Project description:Assembly of the axonemal dynein motors that power ciliary motility occurs in the cytoplasm. Studies in a broad array of organisms have revealed that at least nineteen cytosolic factors are specifically required for this process. Recently, one of these factors (DNAAF3/PF22) was identified as an S-adenosylmethionine-dependent methyltransferase. Furthermore, examination of dyneins from the green alga Chlamydomonas found that axonemal dyneins are methylated at sub-stoichiometric levels on multiple sites including key Lys and Arg residues in several of the nucleotide binding domains and on the microtubule-binding region. Given the highly conserved nature of axonemal dyneins and their cytoplasmic assembly factors, one key question is whether methylation is exclusively present only in dyneins from the chlorophyte algae, or if these modifications occur more broadly throughout the motile ciliated eukaryotes. Here we take a phylo-proteomic approach and examine dynein methylation in a wide range of eukaryotic organisms bearing motile cilia. We find unambiguous evidence for methylation of axonemal dyneins in alveolates, chlorophytes, trypanosomes, and throughout most of the metazoa, including ctenophores, echinoderms, mollusks, ascidians, and vertebrates. Intriguingly, we were unable to identify a single instance of methylation on Drosophila sperm dynein even though dipterans express a Dnaaf3 ortholog, or in spermatozoids of the fern Ceratopteris which assembles inner arms but lacks both outer arm dyneins and DNAAF3. Thus, methylation is a post-translational feature of axonemal dyneins that has been broadly conserved in most eukaryotic groups suggesting the existence of a post-translational dynein code that variably modifies the function of these motors.

Project description:Assembly of the axonemal dynein motors that power ciliary motility occurs in the cytoplasm. Studies in a broad array of organisms have revealed that at least nineteen cytosolic factors are specifically required for this process. Recently, one of these factors (DNAAF3/PF22) was identified as an S-adenosylmethionine-dependent methyltransferase. Furthermore, examination of dyneins from the green alga Chlamydomonas found that axonemal dyneins are methylated at sub-stoichiometric levels on multiple sites including key Lys and Arg residues in several of the nucleotide binding domains and on the microtubule-binding region. Given the highly conserved nature of axonemal dyneins and their cytoplasmic assembly factors, one key question is whether methylation is exclusively present only in dyneins from the chlorophyte algae, or if these modifications occur more broadly throughout the motile ciliated eukaryotes. Here we take a phylo-proteomic approach and examine dynein methylation in a wide range of eukaryotic organisms bearing motile cilia. We find unambiguous evidence for methylation of axonemal dyneins in alveolates, chlorophytes, trypanosomes, and throughout most of the metazoa, including ctenophores, echinoderms, mollusks, ascidians, and vertebrates. Intriguingly, we were unable to identify a single instance of methylation on Drosophila sperm dynein even though dipterans express a Dnaaf3 ortholog, or in spermatozoids of the fern Ceratopteris which assembles inner arms but lacks both outer arm dyneins and DNAAF3. Thus, methylation is a post-translational feature of axonemal dyneins that has been broadly conserved in most eukaryotic groups suggesting the existence of a post-translational dynein code that variably modifies the function of these motors.

Project description:Axonemal dynein motors drive ciliary motility and can consist of up to twenty distinct components with a combined mass of ~2 MDa. In mammals, failure of dyneins to assemble within the axonemal superstructure leads to primary ciliary dyskinesia. Syndromic phenotypes include infertility, rhinitis, severe bronchial conditions, and situs inversus. Nineteen specific cytosolic factors (DNAAFs) are necessary for axonemal dynein assembly although the detailed mechanisms involved remain very unclear. Here we identify the assembly factor DNAAF3 as a structural ortholog of S-adenosyl methionine-dependent methyltransferases. We further demonstrate that dynein heavy chains, especially those forming the ciliary outer arms, are methylated on key residues within various nucleotide-binding sites and on microtubule-binding domain helices directly involved in the transition to low binding affinity. These variable modifications, which are generally missing in a Chlamydomonas null mutant for the DNAAF3 ortholog PF22 (DAB1), likely impact on motor mechanochemistry fine-tuning the activities of individual dynein complexes.

Project description:Dysfunctional motile cilia result in primary ciliary dyskinesia (PCD), a genetically heterogeneous disorder characterized by chronic oto-sino-pulmonary disease, infertility, and laterality defects. Mutations in dynein axonemal assembly factors (DNAAF), that facilitate the assembly of dynein arms in the cytoplasm before transport into the cilium, cause PCD. Sperm-associated antigen 1 (SPAG1) is a DNAAF; however, SPAG1’s precise role in dynein assembly is unknown. Here, we identify a novel 60 kDa SPAG1 isoform that can partially compensate for the absence of full-length SPAG1 to assemble normal outer dynein arms, leading to phenotypic variability in PCD subjects with SPAG1 mutations. Our data shows that SPAG1 interacts with DNAAF, dynein chains, and components of the R2TP complex, and SPAG1 is necessary for axonemal dynein arm assembly by facilitating the folding and/or binding of the dynein heavy chains to the intermediate chain complex.

Project description:Dynein axonemal heavy chain 5 (DNAH5) is the most mutated gene in primary ciliary dyskinesia (PCD), leading to abnormal cilia ultrastructure and function. Few studies have revealed the genetic characteristics and pathogenetic mechanisms of PCD caused by DNAH5 mutation. Here, we established a child PCD airway organoid directly from the bronchoscopic biopsy of a patient with DNAH5 mutation. We found abnormal ciliary function and a decreased immune response caused by DNAH5 mutation through single-cell RNA sequencing (scRNA-seq).

Project description:Molecular chaperones are abundant cellular proteins that promote the folding, function and macromolecular assembly of a diverse set of substrate proteins, also known as clients. Regulation of chaperone specificity and function involves association with a growing set of distinct cofactors, or cochaperones. How these client, co-chaperone and chaperone interactions in vivo underpin the proteostasis network during development and disease remains unclear. We have combined mouse genetics, imaging and quantitative proteomics to systematically characterize a chaperone-cochaperone-client interaction network in mammalian motile ciliated cells. We uncover ZMYND10 to act as a specificity factor for the immunophilin cochaperone FKBP8 and HSP90 chaperone for the biosynthesis of the heavy chains of axonemal dyneins required for cilial beat. We establish a series of protein-protein interactions during cytoplasmic pre-assembly of macromolecular dynein motors, some of which are directly ZMYND10-dependent. In the absence of ZMYND10, failure of these interactions results in misfolded and unstable dynein heavy chains, which together with non-functional folding intermediates, are targeted for degradation. We propose that the motile ciliopathy Primary Ciliary Dyskinesia (PCD), such as seen in Zmynd10 mutants, be reconsidered as a disorder of protein folding, which opens new avenues for development of therapeutics.

Project description:To clarify the role of Wdr92, and R2TP, in motile cilium formation, we explored its function in Drosophila. We show that Drosophila Wdr92 is a cytoplasmic protein exclusively expressed in motile ciliated cells and is required exclusively for ciliary/flagellar motility. The major effect of its mutation is loss of dynein arms from the axonemes of sensory neuron cilia and sperm flagella. We confirm that Drosophila Wdr92 interacts with R2TP and that R2TP depletion also impairs dynein arm formation. We provide proteomic evidence that Wdr92 is associated especially with heavy chain assembly and propose that it acts as a specificity factor to bring axonemal dynein clients to the R2TP/HSP90 complex. Thus, Wdr92 is a new dynein assembly factor and it strongly reinforces the critical role of HSP90 and co-chaperones in dynein assembly.

Project description:Drosophila melanogaster Dnah3, dynein, axonemal, heavy chain 3, is differentially expressed in 6 experiment(s);

Project description:Drosophila melanogaster Dnah3, dynein, axonemal, heavy chain 3, is expressed in 2 baseline experiment(s);

Project description:Dynein axonemal heavy chain 5 (DNAH5) is the most mutated gene in primary ciliary dyskinesia (PCD), leading to abnormal cilia ultrastructure and function. Few studies have revealed the genetic characteristics and pathogenetic mechanisms of PCD caused by DNAH5 mutation. Here, we established a child PCD airway organoid directly from the bronchoscopic biopsy of a patient with DNAH5 mutation. We found abnormal ciliary function and a decreased immune response caused by DNAH5 mutation through proteomic analyses.