Mammalian Homologue NME3 of DYNAMO1 Regulates Peroxisome Division

Peroxisomes proliferate by sequential processes comprising elongation, constriction, and scission of peroxisomal membrane. It is known that the constriction step is mediated by a GTPase named dynamin-like protein 1 (DLP1) upon efficient loading of GTP. However, mechanism of fuelling GTP to DLP1 remains unknown in mammals. We earlier show that nucleoside diphosphate (NDP) kinase-like protein, termed dynamin-based ring motive-force organizer 1 (DYNAMO1), generates GTP for DLP1 in a red alga, Cyanidioschyzon merolae. In the present study, we identified that nucleoside diphosphate kinase 3 (NME3), a mammalian homologue of DYNAMO1, localizes to peroxisomes. Elongated peroxisomes were observed in cells with suppressed expression of NME3 and fibroblasts from a patient lacking NME3 due to the homozygous mutation at the initiation codon of NME3. Peroxisomes proliferated by elevation of NME3 upon silencing the expression of ATPase family AAA domain containing 1, ATAD1. In the wild-type cells expressing catalytically-inactive NME3, peroxisomes were elongated. These results suggest that NME3 plays an important role in peroxisome division in a manner dependent on its NDP kinase activity. Moreover, the impairment of peroxisome division reduces the level of ether-linked glycerophospholipids, ethanolamine plasmalogens, implying the physiological importance of regulation of peroxisome morphology.

A specialized reciprocal connectivity suggests a link between the mechanisms by which the superior colliculus and parabigeminal nucleus produce defensive behaviors in rodents

The parabigeminal nucleus (PBG) is the mammalian homologue to the isthmic complex of other vertebrates. Optogenetic stimulation of the PBG induces freezing and escape in mice, a result thought to be caused by a PBG projection to the central nucleus of the amygdala. However, the isthmic complex, including the PBG, has been classically considered satellite nuclei of the Superior Colliculus (SC), which upon stimulation of its medial part also triggers fear and avoidance reactions. As the PBG-SC connectivity is not well characterized, we investigated whether the topology of the PBG projection to the SC could be related to the behavioral consequences of PBG stimulation. To that end, we performed immunohistochemistry, in situ hybridization and neural tracer injections in the SC and PBG in a diurnal rodent, the Octodon degus. We found that all PBG neurons expressed both glutamatergic and cholinergic markers and were distributed in clearly defined anterior (aPBG) and posterior (pPBG) subdivisions. The pPBG is connected reciprocally and topographically to the ipsilateral SC, whereas the aPBG receives afferent axons from the ipsilateral SC and projected exclusively to the contralateral SC. This contralateral projection forms a dense field of terminals that is restricted to the medial SC, in correspondence with the SC representation of the aerial binocular field which, we also found, in O. degus prompted escape reactions upon looming stimulation. Therefore, this specialized topography allows binocular interactions in the SC region controlling responses to aerial predators, suggesting a link between the mechanisms by which the SC and PBG produce defensive behaviors.

IDENTIFICATION AND CHARACTERIZATION OF MEK1-MIP1-SMEK MULTIPROTEIN SIGNALING COMPLEX

In our previous study we characterized Dictyostelium SUMO targeted Ubiquitin Ligase (StUbL) MIP1 that associates with protein kinase MEK1 and targets SUMOylated MEK1 to ubiquitination and proteasomal degradation. These modifications happen in response to activation of MEK1 by chemoattractant cAMP. SMEK – second site genetic suppressor of mek1- null phenotype also identified in Dictyostelium. MEK1 and SMEK belong to the same linear pathway, in which MEK1 negatively regulates SMEK, which then negatively regulates chemotaxis and aggregation. RNF4 is mammalian homologue of MIP. RNF4 interacts with human homologue of Dictyostelium SMEK – hSMEK2. We propose existence of evolutionarily conserved MEK1-SMEK signaling complex that upon MEK1 activation and SUMOylation, recruits Ubiqutin Ligase MIP1/RNF4, which, in turn, ubiquitinates SMEK and targets this protein for proteasomal degradation. This could be a mechanism for negative regulation of SMEK by MEK1 signaling.

A hypothetical MEK1-MIP1-SMEK multiprotein signaling complex may function in Dictyostelium and mammalian cells

In a previous study, we characterized Dictyostelium SUMO targeted ubiquitin ligase (StUbL) MIP1 that associates with protein kinase MEK1 and targets SUMOylated MEK1 to ubiquitination (Sobko et al., 2002). These modifications happen in response to activation of MEK1 by the chemoattractant cAMP. Second site genetic suppressor of mek1- null phenotype (SMEK) was also identified in Dictyostelium. MEK1 and SMEK belong to the same linear pathway, in which MEK1 negatively regulates SMEK, which then negatively regulates chemotaxis and aggregation. RNF4 is mammalian homologue of MIP. RNF4 interacts with hSMEK2, the human homologue of Dictyostelium SMEK. We propose the existence of an evolutionarily conserved MEK1-SMEK signaling complex that upon MEK1 activation and SUMOylation, recruits ubiqutin ligase MIP1/RNF4, which, in turn, ubiquitinates SMEK and targets this protein for proteasomal degradation. This could be a mechanism for negative regulation of SMEK by MEK1 signaling.

Inducible degron-dependent depletion of the RNA polymerase I associated factor PAF53 demonstrates it is essential for cell growth and allows for the analysis of functional domains

Our knowledge of the mechanism of rDNA transcription has benefitted from the combined application of genetic techniques in yeast, and progress on the biochemistry of the various components of yeast rDNA transcription. Nomura’s laboratory derived a system in yeast for screening for mutants essential for ribosome biogenesis. Such systems have allowed investigators to not only determine if a gene was essential, but to analyze domains of the proteins for different functions in rDNA transcription in vivo. However, because there are significant differences in both the structures and components of the transcription apparatus and the patterns of regulation between mammals and yeast, there are significant deficits in our understanding of mammalian rDNA transcription. We have developed a system combining CRISPR/Cas9 and an inducible degron that allows us to combine a “genetics-like” approach to studying mammalian rDNA transcription with biochemistry. Using this system, we show that the mammalian homologue of yeast A49, PAF53, is required for rDNA transcription and mitotic growth. Further, we have been able to study the domains of the protein required for activity. We have found that while the C-terminal, DNA-binding domain (tWH) was necessary for complete function, the heterodimerization and linker domains were also essential. Analysis of the linker identified a putative DNA-binding domain. We have confirmed that the helix-turn-helix (HTH) of the linker constitutes a second DNA-binding domain within PAF53 and that the HTH is essential for PAF53 function.

The Drosophila Afadin and ZO-1 homologues Canoe and Polychaetoid act in parallel to maintain epithelial integrity when challenged by adherens junction remodeling

During morphogenesis, cells must change shape and move without disrupting tissue integrity. This requires cell–cell junctions to allow dynamic remodeling while resisting forces generated by the actomyosin cytoskeleton. Multiple proteins play roles in junctional–cytoskeletal linkage, but the mechanisms by which they act remain unclear. Drosophila Canoe maintains adherens junction–cytoskeletal linkage during gastrulation. Canoe’s mammalian homologue Afadin plays similar roles in cultured cells, working in parallel with ZO-1 proteins, particularly at multicellular junctions. We take these insights back to the fly embryo, exploring how cells maintain epithelial integrity when challenged by adherens junction remodeling during germband extension and dorsal closure. We found that Canoe helps cells maintain junctional–cytoskeletal linkage when challenged by the junctional remodeling inherent in mitosis, cell intercalation, and neuroblast invagination or by forces generated by the actomyosin cable at the leading edge. However, even in the absence of Canoe, many cells retain epithelial integrity. This is explained by a parallel role played by the ZO-1 homologue Polychaetoid. In embryos lacking both Canoe and Polychaetoid, cell junctions fail early, with multicellular junctions especially sensitive, leading to widespread loss of epithelial integrity. Our data suggest that Canoe and Polychaetoid stabilize Bazooka/Par3 at cell–cell junctions, helping maintain balanced apical contractility and tissue integrity.

SFI1 promotes centriole duplication by recruiting USP9X to stabilize the microcephaly protein STIL

In mammals, centrioles participate in brain development, and human mutations affecting centriole duplication cause microcephaly. Here, we identify a role for the mammalian homologue of yeast SFI1, involved in the duplication of the yeast spindle pole body, as a critical regulator of centriole duplication in mammalian cells. Mammalian SFI1 interacts with USP9X, a deubiquitylase associated with human syndromic mental retardation. SFI1 localizes USP9X to the centrosome during S phase to deubiquitylate STIL, a critical regulator of centriole duplication. USP9X-mediated deubiquitylation protects STIL from degradation. Consistent with a role for USP9X in stabilizing STIL, cells from patients with USP9X loss-of-function mutations have reduced STIL levels. Together, these results demonstrate that SFI1 is a centrosomal protein that localizes USP9X to the centrosome to stabilize STIL and promote centriole duplication. We propose that the USP9X protection of STIL to facilitate centriole duplication underlies roles of both proteins in human neurodevelopment.

Bibliometric analysis of research on the trends in autophagy

Background Autophagy is an important mechanism to maintain homeostasis in cells. It has been linked with ageing and many currently incurable diseases, including heart disease, cancer, myopathies, neurodegeneration, and diabetes. Autophagy research is very important for identifying better treatments. This study aimed to explore the hotspots of autophagy research published from different countries, organizations, and authors. Methods Between 1962 and 2018, articles published about autophagy were identified in the Web of Science database. The total and annual number of articles, citations, impact factor, Hirsch (H)-index, number of article citations, productive authors, and involved journals were collected for quantitative and qualitative comparisons. Results From 1962 to 2018, 18,811 autophagy-related articles written in English were published. Most were from China (6,731). The United States dominated in citation frequency (391,030) and h-index (264). Among related journals, Autophagy published the most articles (1,388), followed by Plos One (585) and Oncotarget (392). Daniel Klionsky was the most productive author, with 171 publications. The article “LC3, a mammalian homologue of yeast Apg8p, is localized in autophagosome membranes after processing” was cited most frequently. The top-ranked keyword was “degradation” of macroautophagy. Conclusions Publication of articles about autophagy has increased notably from 1962 to 2018, and has increased annually. The general quality of publications from China is still in need of improvement. Autophagy research has shifted gradually from basic studies to clinical studies in recent years.

A Yeast Suppressor Screen Used To Identify Mammalian SIRT1 as a Proviral Factor for Middle East Respiratory Syndrome Coronavirus Replication

ABSTRACT Viral proteins must intimately interact with the host cell machinery during virus replication. Here, we used the yeast Saccharomyces cerevisiae as a system to identify novel functional interactions between viral proteins and eukaryotic cells. Our work demonstrates that when the Middle East respiratory syndrome coronavirus (MERS-CoV) ORF4a accessory gene is expressed in yeast it causes a slow-growth phenotype. ORF4a has been characterized as an interferon antagonist in mammalian cells, and yet yeast lack an interferon system, suggesting further interactions between ORF4a and eukaryotic cells. Using the slow-growth phenotype as a reporter of ORF4a function, we utilized the yeast knockout library collection to perform a suppressor screen where we identified the YDL042C/SIR2 yeast gene as a suppressor of ORF4a function. The mammalian homologue of SIR2 is SIRT1, an NAD-dependent histone deacetylase. We found that when SIRT1 was inhibited by either chemical or genetic manipulation, there was reduced MERS-CoV replication, suggesting that SIRT1 is a proviral factor for MERS-CoV. Moreover, ORF4a inhibited SIRT1-mediated modulation of NF-κB signaling, demonstrating a functional link between ORF4a and SIRT1 in mammalian cells. Overall, the data presented here demonstrate the utility of yeast studies for identifying genetic interactions between viral proteins and eukaryotic cells. We also demonstrate for the first time that SIRT1 is a proviral factor for MERS-CoV replication and that ORF4a has a role in modulating its activity in cells. IMPORTANCE Middle East respiratory syndrome coronavirus (MERS-CoV) initially emerged in 2012 and has since been responsible for over 2,300 infections, with a case fatality ratio of approximately 35%. We have used the highly characterized model system of Saccharomyces cerevisiae to investigate novel functional interactions between viral proteins and eukaryotic cells that may provide new avenues for antiviral intervention. We identify a functional link between the MERS-CoV ORF4a proteins and the YDL042C/SIR2 yeast gene. The mammalian homologue of SIR2 is SIRT1, an NAD-dependent histone deacetylase. We demonstrate for the first time that SIRT1 is a proviral factor for MERS-CoV replication and that ORF4a has a role in modulating its activity in mammalian cells.

Overexpression of osmosensitive Ca2+-activated channel TMEM63B promotes migration in HEK293T cells

The recent discovery of the osmosensitive calcium (Ca2+) channel OSCA has revealed the potential mechanism by which plant cells sense diverse stimuli. Osmosensory transporters and mechanosensitive channels can detect and respond to osmotic shifts that play an important role in active cell homeostasis. TMEM63 family of proteins are described as the closest homologues of OSCAs. Here, we characterize TMEM63B, a mammalian homologue of OSCAs, recently classified as mechanosensitive. In HEK293T cells TMEM63B localizes to the plasma membrane and is associated to F-actin. This Ca2+-activated channel specifically induces Ca2+ influx across the membrane in response to extracellular Ca2+ concentration and hyperosmolarity. In addition, overexpression of TMEM63B in HEK293T cells significantly enhanced cell migration and wound healing. The link between Ca2+ osmosensitivity and cell migration might help to establish TMEM63B’s pathogenesis, for example in cancer in which it is frequently overexpressed.