Mms21 SUMO Ligase Activity Promotes Nucleolar Function in Saccharomyces cerevisiae

CpSmt3, an ortholog of small ubiquitin-like modifier, is essential for growth, organelle function, virulence, and antiviral defense in Cryphonectria parasitica

Introduction

SUMOylation is an important post-translational modification that regulates the expression, localization, and activity of substrate proteins, thereby participating in various important cellular processes such as the cell cycle, cell metabolism, gene transcription, and antiviral activity. However, the function of SUMOylation in phytopathogenic fungi has not yet been adequately explored.

Methods

A comprehensive analysis composed of proteomics, affinity pull-down, molecular and cellular approaches was performed to explore the roles of SUMOylation in Cryphonectria parasitica, the fungal pathogen responsible for chestnut blight.

Results and discussion

CpSmt3, the gene encoding the SUMO protein CpSmt3 in C. parasitica was identified and characterized. Deletion of the CpSmt3 gene resulted in defects in mycelial growth and hyphal morphology, suppression of sporulation, attenuation of virulence, weakening of stress tolerance, and elevated accumulation of hypovirus dsRNA. The ΔCpSmt3 deletion mutant exhibited an increase in mitochondrial ROS, swollen mitochondria, excess autophagy, and thickened cell walls. About 500 putative SUMO substrate proteins were identified by affinity pull-down, among which many were implicated in the cell cycle, ribosome, translation, and virulence. Proteomics and SUMO substrate analyses further revealed that deletion of CpSmt3 reduced the accumulation of CpRho1, an important protein that is involved in TOR signal transduction. Silencing of CpRho1 resulted in a phenotype similar to that of ΔCpSmt3, while overexpression of CpRho1 could partly rescue some of the prominent defects in ΔCpSmt3. Together, these findings demonstrate that SUMOylation by CpSmt3 is vitally important and provide new insights into the SUMOylation-related regulatory mechanisms in C. parasitica.

Ubiquitin proteomics identifies RNA polymerase I as a target of the Smc5/6 complex

Ubiquitination controls numerous cellular processes, and its deregulation is associated with many pathologies. The Nse1 subunit in the Smc5/6 complex contains a RING domain with ubiquitin E3 ligase activity and essential functions in genome integrity. However, Nse1-dependent ubiquitin targets remain elusive. Here, we use label-free quantitative proteomics to analyze the nuclear ubiquitinome of nse1-C274A RING mutant cells. Our results show that Nse1 impacts the ubiquitination of several proteins involved in ribosome biogenesis and metabolism that, importantly, extend beyond canonical functions of Smc5/6. In addition, our analysis suggests a connection between Nse1 and RNA polymerase I (RNA Pol I) ubiquitination. Specifically, Nse1 and the Smc5/6 complex promote ubiquitination of K408 and K410 in the clamp domain of Rpa190, a modification that induces its degradation in response to blocks in transcriptional elongation. We propose that this mechanism contributes to Smc5/6-dependent segregation of the rDNA array, the locus transcribed by RNA Pol I.

The Ubiquitin-like Proteins of Saccharomyces cerevisiae

In this review, we present a comprehensive list of the ubiquitin-like modifiers (Ubls) of Saccharomyces cerevisiae, a common model organism used to study fundamental cellular processes that are conserved in complex multicellular organisms, such as humans. Ubls are a family of proteins that share structural relationships with ubiquitin, and which modify target proteins and lipids. These modifiers are processed, activated and conjugated to substrates by cognate enzymatic cascades. The attachment of substrates to Ubls alters the various properties of these substrates, such as function, interaction with the environment or turnover, and accordingly regulate key cellular processes, including DNA damage, cell cycle progression, metabolism, stress response, cellular differentiation, and protein homeostasis. Thus, it is not surprising that Ubls serve as tools to study the underlying mechanism involved in cellular health. We summarize current knowledge on the activity and mechanism of action of the S. cerevisiae Rub1, Smt3, Atg8, Atg12, Urm1 and Hub1 modifiers, all of which are highly conserved in organisms from yeast to humans.

Acute ethanol stress induces sumoylation of conserved chromatin structural proteins in Saccharomyces cerevisiae

Stress is ubiquitous to life and can irreparably damage essential biomolecules and organelles in cells. To survive, organisms must sense and adapt to stressful conditions. One highly conserved adaptive stress response is through the posttranslational modification of proteins by the small ubiquitin-like modifier (SUMO). Here, we examine the effects of acute ethanol stress on protein sumoylation in the budding yeast Saccharomyces cerevisiae. We found that cells exhibit a transient sumoylation response after acute exposure to ≤7.5% vol/vol ethanol. By contrast, the sumoylation response becomes chronic at 10% ethanol exposure. Mass spectrometry analyses identified 18 proteins that are sumoylated after acute ethanol exposure, with 15 known to associate with chromatin. Upon further analysis, we found that the chromatin structural proteins Smc5 and Smc6 undergo ethanol-induced sumoylation that depends on the activity of the E3 SUMO ligase Mms21. Using cell-cycle arrest assays, we observed that Smc5 and Smc6 ethanol-induced sumoylation occurs during G1 and G2/M phases but not S phase. Acute ethanol exposure also resulted in the formation of Rad52 foci at levels comparable to Rad52 foci formation after exposure to the DNA alkylating agent methyl methanesulfonate (MMS). MMS exposure is known to induce the intra-S-phase DNA damage checkpoint via Rad53 phosphorylation, but ethanol exposure did not induce Rad53 phosphorylation. Ethanol abrogated the effect of MMS on Rad53 phosphorylation when added simultaneously. From these studies, we propose that acute ethanol exposure induces a change in chromatin leading to sumoylation of specific chromatin structural proteins.

Siz2 Prevents Ribosomal DNA Recombination by Modulating Levels of Tof2 in Saccharomyces cerevisiae

The genes that encode rRNA in Saccharomyces cerevisiae are organized as multiple repeats. The repetitive nature and heavy transcription of this region make it prone to DNA breaks. DNA breaks could lead to recombination, which could result in either loss or gain of repeats with detrimental consequences to the cell. Multiple mechanisms operate to maintain the stability of rDNA. Earlier studies reported that the absence of Ulp2, a deSUMOylase, resulted in declining levels of Tof2 and thereby disrupted rDNA silencing. In contrast, our findings suggest that accumulation of Tof2 can also result in increased rDNA recombination, through a mechanism that involves Fob1, an RFB-bound protein. While our study has examined only Tof2, rDNA recombination could be regulated by other proteins through a mechanism similar to this.

Ribosomal DNA (rDNA) recombination in budding yeast is regulated by multiple converging processes, including posttranslational modifications such as SUMOylation. In this study, we report that the absence of a SUMO E3 ligase, Siz2, results in increased unequal rDNA exchange. We show that Siz2 is enriched at the replication fork barrier (RFB) in the rDNA and also controls the homeostasis of Tof2 protein. siz2Δ resulted in increased accumulation of total Tof2 in the cell and a consequent increase in the enrichment of Tof2 at the rDNA. Overproducing Tof2 ectopically or conditional overexpression of Tof2 also resulted in higher levels of rDNA recombination, suggesting a direct role for Tof2. Additionally, our chromatin immunoprecipitation (ChIP) data indicate that the accumulation of Tof2 in a siz2Δ mutant resulted in an enhanced association of Fob1, an RFB binding protein at the rDNA at the RFB. This increased Fob1 association at the RFB may have resulted in the elevated rDNA recombination. Our study thus demonstrates that the Tof2 levels modulate recombination at the rDNA.

IMPORTANCE The genes that encode rRNA in Saccharomyces cerevisiae are organized as multiple repeats. The repetitive nature and heavy transcription of this region make it prone to DNA breaks. DNA breaks could lead to recombination, which could result in either loss or gain of repeats with detrimental consequences to the cell. Multiple mechanisms operate to maintain the stability of rDNA. Earlier studies reported that the absence of Ulp2, a deSUMOylase, resulted in declining levels of Tof2 and thereby disrupted rDNA silencing. In contrast, our findings suggest that accumulation of Tof2 can also result in increased rDNA recombination, through a mechanism that involves Fob1, an RFB-bound protein. While our study has examined only Tof2, rDNA recombination could be regulated by other proteins through a mechanism similar to this.

The Smc5/6 Complex: New and Old Functions of the Enigmatic Long-Distance Relative

Smc5 and Smc6, together with the kleisin Nse4, form the heart of the enigmatic and poorly understood Smc5/6 complex, which is frequently viewed as a cousin of cohesin and condensin with functions in DNA repair. As novel functions for cohesin and condensin complexes in the organization of long-range chromatin architecture have recently emerged, new unsuspected roles for Smc5/6 have also surfaced. Here, I aim to provide a comprehensive overview of our current knowledge of the Smc5/6 complex, including its long-established function in genome stability, its multiple roles in DNA repair, and its recently discovered connection to the transcription inhibition of hepatitis B virus genomes. In addition, I summarize new research that is beginning to tease out the molecular details of Smc5/6 structure and function, knowledge that will illuminate the nuclear activities of Smc5/6 in the stability and dynamics of eukaryotic genomes.

Methods to study SUMO dynamics in yeast

Covalent modification of proteins with the small ubiquitin-related modifier (SUMO) is found in all eukaryotes and is involved in many important processes. SUMO attachment may change interaction properties, subcellular localization, or stability of a modified protein. Usually, only a small fraction of a protein is modified at a given time because sumoylation is a highly dynamic process. The sumoylated state of a protein is controlled by the activity of the sumoylation enzymes that promote either their mono- or poly-sumoylation (SUMO chain formation), by SUMO proteases that reverse these modifications, and by SUMO-targeted ubiquitin ligases (STUbL, ULS) that mediate their degradation by the proteasome. While some organisms, such as humans, express multiple isoforms, budding yeast SUMO is encoded by a single and essential gene termed SMT3. The analysis of the simpler SUMO system in budding yeast has been instrumental in the identification of enzymes acting on this modification and controlling its dynamics. Sumoylation of proteins changes dramatically during the cell division cycle and under various stress conditions. Here we summarize various approaches that employ Saccharomyces cerevisiae as a model system to study the dynamics of sumoylation and how it is controlled.

Acute Smc5/6 depletion reveals its primary role in rDNA replication by restraining recombination at fork pausing sites

Smc5/6, a member of the conserved SMC family of complexes, is essential for growth in most organisms. Its exact functions in a mitotic cell cycle are controversial, as chronic Smc5/6 loss-of-function alleles produce varying phenotypes. To circumvent this issue, we acutely depleted Smc5/6 in budding yeast and determined the first cell cycle consequences of Smc5/6 removal. We found a striking primary defect in replication of the ribosomal DNA (rDNA) array. Each rDNA repeat contains a programmed replication fork barrier (RFB) established by the Fob1 protein. Fob1 removal improves rDNA replication in Smc5/6 depleted cells, implicating Smc5/6 in the management of programmed fork pausing. A similar improvement is achieved by removing the DNA helicase Mph1 whose recombinogenic activity can be inhibited by Smc5/6 under DNA damage conditions. DNA 2D gel analyses further show that Smc5/6 loss increases recombination structures at RFB regions; moreover, mph1∆ and fob1∆ similarly reduce this accumulation. These findings point to an important mitotic role for Smc5/6 in restraining recombination events when protein barriers in rDNA stall replication forks. As rDNA maintenance influences multiple essential cellular processes, Smc5/6 likely links rDNA stability to overall mitotic growth.

Smc5/6 belongs to the SMC (Structural Maintenance of Chromosomes) family of protein complexes, all of which are highly conserved and critical for genome maintenance. To address the roles of Smc5/6 during growth, we rapidly depleted its subunits in yeast and found the main acute effect to be defective ribosomal DNA (rDNA) duplication. The rDNA contains hundreds of sites that can pause replication forks; these must be carefully managed for cells to finish replication. We found that reducing fork pausing improved rDNA replication in cells without Smc5/6. Further analysis suggested that Smc5/6 prevents the DNA helicase Mph1 from turning paused forks into recombination structures, which cannot be processed without Smc5/6. Our findings thus revealed a key role for Smc5/6 in managing endogenous replication fork pausing. As rDNA and its associated nucleolar structure are critical for overall genome maintenance and other cellular processes, rDNA regulation by Smc5/6 would be expected to have multilayered effects on cell physiology and growth.

The AAA ATPase MDN1 Acts as a SUMO-Targeted Regulator in Mammalian Pre-ribosome Remodeling

Biogenesis of translation-competent 80S ribosomes is a multi-step process requiring the sequential action of non-ribosomal trans-acting factors. We previously identified the human PELP1-TEX10-WDR18 complex and the associated SUMO isopeptidase SENP3 as regulators of 60S maturation. We provided evidence that deconjugating SUMO from PELP1 by SENP3 is instrumental for proper ribosome biogenesis. Here we show that SUMO conjugation/deconjugation of PELP1 controls its dynamic association with the AAA ATPase MDN1, a key factor of pre-60S remodeling. We demonstrate that modification of PELP1 promotes the recruitment of MDN1 to pre-60S particles, while deSUMOylation is needed to release both MDN1 and PELP1 from pre-ribosomes. Inactivation of SENP3 traps MDN1 at pre-60S particles and prevents critical remodeling events, ultimately generating aberrant pre-60S complexes. We define MDN1 as a SUMO-targeted AAA ATPase, and we propose that a controlled SUMO cycle on PELP1 serves as regulatory point for mammalian 60S maturation through ordered recruitment and release of MDN1.