncover a pivotal role for SETD3 and actin-H73me in the regulation of smooth muscle contractility. Our data also support the broader hypothesis where protein histidine methylation acts as a common regulatory mechanism.

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Molecular and Neural Functions of Rai1 , the Causal Gene for Smith-Magenis Syndrome

Huang

Guenthner

et al. 2016

Neuron

110

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SUMMARY Haploinsufficiency of Retinoic Acid Induced 1 (RAI1) causes Smith-Magenis syndrome (SMS), which is associated with diverse neurodevelopmental and behavioral symptoms as well as obesity. RAI1 encodes a nuclear protein but little is known about its molecular function or the cell types responsible for SMS symptoms. Using genetically engineered mice, we found that Rai1 preferentially occupies DNA regions near active promoters and promotes the expression of a group of genes involved in circuit assembly and neuronal communication. Behavioral analyses demonstrated that pan-neural loss of Rai1 causes deficits in motor function, learning, and food intake. These SMS-like phenotypes are produced by loss of Rai1 function in distinct neuronal types: Rai1 loss in inhibitory neurons or subcortical glutamatergic neurons causes learning deficits, while Rai1 loss in Sim1+ or SF1+ cells causes obesity. By integrating molecular and organismal analyses, our study suggests potential therapeutic avenues for a complex neurodevelopmental disorder.

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The Zn Finger protein Iguana impacts Hedgehog signaling by promoting ciliogenesis

Glazer

Wilkinson

Backer

et al. 2010

Developmental Biology

109

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Hedgehog signaling is critical for metazoan development and requires cilia for pathway activity. The gene iguana was discovered in zebrafish as required for Hedgehog signaling, and encodes a novel Zn finger protein. Planarians are flatworms with robust regenerative capacities and utilize epidermal cilia for locomotion. RNA interference of Smed-iguana in the planarian Schmidtea mediterranea caused cilia loss and failure to regenerate new cilia, but did not cause defects similar to those observed in hedgehog(RNAi) animals. Smed-iguana gene expression was also similar in pattern to the expression of multiple other ciliogenesis genes, but was not required for expression of these ciliogenesis genes. iguana-defective zebrafish had too few motile cilia in pronephric ducts and in Kupffer's vesicle. Kupffer's vesicle promotes left-right asymmetry and iguana mutant embryos had left-right asymmetry defects. Finally, human Iguana proteins (dZIP1 and dZIP1L) localize to the basal bodies of primary cilia and, together, are required for primary cilia formation. Our results indicate that a critical and broadly conserved function for Iguana is in ciliogenesis and that this function has come to be required for Hedgehog signaling in vertebrates.

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Alex W. Wilkinson

SMYD3 links lysine methylation of MAP3K2 to Ras-driven cancer

A molecular wound response program associated with regeneration initiation in planarians

SETD3 is an actin histidine methyltransferase that prevents primary dystocia

Molecular and Neural Functions of Rai1 , the Causal Gene for Smith-Magenis Syndrome

The Zn Finger protein Iguana impacts Hedgehog signaling by promoting ciliogenesis

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