Project description:Mutations in LZTR1, a substrate adaptor for cullin 3 (CUL3) ubiquitin ligase complexes1, have been recently associated with Noonan syndrome2,3 and familial Schwannomatosis4-6. Concordantly, we found that Lztr1+/- mice showed craniofacial abnormalities, cardio defects, and premature ageing; whereas loss of LZTR1 in Schwann cells drives their dedifferentiation into proliferating, pro-myelinating cells. We screened for LZTR1 substrates by trapping LZTR1 complexes from intact mammalian cells. In parallel, we analysed changes in the ubiquitin landscape induced by LZTR1 loss of function. RAS proteins emerged as substrates of the LZTR1/CUL3 complex, which inhibits the RAS pathway by ubiquitinating RAS at K170 and triggering its dissociation from the membrane. Disease-associated LZTR1 mutations affect either the LZTR1/CUL3 complex formation, or the interaction with RAS proteins. These results position LZTR1 as a key node in the RAS pathway, loss-of-function of which leads to a human disease.

Project description:Recently, screens for mediators of resistance to FLT3 and ABL kinase inhibitors in leukemia resulted in the discovery of LZTR1 as an adaptor of a Cullin-3 RING E3 ubiquitin ligase complex responsible for degradation of RAS GTPases. In parallel, dysregulated LZTR1 expression via aberrant splicing and mutations have been identified in clonal hematopoietic conditions. Here we identify that loss of LZTR1, or leukemia-associated mutants in the LZTR1 substrate and RAS GTPase RIT1 which escape degradation, drive hematopoietic stem cell expansion (HSC) and leukemia in vivo. LZTR1 null cells rely on multiple RAS GTPases for transformation. Consequently, RAS targeting bioPROTACs or reduction of GTP-loaded RAS overcomes LZTR1 loss-mediated resistance to FLT3 inhibitors. These data thereby reveal proteolysis of non-canonical RAS proteins as novel regulators of HSC function, define the function and spectrum of RIT1 and LZTR1 mutations in leukemia, and identify means to overcome drug resistance due to LZTR1 downregulation.

Project description:Recently, screens for mediators of resistance to FLT3 and ABL kinase inhibitors in leukemia resulted in the discovery of LZTR1 as an adaptor of a Cullin-3 RING E3 ubiquitin ligase complex responsible for degradation of RAS GTPases. In parallel, dysregulated LZTR1 expression via aberrant splicing and mutations have been identified in clonal hematopoietic conditions. Here we identify that loss of LZTR1, or leukemia-associated mutants in the LZTR1 substrate and RAS GTPase RIT1 which escape degradation, drive hematopoietic stem cell expansion (HSC) and leukemia in vivo. LZTR1 null cells rely on multiple RAS GTPases for transformation. Consequently, RAS targeting bioPROTACs or reduction of GTP-loaded RAS overcomes LZTR1 loss-mediated resistance to FLT3 inhibitors. These data thereby reveal proteolysis of non-canonical RAS proteins as novel regulators of HSC function, define the function and spectrum of RIT1 and LZTR1 mutations in leukemia, and identify means to overcome drug resistance due to LZTR1 downregulation.

Project description:Mutations in LZTR1, a substrate adaptor for cullin 3 (CUL3) ubiquitin ligase complexes, have been recently associated with Noonan syndrome and familial Schwannomatosis. Concordantly, we found that Lztr1+/- mice showed craniofacial abnormalities, cardio defects, and premature ageing; whereas loss of LZTR1 in Schwann cells drives their dedifferentiation into proliferating, pro-myelinating cells. In the present dataset we screened for changes in the ubiquitin landscape induced by LZTR1 loss of function by mass spectrometry-based proteomics and identified RAS proteins as substrates of the LZTR1/CUL3 complex. In follow-up experiments we showed that LZTR1/CUL3 inhibits the RAS pathway by ubiquitinating RAS at K170 and triggering its dissociation from the membrane. Disease-associated LZTR1 mutations affect either the LZTR1/CUL3 complex formation, or the interaction with RAS proteins. Together, our results position LZTR1 as a key node in the RAS pathway, loss-of-function of which leads to human disease.

Project description:Most metazoans contain two distinct pre-mRNA splicing machineries: the major spliceosome, which removes >99% of introns, and the minor spliceosome, which recognizes <1% of introns. Despite their rarity, minor introns are exquisitely conserved amongst species, suggesting important regulatory functions. However, physiologic roles for the minor spliceosome and the relevance of recurrent, leukemia-associated mutations affecting minor spliceosome components are not well understood. Here, we identify that mutational loss of the minor spliceosomal factor ZRSR2 enhances hematopoietic stem cell self-renewal via impaired minor intron splicing that converges on LZTR1, a regulator of Ras-related GTPases. LZTR1 minor intron retention is additionally observed in Noonan syndrome and diverse cancers. These data uncover minor intron recognition as a regulator of hematopoiesis and mechanistic links between ZRSR2 mutations, LZTR1, and leukemia.

Project description:Acral melanoma, the most common melanoma subtype among non-Caucasian individuals, is associated with poor prognosis. However, its key molecular drivers remain obscure. Here, we perform integrative genomic and clinical profiling of acral melanomas from a cohort of 104 patients treated in North America or China. We find that recurrent, late-arising amplifications of cytoband chr22q11.21 are a leading determinant of inferior survival, strongly associated with metastasis, and linked to downregulation of immunomodulatory genes associated with response to immune checkpoint blockade. Unexpectedly, LZTR1 – a known tumor suppressor in other cancers – is a key candidate oncogene in this cytoband. Silencing of LZTR1 in melanoma cell lines caused apoptotic cell death independent of major hotspot mutations or melanoma subtypes. Conversely, overexpression of LZTR1 in normal human melanocytes initiated processes associated with metastasis, including anchorage-independent growth, formation of spheroids, and increased levels of MAPK and SRC activities. Our results provide insights into the etiology of acral melanoma and implicate LZTR1 as a key tumor promoter and therapeutic target.

Project description:Acral melanoma, the most common melanoma subtype among non-Caucasian individuals, is associated with poor prognosis. However, its key molecular drivers remain obscure. Here, we performed integrative genomic and clinical profiling of acral melanomas from a cohort of 104 patients treated in North America or China. We found that recurrent, late-arising amplifications of cytoband chr22q11.21 are a leading determinant of inferior survival, strongly associated with metastasis, and linked to downregulation of immunomodulatory genes associated with response to immune checkpoint blockade. Unexpectedly, LZTR1 – a known tumor suppressor in other cancers – is a key candidate oncogene in this cytoband. Silencing of LZTR1 in melanoma cell lines caused apoptotic cell death independent of major hotspot mutations or melanoma subtypes. Conversely, overexpression of LZTR1 in normal human melanocytes initiated processes associated with metastasis, including anchorage-independent growth, formation of spheroids, and increased levels of MAPK and SRC activities. Our results provide new insights into the etiology of acral melanoma and implicate LZTR1 as a key tumor promoter and therapeutic target. Keywords: Expression profiling by high throughput sequencing

Project description:Alterations of serine/threonine phosphorylation of the cardiac proteome are a hallmark of heart failure. However, the contribution of tyrosine phosphorylation (pTyr) to the pathogenesis of cardiac hypertrophy remains unclear. We use global mapping to discover and quantify site-specific pTyr in two cardiac hypertrophic mouse models, i.e., cardiac overexpression of ErbB2 (TgErbB2) and myosin heavy chain R403Q (R403Q-aMyHC Tg), compared to control hearts. From this, there are significant phosphoproteomic alterations in TgErbB2 mice in right ventricular cardiomyopathy, hypertrophic cardiomyopathy (HCM), and dilated cardiomyopathy (DCM) pathways. On the other hand, R403Q-aMyHC Tg mice indicated that the EGFR1 pathway is central for cardiac hypertrophy, along with angiopoietin, ErbB, growth hormone, and chemokine signaling pathways activation. Surprisingly, most myofilament proteins have downregulation of pTyr rather than upregulation. Kinase-substrate enrichment analysis (KSEA) shows a marked downregulation of MAPK pathway activity downstream of k-Ras in TgErbB2 mice and activation of EGFR, focal adhesion, PDGFR, and actin cytoskeleton pathways. In vivo ErbB2 inhibition by AG-825 decreases cardiomyocyte disarray. Serine/threonine and tyrosine phosphoproteome confirms the above-described pathways and the effectiveness of AG-825 treatment. Thus, altered pTyr may play a regulatory role in cardiac hypertrophic models.

Project description:Most eukaryotes harbor two distinct pre-mRNA splicing machineries: the major spliceosome, which removes >99% of introns, and the minor spliceosome, which removes rare, evolutionarily conserved introns. Although hypothesized to serve important regulatory functions, physiologic roles for the minor spliceosome are not well understood. For example, the minor spliceosome component ZRSR2 is subject to recurrent, leukemia-associated mutations, yet functional connections between minor introns, hematopoiesis, and cancers are unclear. Here, we identify that impaired minor intron excision via ZRSR2 loss enhances hematopoietic stem cell self-renewal. CRISPR screens mimicking nonsense-mediated decay of minor intron-containing mRNAs converged on LZTR1, a regulator of Ras-related GTPases. LZTR1 minor intron retention was also discovered in the RASopathy Noonan syndrome, due to intronic mutations disrupting splicing, and diverse solid tumors. These data uncover minor intron recognition as a regulator of hematopoiesis, noncoding mutations within minor introns as cancer drivers, and links between ZRSR2 mutations, LZTR1 regulation, and leukemias.

Project description:Basal cell carcinoma may undergo BST spontaneously or upon Hedgehog targeting therapy. We identified that modulation of Ras/MAPK or TGFb signaling drive BST. Here, we induce Ras/MAPK and/or abrogate TGFb signaling to induce BST. Alternatively we drive c-FOS to induce BST. Here, we analyze transcriptional profiles upon Ras/MAPK activation and/or TGFb signaling abrogation.