Multiscale 3D Bioprinting by Nozzle-Free Acoustic Droplet Ejection.

Bioprinting allows the manufacture of complex cell-laden hydrogel constructs that can mature into tissue replacements in subsequent cell culture processes. The nozzles used in currently available bioprinters limit the print resolution and at dimensions below 100 µm clogging is expected. Most critically, the reduction of nozzle diameter also increases shear stress during printing. At critical shear stress, mechanical damage to printed cells triggers cell death. To overcome these limitations, a novel 3D bioprinting method based on the principle of acoustic droplet ejection (ADE) is introduced here. The absence of a nozzle in this method minimizes critical shear stress. A numerical simulation reveals that maximum shear stress during the ADE process is 2.7 times lower than with a Ø150 µm microvalve nozzle. Printing of cell clusters contained in droplets at the millimeter length scale, as well as in droplets the size of a single cell, is feasible. The precise 3D build-up of cell-laden structures is demonstrated and evidence is provided that there are no negative effects on stem cell morphology, proliferation, or differentiation capacities. This multiscale acoustic bioprinting technique thus holds promise for cell-preserving creation of complex and individualized cell-laden 3D hydrogel structures.

Nucleolar release of rDNA repeats for repair involves SUMO-mediated untethering by the Cdc48/p97 segregase.

Ribosomal RNA genes (rDNA) are highly unstable and susceptible to rearrangement due to their repetitive nature and active transcriptional status. Sequestration of rDNA in the nucleolus suppresses uncontrolled recombination. However, broken repeats must be first released to the nucleoplasm to allow repair by homologous recombination. Nucleolar release of broken rDNA repeats is conserved from yeast to humans, but the underlying molecular mechanisms are currently unknown. Here we show that DNA damage induces phosphorylation of the CLIP-cohibin complex, releasing membrane-tethered rDNA from the nucleolus in Saccharomyces cerevisiae. Downstream of phosphorylation, SUMOylation of CLIP-cohibin is recognized by Ufd1 via its SUMO-interacting motif, which targets the complex for disassembly through the Cdc48/p97 chaperone. Consistent with a conserved mechanism, UFD1L depletion in human cells impairs rDNA release. The dynamic and regulated assembly and disassembly of the rDNA-tethering complex is therefore a key determinant of nucleolar rDNA release and genome integrity.

ESCRT recruitment by the S. cerevisiae inner nuclear membrane protein Heh1 is regulated by Hub1-mediated alternative splicing.

Misassembled nuclear pore complexes (NPCs) are removed by sealing off the surrounding nuclear envelope (NE), which is conducted by the endosomal sorting complexes required for transport (ESCRT) machinery. Recruitment of ESCRT proteins to the NE is mediated by the interaction between the ESCRT member Chm7 and the inner nuclear membrane protein Heh1, which belongs to the conserved LEM family. Increased ESCRT recruitment results in excessive membrane scission at damage sites but its regulation remains poorly understood. Here, we show that Hub1-mediated alternative splicing of HEH1 pre-mRNA, resulting in production of its shorter form Heh1-S, is critical for the integrity of the NE in Saccharomyces cerevisiae ESCRT-III mutants lacking Hub1 or Heh1-S display severe growth defects and accumulate improperly assembled NPCs. This depends on the interaction of Chm7 with the conserved MSC domain, which is only present in the longer variant Heh1-L. Heh1 variants assemble into heterodimers, and we demonstrate that a unique splice segment in Heh1-S suppresses growth defects associated with the uncontrolled interaction between Heh1-L and Chm7. Together, our findings reveal that Hub1-mediated splicing generates Heh1-S to regulate ESCRT recruitment to the NE.This article has an associated First Person interview with the first author of the paper.

A Selective Autophagy Pathway for Phase-Separated Endocytic Protein Deposits.

Autophagy eliminates cytoplasmic content selected by autophagy receptors, which link cargo to the membrane-bound autophagosomal ubiquitin-like protein Atg8/LC3. Here, we report a selective autophagy pathway for protein condensates formed by endocytic proteins in yeast. In this pathway, the endocytic protein Ede1 functions as a selective autophagy receptor. Distinct domains within Ede1 bind Atg8 and mediate phase separation into condensates. Both properties are necessary for an Ede1-dependent autophagy pathway for endocytic proteins, which differs from regular endocytosis and does not involve other known selective autophagy receptors but requires the core autophagy machinery. Cryo-electron tomography of Ede1-containing condensates, at the plasma membrane and in autophagic bodies, shows a phase-separated compartment at the beginning and end of the Ede1-mediated selective autophagy route. Our data suggest a model for autophagic degradation of macromolecular protein complexes by the action of intrinsic autophagy receptors.

Chaperone-Mediated Protein Disaggregation Triggers Proteolytic Clearance of Intra-nuclear Protein Inclusions.

The formation of insoluble inclusions in the cytosol and nucleus is associated with impaired protein homeostasis and is a hallmark of several neurodegenerative diseases. Due to the absence of the autophagic machinery, nuclear protein aggregates require a solubilization step preceding degradation by the 26S proteasome. Using yeast, we identify a nuclear protein quality control pathway required for the clearance of protein aggregates. The nuclear J-domain protein Apj1 supports protein disaggregation together with Hsp70 but independent of the canonical disaggregase Hsp104. Disaggregation mediated by Apj1/Hsp70 promotes turnover rather than refolding. A loss of Apj1 activity uncouples disaggregation from proteasomal turnover, resulting in accumulation of toxic soluble protein species. Endogenous substrates of the Apj1/Hsp70 pathway include both nuclear and cytoplasmic proteins, which aggregate inside the nucleus upon proteotoxic stress. These findings demonstrate the coordinated activity of the Apj1/Hsp70 disaggregation system with the 26S proteasome in facilitating the clearance of toxic inclusions inside the nucleus.

Selective autophagy degrades nuclear pore complexes.

Nuclear pore complexes (NPCs) are very large proteinaceous assemblies that consist of more than 500 individual proteins1,2. NPCs are essential for nucleocytoplasmic transport of different cellular components, and disruption of the integrity of NPCs has been linked to aging, cancer and neurodegenerative diseases3-7. However, the mechanism by which membrane-embedded NPCs are turned over is currently unknown. Here we show that, after nitrogen starvation or genetic interference with the architecture of NPCs, nucleoporins are rapidly degraded in the budding yeast Saccharomyces cerevisiae. We demonstrate that NPC turnover involves vacuolar proteases and the core autophagy machinery. Autophagic degradation is mediated by the cytoplasmically exposed Nup159, which serves as intrinsic cargo receptor and directly binds to the autophagy marker protein Atg8. Autophagic degradation of NPCs is therefore inducible, enabling the removal of individual NPCs from the nuclear envelope.

A SUMO-dependent pathway controls elongating RNA Polymerase II upon UV-induced damage.

RNA polymerase II (RNAPII) is the workhorse of eukaryotic transcription and produces messenger RNAs and small nuclear RNAs. Stalling of RNAPII caused by transcription obstacles such as DNA damage threatens functional gene expression and is linked to transcription-coupled DNA repair. To restore transcription, persistently stalled RNAPII can be disassembled and removed from chromatin. This process involves several ubiquitin ligases that have been implicated in RNAPII ubiquitylation and proteasomal degradation. Transcription by RNAPII is heavily controlled by phosphorylation of the C-terminal domain of its largest subunit Rpb1. Here, we show that the elongating form of Rpb1, marked by S2 phosphorylation, is specifically controlled upon UV-induced DNA damage. Regulation of S2-phosphorylated Rpb1 is mediated by SUMOylation, the SUMO-targeted ubiquitin ligase Slx5-Slx8, the Cdc48 segregase as well as the proteasome. Our data suggest an RNAPII control pathway with striking parallels to known disassembly mechanisms acting on defective RNA polymerase III.

Slx5/Slx8-dependent ubiquitin hotspots on chromatin contribute to stress tolerance.

Chromatin is a highly regulated environment, and protein association with chromatin is often controlled by post-translational modifications and the corresponding enzymatic machinery. Specifically, SUMO-targeted ubiquitin ligases (STUbLs) have emerged as key players in nuclear quality control, genome maintenance, and transcription. However, how STUbLs select specific substrates among myriads of SUMOylated proteins on chromatin remains unclear. Here, we reveal a remarkable co-localization of the budding yeast STUbL Slx5/Slx8 and ubiquitin at seven genomic loci that we term "ubiquitin hotspots". Ubiquitylation at these sites depends on Slx5/Slx8 and protein turnover on the Cdc48 segregase. We identify the transcription factor-like Ymr111c/Euc1 to associate with these sites and to be a critical determinant of ubiquitylation. Euc1 specifically targets Slx5/Slx8 to ubiquitin hotspots via bipartite binding of Slx5 that involves the Slx5 SUMO-interacting motifs and an additional, novel substrate recognition domain. Interestingly, the Euc1-ubiquitin hotspot pathway acts redundantly with chromatin modifiers of the H2A.Z and Rpd3L pathways in specific stress responses. Thus, our data suggest that STUbL-dependent ubiquitin hotspots shape chromatin during stress adaptation.

Failed mitochondrial import and impaired proteostasis trigger SUMOylation of mitochondrial proteins.

Modification by the ubiquitin-like protein SUMO affects hundreds of cellular substrate proteins and regulates a wide variety of physiological processes. While the SUMO system appears to predominantly target nuclear proteins and, to a lesser extent, cytosolic proteins, hardly anything is known about the SUMOylation of proteins targeted to membrane-enclosed organelles. Here, we identify a large set of structurally and functionally unrelated mitochondrial proteins as substrates of the SUMO pathway in yeast. We show that SUMO modification of mitochondrial proteins does not rely on mitochondrial targeting and, in fact, is strongly enhanced upon import failure, consistent with the modification occurring in the cytosol. Moreover, SUMOylated forms of mitochondrial proteins particularly accumulate in HSP70- and proteasome-deficient cells, suggesting that SUMOylation participates in cellular protein quality control. We therefore propose that SUMO serves as a mark for nonfunctional mitochondrial proteins, which only sporadically arise in unstressed cells but strongly accumulate upon defective mitochondrial import and impaired proteostasis. Overall, our findings provide support for a role of SUMO in the cytosolic response to aberrant proteins.

Pathway choice between proteasomal and autophagic degradation.

Efficient degradation of abnormal or aggregated proteins is crucial to protect the cell against proteotoxic stress. Selective targeting and disposal of such proteins usually occurs in a ubiquitin-dependent manner by proteasomes and macroautophagy/autophagy. Whereas proteasomes are efficient in degrading abnormal soluble proteins, protein aggregates are typically targeted for degradation by autophagic vesicles. Both processes require ubiquitin-binding receptors, which are targeted to proteasomes via ubiquitin-like domains or to phagophores (the precursors to autophagosomes) via Atg8/LC3 binding motifs, respectively. The use of substrate modification by ubiquitin in both pathways raised the question of how degradative pathway choice is achieved. In contrast to previous models, proposing different types of ubiquitin linkages for substrate targeting, we find that pathway choice is a late event largely determined by the oligomeric state of the receptors. Monomeric proteasome receptors bind soluble substrates more efficiently due to their higher affinity for ubiquitin. Upon substrate aggregation, autophagy receptors with lower ubiquitin binding affinity gain the upper hand due to higher avidity achieved by receptor bundling. Thus, our work suggests that ubiquitination is a shared signal of an adaptive protein quality control system, which targets substrates for the optimal proteolytic pathway.

Error-Prone Splicing Controlled by the Ubiquitin Relative Hub1.

Accurate pre-mRNA splicing is needed for correct gene expression and relies on faithful splice site recognition. Here, we show that the ubiquitin-like protein Hub1 binds to the DEAD-box helicase Prp5, a key regulator of early spliceosome assembly, and stimulates its ATPase activity thereby enhancing splicing and relaxing fidelity. High Hub1 levels enhance splicing efficiency but also cause missplicing by tolerating suboptimal splice sites and branchpoint sequences. Notably, Prp5 itself is regulated by a Hub1-dependent negative feedback loop. Since Hub1-mediated splicing activation induces cryptic splicing of Prp5, it also represses Prp5 protein levels and thus curbs excessive missplicing. Our findings indicate that Hub1 mediates enhanced, but error-prone splicing, a mechanism that is tightly controlled by a feedback loop of PRP5 cryptic splicing activation.

Receptor oligomerization guides pathway choice between proteasomal and autophagic degradation.

Abnormal or aggregated proteins have a strong cytotoxic potential and are causative for human disorders such as Alzheimer's, Parkinson's, Huntington's disease and amyotrophic lateral sclerosis. If not restored by molecular chaperones, abnormal proteins are typically degraded by proteasomes or eliminated by selective autophagy. The discovery that both pathways are initiated by substrate ubiquitylation but utilize different ubiquitin receptors incited a debate over how pathway choice is achieved. Here, we demonstrate in yeast that pathway choice is made after substrate ubiquitylation by competing ubiquitin receptors harbouring either proteasome- or autophagy-related protein 8 (Atg8/LC3)-binding modules. Proteasome pathway receptors bind ubiquitin moieties more efficiently, but autophagy receptors gain the upper hand following substrate aggregation and receptor bundling. Indeed, by using sets of modular artificial receptors harbouring identical ubiquitin-binding modules we found that proteasome/autophagy pathway choice is independent of the ubiquitin-binding properties of the receptors but largely determined by their oligomerization potentials. Our work thus suggests that proteasomal degradation and selective autophagy are two branches of an adaptive protein quality control pathway, which uses substrate ubiquitylation as a shared degradation signal.

The INO80 Complex Removes H2A.Z to Promote Presynaptic Filament Formation during Homologous Recombination.

The INO80 complex (INO80-C) is an evolutionarily conserved nucleosome remodeler that acts in transcription, replication, and genome stability. It is required for resistance against genotoxic agents and is involved in the repair of DNA double-strand breaks (DSBs) by homologous recombination (HR). However, the causes of the HR defect in INO80-C mutant cells are controversial. Here, we unite previous findings using a system to study HR with high spatial resolution in budding yeast. We find that INO80-C has at least two distinct functions during HR-DNA end resection and presynaptic filament formation. Importantly, the second function is linked to the histone variant H2A.Z. In the absence of H2A.Z, presynaptic filament formation and HR are restored in INO80-C-deficient mutants, suggesting that presynaptic filament formation is the crucial INO80-C function during HR.

Identification of Substrates of Protein-Group SUMOylation.

Protein modification by conjugation to the ubiquitin-related protein SUMO (SUMOylation) regulates numerous cellular functions and is reversible. However, unlike typical posttranslational modifications, SUMOylation often targets and regulates proteins of functionally and physically linked protein groups, rather than individual proteins. Functional studies of protein-group SUMOylation are thus particularly challenging, as they require the identification of ideally all members of a modified protein group. Here, we describe mass spectrometric approaches to detect SUMOylated protein groups in Saccharomyces cerevisiae, yet the protocols can be readily adapted for studies of SUMOylation in mammalian cells.

DNA-protein crosslink repair.

DNA-protein crosslinks (DPCs) are highly toxic DNA adducts, but whether dedicated DPC-repair mechanisms exist was until recently unknown. This has changed with discoveries made in yeast and Xenopus laevis that revealed a protease-based DNA-repair pathway specific for DPCs. Importantly, mutations in the gene encoding the putative human homologue of a yeast DPC protease cause a human premature ageing and cancer predisposition syndrome. Thus, DPC repair is a previously overlooked genome-maintenance mechanism that may be essential for tumour suppression.

DNA-protein crosslink repair: proteases as DNA repair enzymes.

DNA-protein crosslinks (DPCs) are highly toxic DNA lesions because they interfere with DNA transactions. The recent discovery of a yeast protease that processes DPCs proteolytically raises the question whether DPC proteases also exist in higher eukaryotes. We argue here that the yeast enzyme, Wss1 (weak suppressor of smt3), is a member of a protease family whose mammalian representative is Spartan (SprT-like domain-containing protein)/DVC1 (DNA damage protein targeting VCP). DPC proteases may thus be common to all eukaryotes where they function as novel guardians of the genome.

A new class of ubiquitin-Atg8 receptors involved in selective autophagy and polyQ protein clearance.

Selective ubiquitin-dependent autophagy mediates the disposal of superfluous cellular structures and clears cells of protein aggregates such as polyQ proteins linked to Huntington disease. Crucial selectivity factors of this pathway are ubiquitin-Atg8 receptors such as human SQSTM1/p62, which recognize ubiquitinated cargoes and deliver them to phagophores for degradation. Contrasting previous beliefs, we recently showed that ubiquitin-dependent autophagy is not restricted to higher eukaryotes but also exists in yeast with Cue5, harboring a ubiquitin-binding CUE domain, being a ubiquitin-Atg8 receptor. Notably, the human CUE domain protein TOLLIP is functionally similar to yeast Cue5, indicating that Cue5/TOLLIP (CUET) proteins represent a new and conserved class of autophagy receptors. Remarkably, both Cue5 in yeast and TOLLIP in human cells mediate efficient clearance of aggregation-prone polyQ proteins derived from human HTT/huntingtin. Indeed, TOLLIP is potentially more potent in polyQ clearance than SQSTM1/p62 in HeLa cells, suggesting that TOLLIP, also implicated in innate immunity, may be significant for human health and disease.

Autophagic clearance of polyQ proteins mediated by ubiquitin-Atg8 adaptors of the conserved CUET protein family.

Selective ubiquitin-dependent autophagy plays a pivotal role in the elimination of protein aggregates, assemblies, or organelles and counteracts the cytotoxicity of proteins linked to neurodegenerative diseases. Following substrate ubiquitylation, the cargo is delivered to autophagosomes involving adaptors like human p62 that bind ubiquitin and the autophagosomal ubiquitin-like protein Atg8/LC3; however, whether similar pathways exist in lower eukaryotes remained unclear. Here, we identify by a screen in yeast a new class of ubiquitin-Atg8 adaptors termed CUET proteins, comprising the ubiquitin-binding CUE-domain protein Cue5 from yeast and its human homolog Tollip. Cue5 collaborates with Rsp5 ubiquitin ligase, and the corresponding yeast mutants accumulate aggregation-prone proteins and are vulnerable to polyQ protein expression. Similarly, Tollip depletion causes cytotoxicity toward polyQ proteins, whereas Tollip overexpression clears human cells from Huntington's disease-linked polyQ proteins by autophagy. We thus propose that CUET proteins play a critical and ancient role in autophagic clearance of cytotoxic protein aggregates.

A DNA-dependent protease involved in DNA-protein crosslink repair.

Toxic DNA-protein crosslinks (DPCs) arise by ionizing irradiation and UV light, are particularly caused by endogenously produced reactive compounds such as formaldehyde, and also occur during compromised topoisomerase action. Although nucleotide excision repair and homologous recombination contribute to cell survival upon DPCs, hardly anything is known about mechanisms that target the protein component of DPCs directly. Here, we identify the metalloprotease Wss1 as being crucial for cell survival upon exposure to formaldehyde and topoisomerase 1-dependent DNA damage. Yeast mutants lacking Wss1 accumulate DPCs and exhibit gross chromosomal rearrangements. Notably, in vitro assays indicate that substrates such as topoisomerase 1 are processed by the metalloprotease directly and in a DNA-dependent manner. Thus, our data suggest that Wss1 contributes to survival of DPC-harboring cells by acting on DPCs proteolytically. We propose that DPC proteolysis enables repair of these unique lesions via downstream canonical DNA repair pathways.

The conserved ubiquitin-like protein Hub1 plays a critical role in splicing in human cells.

Different from canonical ubiquitin-like proteins, Hub1 does not form covalent conjugates with substrates but binds proteins non-covalently. In Saccharomyces cerevisiae, Hub1 associates with spliceosomes and mediates alternative splicing of SRC1, without affecting pre-mRNA splicing generally. Human Hub1 is highly similar to its yeast homolog, but its cellular function remains largely unexplored. Here, we show that human Hub1 binds to the spliceosomal protein Snu66 as in yeast; however, unlike its S. cerevisiae homolog, human Hub1 is essential for viability. Prolonged in vivo depletion of human Hub1 leads to various cellular defects, including splicing speckle abnormalities, partial nuclear retention of mRNAs, mitotic catastrophe, and consequently cell death by apoptosis. Early consequences of Hub1 depletion are severe splicing defects, however, only for specific splice sites leading to exon skipping and intron retention. Thus, the ubiquitin-like protein Hub1 is not a canonical spliceosomal factor needed generally for splicing, but rather a modulator of spliceosome performance and facilitator of alternative splicing.