Ryan L. Huizar scite author profile

Macromolecular protein complexes carry out many of the essential functions of cells, and many genetic diseases arise from disrupting the functions of such complexes. Currently, there is great interest in defining the complete set of human protein complexes, but recent published maps lack comprehensive coverage. Here, through the synthesis of over 9,000 published mass spectrometry experiments, we present hu.MAP, the most comprehensive and accurate human protein complex map to date, containing > 4,600 total complexes, > 7,700 proteins, and > 56,000 unique interactions, including thousands of confident protein interactions not identified by the original publications. hu.MAP accurately recapitulates known complexes withheld from the learning procedure, which was optimized with the aid of a new quantitative metric (k‐cliques) for comparing sets of sets. The vast majority of complexes in our map are significantly enriched with literature annotations, and the map overall shows improved coverage of many disease‐associated proteins, as we describe in detail for ciliopathies. Using hu.MAP, we predicted and experimentally validated candidate ciliopathy disease genes in vivo in a model vertebrate, discovering CCDC138, WDR90, and KIAA1328 to be new cilia basal body/centriolar satellite proteins, and identifying ANKRD55 as a novel member of the intraflagellar transport machinery. By offering significant improvements to the accuracy and coverage of human protein complexes, hu.MAP (http://proteincomplexes.org) serves as a valuable resource for better understanding the core cellular functions of human proteins and helping to determine mechanistic foundations of human disease.

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A liquid-like organelle at the root of motile ciliopathy

Huizar

Lee

Boulgakov

et al. 2018

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Motile ciliopathies are characterized by specific defects in cilia beating that result in chronic airway disease, subfertility, ectopic pregnancy, and hydrocephalus. While many patients harbor mutations in the dynein motors that drive cilia beating, the disease also results from mutations in so-called dynein axonemal assembly factors (DNAAFs) that act in the cytoplasm. The mechanisms of DNAAF action remain poorly defined. Here, we show that DNAAFs concentrate together with axonemal dyneins and chaperones into organelles that form specifically in multiciliated cells, which we term DynAPs, for dynein axonemal particles. These organelles display hallmarks of biomolecular condensates, and remarkably, DynAPs are enriched for the stress granule protein G3bp1, but not for other stress granule proteins or P-body proteins. Finally, we show that both the formation and the liquid-like behaviors of DynAPs are disrupted in a model of motile ciliopathy. These findings provide a unifying cell biological framework for a poorly understood class of human disease genes and add motile ciliopathy to the growing roster of human diseases associated with disrupted biological phase separation.

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A systematic, label-free method for identifying RNA-associated proteins in vivo provides insights into vertebrate ciliary beating machinery

Drew

Lee

Cox

et al. 2020

Developmental Biology

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A systematic, label-free method for identifying RNA-associated proteinsin vivoprovides insights into vertebrate ciliary beating

Drew

Lee

Cox

et al. 2020

Preprint

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Cell-type specific RNA-associated proteins (RAPs) are essential for development and homeostasis in animals. Despite a massive recent effort to systematically identify RAPs, we currently have few comprehensive rosters of cell-type specific RAPs in vertebrate tissues. Here, we demonstrate the feasibility of determining the RNA-interacting proteome of a defined vertebrate embryonic tissue using DIF-FRAC, a systematic and universal (i.e., label-free) method. Application of DIF-FRAC to cultured tissue explants of Xenopus mucociliary epithelium identified dozens of known RAPs as expected, but also several novel RAPs, including proteins related to assembly of the mitotic spindle and regulation of ciliary beating. In particular, we show that the inner dynein arm tether Cfap44 is an RNA-associated protein that localizes not only to axonemes, but also to liquid-like organelles in the cytoplasm called DynAPs. This result led us to discover that DynAPs are generally enriched for RNA. Together, these data provide a useful resource for a deeper understanding of mucociliary epithelia and demonstrate that DIF-FRAC will be broadly applicable for systematic identification of RAPs from embryonic tissues. Introduction:

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A phase separated organelle at the root of motile ciliopathy

Huizar

Lee

Boulgakov

et al. 2017

Preprint

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Hundreds of different cell types emerge in the developing embryo, each of which must compartmentalize cell type specific biochemical processes in a crowded intracellular environment. To study cell type specific compartmentalization, we examined motile ciliated cells, which must assemble vast numbers of dynein motors to drive ciliary beating, as mutation of dyneins or their assembly factors causes motile ciliopathy. We show that dyneins, their assembly factors, and chaperones all concentrate together in Dynein Assembly Particles (DynAPs). These phase-separated organelles are specific to ciliated cells but share machinery with stress granules. Our data suggest that a common framework underlies ubiquitous and cell-type specific phase separated organelles and that one such organelle is defective in a human genetic disease.Motile cilia are microtubule based cellular projections that beat in an oriented manner to generate fluid flows that are critical for development and homeostasis. Accordingly, defects in ciliary beating underlie a constellation of human diseases called the motile ciliopathies, which are characterized by situs inversus, chronic airway infection, and infertility (1, 2). Motile ciliopathies frequently result from mutations in genes encoding subunits of the multi-protein dynein motors that drive ciliary beating (Fig. 1A) (1, 2).Interestingly, dynein motors are pre-assembled in the cytoplasm before being deployed to cilia (3), and it is now clear that many motile ciliopathies result from mutations in an array of cytoplasmic Dynein Arm Assembly Factors (DNAAFs) (Fig. 1A) (4-16). Previously, we reported that Heatr2/Dnaaf5 is present in cytoplasmic foci in human MCCs (8); and interestingly, we found that many other foci-forming proteins in MCCs are encoded by genes controlled by Rfx2 (17), a component of the evolutionarily conserved motile ciliogenic transcriptional circuitry (18)(19)(20)(21)(22). Because no unifying cell biological mechanism for DNAAF action has yet emerged, we set out to explore the link between the motile ciliogenic transcription factors, cytoplasmic foci, and dynein arm assembly.Dynein Assembly Particles (DynAPs) are evolutionarily conserved organelles compartmentalizing axonemal dyneins and their assembly factors.

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Ryan L. Huizar

Integration of over 9,000 mass spectrometry experiments builds a global map of human protein complexes

A liquid-like organelle at the root of motile ciliopathy

A systematic, label-free method for identifying RNA-associated proteins in vivo provides insights into vertebrate ciliary beating machinery

A systematic, label-free method for identifying RNA-associated proteinsin vivoprovides insights into vertebrate ciliary beating

A phase separated organelle at the root of motile ciliopathy

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