Project description:af01_cul3a2_cul3b - comparison ws vs crb (cul3a) - Cullin proteins belong to a multigene family that includes at least three members in budding yeast, six in human, five in C. elegans and five in Arabidopsis thaliana. All cullins analyzed so far directly interact with RBX1/HRT1/ROC1, a RING finger protein, thereby forming the core module of different ubiquitin ligase complexes, which specifically recruit substrate proteins for ubiquitylation and subsequent degradation by the proteasome. CULLIN1, the only cullin protein studied so far in plants, has been shown to be essential for plant development and to play a role in multiple signalling cascades. Here, we report on the first molecular and genetic characterisation of a plant Cullin 3. In contrast to fungi and animals, the genome of the model plant Arabidopsis thaliana contains two related CULLIN 3 genes, called CUL3A and CUL3B. We found that CUL3A is ubiquitously expressed in plants and that the CUL3A protein is also able to interact with RBX1 and certain Arabidopsis BTB-domain proteins. In order to determine the role of CUL3A in plant development, we used a reverse genetic approach and identified T-DNA insertion mutants. cul3a null mutants flower slightly latter than the control plants and their hypocotyls exhibit a reduced sensitivity to far red light. The viability of the cul3a mutant plants suggests functional redundancy between both CUL3 genes in plants. - Comparaison of mutant AtCul3a (T-DNA mutant of Versailles collection) and WS. Keywords: wt vs mutant comparison

Project description:af01_cul3a2_cul3b - comparison col0 vs 003d - Cullin proteins belong to a multigene family that includes at least three members in budding yeast, six in human, five in C. elegans and five in Arabidopsis thaliana. All cullins analyzed so far directly interact with RBX1/HRT1/ROC1, a RING finger protein, thereby forming the core module of different ubiquitin ligase complexes, which specifically recruit substrate proteins for ubiquitylation and subsequent degradation by the proteasome. CULLIN1, the only cullin protein studied so far in plants, has been shown to be essential for plant development and to play a role in multiple signalling cascades. Here, we report on the first molecular and genetic characterisation of a plant Cullin 3. In contrast to fungi and animals, the genome of the model plant Arabidopsis thaliana contains two related CULLIN 3 genes, called CUL3A and CUL3B. We found that CUL3A is ubiquitously expressed in plants and that the CUL3A protein is also able to interact with RBX1 and certain Arabidopsis BTB-domain proteins. In order to determine the role of CUL3A in plant development, we used a reverse genetic approach and identified T-DNA insertion mutants. cul3a null mutants flower slightly latter than the control plants and their hypocotyls exhibit a reduced sensitivity to far red light. The viability of the cul3a mutant plants suggests functional redundancy between both CUL3 genes in plants. - Comparaison of AtCul3b (mutant of Gabi collection) and Col0. Keywords: wt vs mutant comparison

Project description:We identified Rho Related BTB Domain Containing 1 (RhoBTB1) as a key regulator of phosphodiesterase 5 (PDE5) activity, and through PDE5, a regulator of vascular tone. We identified the binding interface for PDE5 on RhoBTB1 by truncating full-length RhoBTB1 into its component domains. Co-immunoprecipitation analyses revealed that the C-terminal half of RhoBTB1 containing its two BTB domains and the C-terminal domain (B1B2C) is the minimal region required for PDE5 recruitment and subsequent proteasomal degradation via the Cullin-3 (CUL3). The C-terminal domain was essential in recruiting PDE5 as constructs lacking this region could not participate in PDE5 binding or proteasomal degradation. We also identified Pro353 and Ser363 as key amino acid residues in the B1B2C region involved in CUL3 binding to RhoBTB1. Mutation of either of these residues exhibited impaired CUL3 binding and PDE5 degradation, although the binding to PDE5 was preserved. Finally, we employed ascorbate peroxidase 2 (APEX2) proximity labeling using a B1B2C-APEX2 fusion protein as bait to capture unknown RhoBTB1 binding partners. Among several B1B2C-binding proteins identified and validated, we focused on SET Domain Containing 2 (SETD2). SETD2 and RhoBTB1 directly interacted, and the level of SETD2 increased in response to pharmacological inhibition of the proteasome or Cullin complex, CUL3 deletion, and RhoBTB1-inhibition with siRNA. This suggests that SETD2 is regulated by the RhoBTB1-CUL3 axis. Future studies will determine if SETD2 plays a role in cardiovascular function.

Project description:E3-ubiquitin ligase Cullin3 (Cul3) is a high confidence risk gene for Neurodevelopmental Disorders such as Autism Spectrum Disorder (ASD) and Developmental Delay (DD). This study identifies the impact of the ASD-associated de novo Cul3-mutation on brain anatomy, behavior, molecular, cellular, and circuit-level mechanisms during early neocortical development. We report that Cul3 mutant mice have microcephaly and severe brain structure defects. This mouse model exhibits social and cognitive deficits and hyperactivity behavior. Spatiotemporal transcriptomic and proteomic profiling of Cul3 mouse brain implicates neurogenesis and cytoskeletal defects as key drivers of Cul3 functional effect. We show that Cul3 is critical for neuron growth and development. Cultured cortical neurons from the mutant mice have reduced dendritic length, actin cytosketon defects, reduced network activity, and increased cell death. At the molecular level, we implicate upregulation of small GTPase RhoA, involved in regulation of cytoskeletal dynamics, and neurite outgrowth as one of the pathways impacted by the de novo Cul3 mutations in ASD. Treatment with small molecule RhoA inhibitor Rhosin rescues dendrite length phenotype and implicates RhoA pathway in ASD.

Project description:ARMC5 is a protein containing an armadillo domain (ARM) and a BTB domain. Its gene knockout caused many phenotypes, including dwarfism, compromise T-cell immunity, and adrenal gland hypertrophy. ARMC5 mutation in humans is associated with bilateral macronodular adrenal gland hypertrophy. We found that AMC5 KO mice suffered from an increased incidence of neural tube defects (NTDs). We revealed that ARMC5 complexed with CUL3 and POLR2A and was part of a novel POLR2A-specific ubiquitin ligase (E3). This E3 was the dominant DNA damage-independent POLR2A-specific E3 in developing neural tubes and neural precursor cells under a physiological condition. ARMC5 gene knockout (KO) caused diminished POLR2A ubiquitination and compromised POLR2A degradation via proteasomes. Surprisingly, the absence of this E3 did not lead to generalized Pol II stalling and the subsequent generalized decrease of mRNA transcription but caused an enlarged Pol II pool size, which dysregulated 108 genes in NPCs, including some known to neural development. ARMC5 KO in the intestine downregulated FOHL1 expression, which was essential in folate absorption. Whole-exome sequencing of 511 myelomeningocele (MM) patients revealed nine highly deleterious mutations in the ARMC5 coding sequence. A significant deleterious mutation Arg429Cys found in MM patients drastically weakened the interaction between ARMC5 and POLR2A, supporting our hypothesis that such mutations in ARMC5 increased the NTD risks by compromising the POLR2A-specific E3 activity. Our results indicated that this novel ARMC5-CUL3-RBX1 E3 played a critical role in Pol II pool homeostasis, and ARMC5 mutation was a modifier of NTD risks in mice and humans.

Project description:ARMC5 is a protein containing an armadillo domain (ARM) and a BTB domain. Its gene knockout caused many phenotypes, including dwarfism, compromise T-cell immunity, and adrenal gland hypertrophy. ARMC5 mutation in humans is associated with bilateral macronodular adrenal gland hypertrophy. We found that AMC5 KO mice suffered from an increased incidence of neural tube defects (NTDs). We revealed that ARMC5 complexed with CUL3 and POLR2A and was part of a novel POLR2A-specific ubiquitin ligase (E3). This E3 was the dominant DNA damage-independent POLR2A-specific E3 in developing neural tubes and neural precursor cells under a physiological condition. ARMC5 gene knockout (KO) caused diminished POLR2A ubiquitination and compromised POLR2A degradation via proteasomes. Surprisingly, the absence of this E3 did not lead to generalized Pol II stalling and the subsequent generalized decrease of mRNA transcription but caused an enlarged Pol II pool size, which dysregulated 108 genes in NPCs, including some known to neural development. ARMC5 KO in the intestine downregulated FOHL1 expression, which was essential in folate absorption. Whole-exome sequencing of 511 myelomeningocele (MM) patients revealed nine highly deleterious mutations in the ARMC5 coding sequence. A significant deleterious mutation Arg429Cys found in MM patients drastically weakened the interaction between ARMC5 and POLR2A, supporting our hypothesis that such mutations in ARMC5 increased the NTD risks by compromising the POLR2A-specific E3 activity. Our results indicated that this novel ARMC5-CUL3-RBX1 E3 played a critical role in Pol II pool homeostasis, and ARMC5 mutation was a modifier of NTD risks in mice and humans.

Project description:Non-small cell lung cancers (NSCLCs) harbor thousands of passenger events that hide genetic drivers. Even highly recurrent events in NSCLC, such as mutations in PTEN, EGFR, KRAS, and ALK, are only detected in, at most, 30% of patients. Thus, many unidentified low-penetrant events are causing a significant portion of lung cancers. To detect low-penetrance drivers of NSCLC a forward genetic screen was performed in mice using the Sleeping Beauty (SB) DNA transposon as a random mutagen to generate lung tumors in a Pten deficient background. SB mutations coupled with Pten deficiency were sufficient to produce lung tumors in 29% of mice. Pten deficiency alone, without SB mutations, resulted in lung tumors in 11% of mice, while the rate in control mice was ~3%. In addition, thyroid cancer and other carcinomas as well as the presence of bronchiolar and alveolar epithelialization in mice deficient for Pten were also identified. Analysis of common transposon insertion sites identified 76 candidate cancer driver genes. These genes are frequently dysregulated in human lung cancers and implicate several signaling pathways. Cullin3 (Cul3), a member of an ubiquitin ligase complex that plays a role in the oxidative stress response pathway, was identified in the screen and evidence demonstrates that Cul3 functions as a tumor suppressor HumanHT-12 v4 Expression BeadChip Kit for human A549 lung adenocarcinoma cells with CUL3, PTEN, CUL3 and PTEN or no knockdown. A549 cells were stably transfected under Puromycin or Hygromycin selection to knockdown PTEN (SA Biosystems) or CUL3 (Open Biosystems) shRNAs. RNA was extracted in triplicate from each condition and used for microarray

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: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:CUL3-mRNASeq