Comprehensive Study of Human FBXW7 Deleterious nsSNP's Functional Inference and Susceptibility to Gynaecological Cancer

Cancer is one of the world's major causes of mortality, and it plays a most important role in the world's declining life expectancy. F-box and WD-40 domain protein 7 (FBXW7), a typical participant of the F-box family of proteins, has been considered as an antitumor protein and one of the maximum deregulated ubiquitin-proteasome system proteins in uterine carcinosarcoma, endometrial clear cell carcinoma and cervical carcinoma with the greatest prevalence of alterations. FBXW7 variants with known clinical significance, as well as nsSNP’s in the F-Box and WD40 domains, were evaluated using functionality prediction web resources. Upon analysing the seventy-three deleterious nsSNP’s impact on protein stability and function, we identified that forty-one nsSNP’s of WD40 domain and three of F-Box domain imply decreased stability of the FBXW7 structure. Next to TP53 and PTEN, FBXW7 was reported with the highest percentage of arginine substitution among mutations related to cancer. The current research concentrated on two arginine residue locations (Arg465, Arg505) within the WD40-repeat domain, which is vital for substrate binding. Computational analysis revealed that significant deviation in stability and structural configuration of mutants R505L, R465H, R465P, R505G, R505C, R465C R505S and R505L structures. Protein–protein interaction network of FBXW7 populated with promising hub proteins NOTCH1, c-Myc, CCNE1, STYX, KLG5, SREB1, NFKB2, SKP1, CUL1, thus alteration in the FBXW7 leads to aberration in their signalling pathways as well as their substrate binding ability makes this protein as attractive target for personalized therapeutic intervention.

Two helices control the dynamic crosstalk between the catalytic domains of LRRK2

The two major molecular switches in biology, kinases and GTPases, are both contained in the Parkinson’s Disease-related Leucine-rich repeat kinase 2 (LRRK2). Using hydrogen-deuterium exchange mass spectrometry (HDX-MS) and Molecular Dynamics (MD) simulations, we generated a comprehensive dynamic allosteric portrait of the C-terminal domains of LRRK2 (LRRK2 RCKW). We identified two helices that shield the kinase domain and regulate LRRK2 conformation and function. One docking helix in COR-B (Dk-Helix) tethers the COR-B domain to the αC helix of the kinase domain and faces its Activation Loop, while the C-terminal helix (Ct-Helix) extends from the WD40 domain and interacts with both kinase lobes. The Ct-Helix and the N-terminus of the Dk-Helix create a “cap” that regulates the N-Lobe of the kinase domain. Our analyses reveal allosteric sites for pharmacological intervention and confirm the kinase domain as the central hub for conformational control.

Exploring the genes involved in biosynthesis of dihydroquercetin and dihydromyricetin in Ampelopsis grossedentata

Dihydroquercetin (DHQ), an extremely low content compound (less than 3%) in plants, is an important component of dietary supplements and used as functional food for its antioxidant activity. Moreover, as downstream metabolites of DHQ, an extremely high content of dihydromyricetin (DHM) is up to 38.5% in Ampelopsis grossedentata. However, the mechanisms involved in the biosynthesis and regulation from DHQ to DHM in A. grossedentata remain unclear. In this study, a comparative transcriptome analysis of A. grossedentata containing extreme amounts of DHM was performed on the Illumina HiSeq 2000 sequencing platform. A total of 167,415,597 high-quality clean reads were obtained and assembled into 100,584 unigenes having an N50 value of 1489. Among these contigs, 57,016 (56.68%) were successfully annotated in seven public protein databases. From the differentially expressed gene (DEG) analysis, 926 DEGs were identified between the B group (low DHM: 210.31 mg/g) and D group (high DHM: 359.12 mg/g) libraries, including 446 up-regulated genes and 480 down-regulated genes (B vs. D). Flavonoids (DHQ, DHM)-related DEGs of ten structural enzyme genes, three myeloblastosis transcription factors (MYB TFs), one basic helix–loop–helix (bHLH) TF, and one WD40 domain-containing protein were obtained. The enzyme genes comprised three PALs, two CLs, two CHSs, one F3’H, one F3’5’H (directly converts DHQ to DHM), and one ANS. The expression profiles of randomly selected genes were consistent with the RNA-seq results. Our findings thus provide comprehensive gene expression resources for revealing the molecular mechanism from DHQ to DHM in A. grossedentata. Importantly, this work will spur further genetic studies about A. grossedentata and may eventually lead to genetic improvements of the DHQ content in this plant.

RBV, an evolutionarily conserved WD40 repeat protein, promotes microRNA biogenesis and loading into ARGONAUTE1 in Arabidopsis

MicroRNAs (miRNAs) play crucial roles in gene expression regulation through RNA cleavage or translation repression. Although miRNA biogenesis has been extensively studied, new factors involved in miRNA biogenesis are still being found from various genetic screens, suggesting that knowledge of miRNA biogenesis or its regulation is still incomplete. Here, we report the identification of a previously uncharacterized and evolutionarily conserved WD40 domain protein as a player in miRNA biogenesis in Arabidopsis thaliana. A mutation in the REDUCTION IN BLEACHED VEIN AREA (RBV) gene encoding a WD40 domain protein led to the suppression of leaf bleaching caused by an artificial miRNA; the mutation also led to a global reduction in the accumulation of endogenous miRNAs. RBV may act at multiple steps in miRNA biogenesis. RBV promotes the transcription of MIR genes into pri-miRNAs by enhancing the occupancy of RNA polymerase II (Pol II) at MIR gene promoters. The nuclear protein RBV may also participate in pri-miRNA processing, as the mutation of RBV leads to the reduction of dicing body number. Moreover, mutation of RBV leads to a defect of miRNA loading into AGO1.RBV function is required in messenger RNA splicing, as RNA-seq uncovered a global intron retention defect in the mutant. Thus, this previously uncharacterized, evolutionarily conserved, nuclear WD40 domain protein acts in miRNA biogenesis and RNA splicing.

V-ATPase is a universal regulator of LC3 associated phagocytosis and non-canonical autophagy

Non-canonical autophagy is a key cellular pathway in immunity, cancer and neurodegeneration, characterised by Conjugation of ATG8 to endolysosomal Single-Membranes (CASM). CASM is activated by engulfment (endocytosis, phagocytosis), agonists (STING, TRPML1) and infection (influenza), dependent on the ATG16L1 WD40-domain, and specifically K490. However, the factor(s) associated with non-canonical ATG16L1 recruitment, and CASM induction, remain unknown. Here, we investigate a role for V-ATPase during non-canonical autophagy. We report that increased V0-V1 engagement is associated with, and sufficient for, CASM activation. Upon V0-V1 binding, V-ATPase directly recruits ATG16L1, via K490, during LC3-associated phagocytosis (LAP), STING- and drug-induced CASM, indicating a common mechanism. Furthermore, during LAP, key molecular players, including NADPH oxidase/ROS, converge on V-ATPase. Finally, we show that LAP is sensitive to Salmonella SopF, which disrupts the V-ATPase-ATG16L1 axis, and provide evidence that CASM contributes to the Salmonella host response. Together, these data identify V-ATPase as a universal regulator of CASM, and indicate that SopF evolved in part to evade non-canonical autophagy.

MO049FUNCTIONAL IMPORTANCE OF MAPKBP1 PROTEIN DOMAINS IN NEPHRONOPHTHISIS

Background and Aims Nephronophthisis is an autosomal-recessive kidney disease that accounts for a significant proportion of end-stage renal disease (ESRD) in childhood, adolescence and early adulthood. Biallelic pathogenic variants in MAPKBP1, encoding the c-Jun N-terminale kinase (JNK)-binding protein 1, are associated with development of Nephronophthisis and subsequent chronic kidney disease (CKD) (Macia et al, AJHG, 2017). We recently characterized MAPKBP1 as microtubule-associated protein that is able to localize to centrioles and the base of primary cilia depending on dimerization via its C-terminal coiled-coil domain (Schönauer et al, Kidney Int, 2020). However, the physiological function of its N-terminal WD40 and intermediate JNK-binding domain is still poorly understood. By in vitro comparison of artificial domain deletions with known and novel patient variants, we aim at pinpointing functional consequences of pathogenic MAPKBP1 in cilia and cell cycle control. Method N-terminally GFP-tagged MAPKBP1 constructs with either full-domain deletions or patient-derived variants were expressed in non-ciliated HeLa and ciliated H69 cells for fluorescence microscopy studies. Furthermore, RNA-seq analysis using primary patient cells was conducted to investigate differentially regulated molecular pathways compared to healthy control individuals. Results Immunofluorescence microscopy revealed inappropriate intracellular localization upon single or combined deletion of any MAPKBP1 protein domain. Compared to wild type, all deletion variants showed reduced intensity at the centrosome and ciliary base. Despite preserved dimerization ability, loss of the intermediate JNK-binding domain (JBD) most effectively abolished centrosomal or ciliary targeting, whereas loss of the N-terminal WD40-domain induced strongest mitotic aberrations. Unlike wild type, both, artificial and patient-derived truncating variants were able to enter the nucleus. RNA-seq analysis using primary patient fibroblasts with varying C-terminal truncations will allow important insights into common gene expression profiles unveiling consequences of aberrant intracellular trafficking. Conclusion In the present work, we demonstrate that all protein domains are indispensable for appropriate MAPKBP1 intracellular localization and function. Most of clinically reported patient variants exhibiting C-terminal truncation of varying lengths resulted in comparable intracellular behavior in presence of an intact N-terminal WD40 domain. Surprisingly, deletion of the JNK-binding domain alone aggravated functional disturbances hinting at a prominent regulatory role of this protein part interdepending with dimerization. Further insights into domain-specific functions will explain molecular disease mechanisms of MAPKBP1.

Non-TZF Protein AtC3H59/ZFWD3 Is Involved in Seed Germination, Seedling Development, and Seed Development, Interacting with PPPDE Family Protein Desi1 in Arabidopsis

Despite increasing reports on the function of CCCH zinc finger proteins in plant development and stress response, the functions and molecular aspects of many non-tandem CCCH zinc finger (non-TZF) proteins remain uncharacterized. AtC3H59/ZFWD3 is an Arabidopsis non-TZF protein and belongs to the ZFWD subfamily harboring a CCCH zinc finger motif and a WD40 domain. In this study, we characterized the biological and molecular functions of AtC3H59, which is subcellularly localized in the nucleus. The seeds of AtC3H59-overexpressing transgenic plants (OXs) germinated faster than those of wild type (WT), whereas atc3h59 mutant seeds germinated slower than WT seeds. AtC3H59 OX seedlings were larger and heavier than WT seedlings, whereas atc3h59 mutant seedlings were smaller and lighter than WT seedlings. Moreover, AtC3H59 OX seedlings had longer primary root length than WT seedlings, whereas atc3h59 mutant seedlings had shorter primary root length than WT seedlings, owing to altered cell division activity in the root meristem. During seed development, AtC3H59 OXs formed larger and heavier seeds than WT. Using yeast two-hybrid screening, we isolated Desi1, a PPPDE family protein, as an interacting partner of AtC3H59. AtC3H59 and Desi1 interacted via their WD40 domain and C-terminal region, respectively, in the nucleus. Taken together, our results indicate that AtC3H59 has pleiotropic effects on seed germination, seedling development, and seed development, and interacts with Desi1 in the nucleus via its entire WD40 domain. To our knowledge, this is the first report to describe the biological functions of the ZFWD protein and Desi1 in Arabidopsis.