Your search keyword '"Nina V Romanova"' showing total 8 results

1. Mismatch repair-dependent mutagenesis in nondividing cells

Author

Nina V. Romanova, Yoke W. Kow, N. Cynthia Rouf, Gina P. Rodriguez, Gray F. Crouse, and Gaobin Bao

Subjects

DNA Replication, Genetics, Saccharomyces cerevisiae Proteins, Multidisciplinary, Base Sequence, Genotype, Models, Genetic, Semiconservative replication, DNA replication, Eukaryotic DNA replication, Saccharomyces cerevisiae, DNA Repair Pathway, Biological Sciences, Biology, DNA Mismatch Repair, DNA-Binding Proteins, Replication factor C, Control of chromosome duplication, Mutagenesis, Mutation, Tryptophan Synthase, DNA mismatch repair, DNA, Fungal, Replication protein A, DNA Damage

Abstract

Mismatch repair (MMR) is a major DNA repair pathway in cells from all branches of life that removes replication errors in a strand-specific manner, such that mismatched nucleotides are preferentially removed from the newly replicated strand of DNA. Here we demonstrate a role for MMR in helping create new phenotypes in nondividing cells. We show that mispairs in yeast that escape MMR during replication can later be subject to MMR activity in a replication strand-independent manner in nondividing cells, resulting in either fully wild-type or mutant DNA sequence. In one case, this activity is responsible for what appears to be adaptive mutation. This replication strand-independent MMR activity could contribute to the formation of tumors arising in nondividing cells and could also contribute to mutagenesis observed during somatic hypermutation of Ig genes.

Published

2012

2. Mutation of the protein-O-mannosyltransferase enhances secretion of the human urokinase-type plasminogen activator inHansenula polymorpha

Author

Eui-Sung Choi, Michael O. Agaphonov, Nina V. Romanova, Michael D. Ter-Avanesyan, Sviatoslav S. Sokolov, Tatyana S. Kalebina, So-Young Kim, and Jung-Hoon Sohn

Subjects

Protein Folding, Mannosyltransferase, Glycosylation, KDEL, Molecular Sequence Data, Mutant, Saccharomyces cerevisiae, Bioengineering, Endoplasmic Reticulum, Mannosyltransferases, Applied Microbiology and Biotechnology, Biochemistry, Pichia, Gene Expression Regulation, Fungal, Genetics, Humans, Secretion, Amino Acid Sequence, biology, Endoplasmic reticulum, Sequence Analysis, DNA, biology.organism_classification, Urokinase-Type Plasminogen Activator, Molecular biology, Secretory protein, Mutation, Plasminogen activator, Biotechnology

Abstract

Human urokinase-type plasminogen activator (uPA) is poorly secreted and aggregates in the endoplasmic reticulum of yeast cells due to inefficient folding. A screen for Hansenula polymorpha mutants with improved uPA secretion revealed a gene encoding a homologue of the Saccharomyces cerevisiae protein-O-mannosyltransferase Pmt1p. Expression of the H. polymorpha PMT1 gene (HpPMT1) abolished temperature sensitivity of the S. cerevisiae pmt1 pmt2 double mutant. As in S. cerevisiae, inactivation of the HpPMT1 gene affected electrophoretic mobility of the O-glycosylated protein, extracellular chitinase. In contrast to S. cerevisiae, disruption of HpPMT1 alone caused temperature sensitivity. Inactivation of the HpPMT1 gene decreased intracellular aggregation of uPA, suggesting that enhanced secretion of uPA was due to improvement of its folding in the endoplasmic reticulum. Unlike most of the endoplasmic reticulum membrane proteins, HpPmt1p possesses the C-terminal KDEL retention signal. The GenBank Accession No. for the H. polymorpha PMT1 sequence is AY701415. Copyright © 2005 John Wiley & Sons, Ltd.

Published

2005

3. Different Roles of Eukaryotic MutS and MutL Complexes in Repair of Small Insertion and Deletion Loops in Yeast

Author

Gray F. Crouse and Nina V. Romanova

Subjects

DNA Replication, Cancer Research, Saccharomyces cerevisiae Proteins, lcsh:QH426-470, Oligonucleotides, Saccharomyces cerevisiae, Biology, medicine.disease_cause, DNA Mismatch Repair, 03 medical and health sciences, 0302 clinical medicine, Transformation, Genetic, INDEL Mutation, MutS-1, Genetics, medicine, Insertion, Molecular Biology, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0303 health sciences, Mutation, Point mutation, DNA replication, MutS Proteins, MutS DNA Mismatch-Binding Protein, DNA-Binding Proteins, lcsh:Genetics, MutL Proteins, Coding strand, DNA mismatch repair, Carrier Proteins, 030217 neurology & neurosurgery, Research Article, DNA Damage

Abstract

DNA mismatch repair greatly increases genome fidelity by recognizing and removing replication errors. In order to understand how this fidelity is maintained, it is important to uncover the relative specificities of the different components of mismatch repair. There are two major mispair recognition complexes in eukaryotes that are homologues of bacterial MutS proteins, MutSα and MutSβ, with MutSα recognizing base-base mismatches and small loop mispairs and MutSβ recognizing larger loop mispairs. Upon recognition of a mispair, the MutS complexes then interact with homologues of the bacterial MutL protein. Loops formed on the primer strand during replication lead to insertion mutations, whereas loops on the template strand lead to deletions. We show here in yeast, using oligonucleotide transformation, that MutSα has a strong bias toward repair of insertion loops, while MutSβ has an even stronger bias toward repair of deletion loops. Our results suggest that this bias in repair is due to the different interactions of the MutS complexes with the MutL complexes. Two mutants of MutLα, pms1-G882E and pms1-H888R, repair deletion mispairs but not insertion mispairs. Moreover, we find that a different MutL complex, MutLγ, is extremely important, but not sufficient, for deletion repair in the presence of either MutLα mutation. MutSβ is present in many eukaryotic organisms, but not in prokaryotes. We suggest that the biased repair of deletion mispairs may reflect a critical eukaryotic function of MutSβ in mismatch repair., Author Summary DNA mismatch repair is a major pathway that prevents both base substitution and insertion or deletion errors during replication. Most eukaryotes have two recognition complexes, MutSα and MutSβ, homologues of prokaryotic MutS and differing in their affinity for mismatches, with MutSα recognizing base-base mismatches and small insertion/deletion loops and MutSβ recognizing larger loops. We show that repair mediated by these complexes has opposite biases for insertion versus deletion mispairs with MutSα-directed repair favoring insertion loops and MutSβ-directed repair favoring deletion loops. This bias is mediated by differing interactions with downstream MutL complexes. We suggest that MutSα represents a prokaryotic MutS biased for repair of insertion loops and that MutSβ represents a new eukaryotic activity biased for repair of deletion loops.

Published

2013

4. Polyglutamine toxicity is controlled by prion composition and gene dosage in yeast

Author

Kavita C. Gokhale, Yury O. Chernoff, He Gong, Kim D. Allen, Michael Y. Sherman, Gary P. Newnam, Nina V. Romanova, Pavithra Chandramowlishwaran, and Piotr A. Mieczkowski

Subjects

Cancer Research, Saccharomyces cerevisiae Proteins, lcsh:QH426-470, Prions, Saccharomyces cerevisiae, Gene Dosage, Nerve Tissue Proteins, Plasma protein binding, Biology, Epigenesis, Genetic, Green fluorescent protein, 03 medical and health sciences, 0302 clinical medicine, Genetics, Huntingtin Protein, Protein biosynthesis, Humans, Cytotoxicity, Molecular Biology, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, Sequence Deletion, 030304 developmental biology, 0303 health sciences, biology.organism_classification, 3. Good health, Cell biology, lcsh:Genetics, Aggresome, Biochemistry, Protein Biosynthesis, Peptides, Release factor, 030217 neurology & neurosurgery, Peptide Termination Factors, Protein Binding, Research Article

Abstract

Polyglutamine expansion causes diseases in humans and other mammals. One example is Huntington's disease. Fragments of human huntingtin protein having an expanded polyglutamine stretch form aggregates and cause cytotoxicity in yeast cells bearing endogenous QN-rich proteins in the aggregated (prion) form. Attachment of the proline(P)-rich region targets polyglutamines to the large perinuclear deposit (aggresome). Aggresome formation ameliorates polyglutamine cytotoxicity in cells containing only the prion form of Rnq1 protein. Here we show that expanded polyglutamines both with (poly-QP) or without (poly-Q) a P-rich stretch remain toxic in the presence of the prion form of translation termination (release) factor Sup35 (eRF3). A Sup35 derivative that lacks the QN-rich domain and is unable to be incorporated into aggregates counteracts cytotoxicity, suggesting that toxicity is due to Sup35 sequestration. Increase in the levels of another release factor, Sup45 (eRF1), due to either disomy by chromosome II containing the SUP45 gene or to introduction of the SUP45-bearing plasmid counteracts poly-Q or poly-QP toxicity in the presence of the Sup35 prion. Protein analysis confirms that polyglutamines alter aggregation patterns of Sup35 and promote aggregation of Sup45, while excess Sup45 counteracts these effects. Our data show that one and the same mode of polyglutamine aggregation could be cytoprotective or cytotoxic, depending on the composition of other aggregates in a eukaryotic cell, and demonstrate that other aggregates expand the range of proteins that are susceptible to sequestration by polyglutamines., Author Summary Polyglutamine diseases, including Huntington disease, are associated with expansions of polyglutamine tracts, resulting in aggregation of respective proteins. The severity of Huntington disease is controlled by both DNA and non–DNA factors. Mechanisms of such a control are poorly understood. Polyglutamine may sequester other cellular proteins; however, different experimental models have pointed to different sequestered proteins. By using a yeast model, we demonstrate that the mechanism of polyglutamine toxicity is driven by the composition of other (endogenous) aggregates (for example, yeast prions) present in a eukaryotic cell. Although these aggregates do not necessarily cause significant toxicity on their own, they serve as mediators in protein sequestration and therefore determine which specific proteins are to be sequestered by polyglutamines. We also show that polyglutamine deposition into an aggresome, a perinuclear compartment thought to be cytoprotective, fails to ameliorate cytotoxicity in cells with certain compositions of pre-existing aggregates. Finally, we demonstrate that an increase in the dosage of a sequestered protein due to aneuploidy by a chromosome carrying a respective gene may rescue cytotoxicity. Our data shed light on genetic and epigenetic mechanisms modulating polyglutamine cytotoxicity and establish a new approach for identifying potential therapeutic targets through characterization of the endogenous aggregated proteins.

Published

2012

5. Abnormal proteins can form aggresome in yeast: aggresome-targeting signals and components of the machinery

Author

Nava Zaarur, Michael Y. Sherman, Yan Wang, Catherine E. Costello, Yury O. Chernoff, Anatoli B. Meriin, and Nina V. Romanova

Subjects

Signal peptide, Huntingtin, Saccharomyces cerevisiae Proteins, Valosin-containing protein, Molecular Sequence Data, Cell Cycle Proteins, Plasma protein binding, Saccharomyces cerevisiae, Biochemistry, Spindle pole body, Substrate Specificity, Research Communications, Ubiquitin, Valosin Containing Protein, Genetics, Amino Acid Sequence, Molecular Biology, Adenosine Triphosphatases, biology, Ubiquitination, Cell biology, Aggresome, 14-3-3 Proteins, Centrosome, biology.protein, Peptides, Biotechnology, Protein Binding, Signal Transduction

Abstract

In mammalian cells, abnormal proteins that escape proteasome-dependent degradation form small aggregates that can be transported into a centrosome-associated structure, called an aggresome. Here we demonstrate that in yeast a single aggregate formed by the huntingtin exon 1 with an expanded polyglutamine domain (103QP) represents a bona fide aggresome that colocalizes with the spindle pole body (the yeast centrosome) in a microtubule-dependent fashion. Since a polypeptide lacking the proline-rich region (P-region) of huntingtin (103Q) cannot form aggresomes, this domain serves as an aggresome-targeting signal. Coexpression of 103Q with 25QP, a soluble polypeptide that also carries the P-region, led to the recruitment of 103Q to the aggresome via formation of hetero-oligomers, indicating the aggresome targeting in trans. To identify additional factors involved in aggresome formation and targeting, we purified 103QP aggresomes and 103Q aggregates and identified the associated proteins using mass spectrometry. Among the aggresome-associated proteins we identified, Cdc48 (VCP/p97) and its cofactors, Ufd1 and Nlp4, were shown genetically to be essential for aggresome formation. The 14-3-3 protein, Bmh1, was also found to be critical for aggresome targeting. Its interaction with the huntingtin fragment and its role in aggresome formation required the huntingtin N-terminal N17 domain, adjacent to the polyQ domain. Accordingly, the huntingtin N17 domain, along with the P-region, plays a role in aggresome targeting. We also present direct genetic evidence for the protective role of aggresomes by demonstrating genetically that aggresome targeting of polyglutamine polypeptides relieves their toxicity.—Wang, Y., Meriin, A. B., Zaarur, N., Romanova, N. V., Chernoff, Y. O., Costello, C. E., Sherman, M. Y. Abnormal proteins can form aggresome in yeast: aggresome-targeting signals and components of the machinery.

Published

2008

6. Inactivation of the Hansenula polymorpha PMR1 gene affects cell viability and functioning of the secretory pathway

Author

T A Plotnikova, Anastasia V. Fokina, Hyun Ah Kang, Michael O. Agaphonov, Michael D. Ter-Avanesyan, A N Packeiser, and Nina V. Romanova

Subjects

Glycosylation, Saccharomyces cerevisiae, Mutant, Calcium-Transporting ATPases, Applied Microbiology and Biotechnology, Microbiology, Pichia, Fungal Proteins, symbols.namesake, Secretion, Secretory pathway, Vacuolar protein sorting, Genes, Essential, Microbial Viability, biology, Endoplasmic reticulum, General Medicine, Golgi apparatus, biology.organism_classification, Urokinase-Type Plasminogen Activator, Recombinant Proteins, Cell biology, Mutagenesis, Insertional, Protein Transport, Secretory protein, symbols, Gene Deletion

Abstract

In yeast, functions of the endoplasmic reticulum (ER) depend on the Golgi apparatus Ca2+ pool, which is replenished by the medial-Golgi ion pump Pmr1p. Here, to dissect the role of the Golgi Ca2+ pool in protein folding and elimination of unfolded proteins in the ER, the manifestations of the pmr1 mutation in yeast Hansenula polymorpha were studied. The PMR1 gene was disrupted in a H. polymorpha diploid strain. Haploid segregants of this diploid bearing the disruption allele were viable, though they showed a severe growth defect on synthetic medium and rapidly died during storage at low temperature. Disruption of H. polymorpha PMR1 led to defects of the Golgi-hosted protein glycosylation and vacuolar protein sorting. This mutation increased the survival rate of H. polymorpha cells upon treatment with the proapoptotic drug amiodarone. Unlike Saccharomyces cerevisiae , the H. polymorpha pmr1 mutant was not hypersensitive to chemicals that induce the accumulation of unfolded proteins in the ER, indicating that the elimination of unfolded proteins from the ER was not essentially affected. At the same time, the pmr1 mutation improved the secretion of human urokinase and decreased its intracellular aggregation, indicating an influence of the mutation on the protein folding in the ER.

Published

2007

7. C-terminal truncation of alpha-COP affects functioning of secretory organelles and calcium homeostasis in Hansenula polymorpha

Author

Alexander V. Deev, Michael O. Agaphonov, Anna N. Packeiser, Maria B. Chechenova, Vladimir N. Smirnov, Michael D. Ter-Avanesyan, and Nina V. Romanova

Subjects

Saccharomyces cerevisiae Proteins, Glycosylphosphatidylinositols, Blotting, Western, Immunoblotting, Molecular Sequence Data, Golgi Apparatus, Calcium-Transporting ATPases, Saccharomyces cerevisiae, Biology, Endoplasmic Reticulum, Microbiology, Coatomer Protein, Pichia, Article, symbols.namesake, Humans, Secretion, Amino Acid Sequence, Cloning, Molecular, Molecular Biology, COPII, Secretory pathway, Membrane Glycoproteins, Models, Genetic, Sequence Homology, Amino Acid, Reverse Transcriptase Polymerase Chain Reaction, Endoplasmic reticulum, Proteins, Biological Transport, General Medicine, COPI, Golgi apparatus, Urokinase-Type Plasminogen Activator, Cell biology, Protein Structure, Tertiary, Vesicular transport protein, Secretory protein, Phenotype, Biochemistry, Mutation, symbols, RNA, Calcium, Molecular Chaperones, Plasmids

Abstract

In eukaryotic cells, COPI vesicles retrieve resident proteins to the endoplasmic reticulum and mediate intra-Golgi transport. Here, we studied the Hansenula polymorpha homologue of the Saccharomyces cerevisiae RET1 gene, encoding -COP, a subunit of the COPI protein complex. H. polymorpha ret1 mutants, which expressed truncated -COP lacking more than 300 C-terminal amino acids, manifested an enhanced ability to secrete human urokinase-type plasminogen activator (uPA) and an inability to grow with a shortage of Ca 2 ions, whereas a lack of -COP expression was lethal. The -COP defect also caused alteration of intracellular transport of the glycosylphosphatidylinositol-anchored protein Gas1p, secretion of abnormal uPA forms, and reductions in the levels of Pmr1p, a Golgi Ca 2 -ATPase. Overexpression of Pmr1p suppressed some ret1 mutant phenotypes, namely, Ca 2 dependence and enhanced uPA secretion. The role of COPI-dependent vesicular transport in cellular Ca 2 homeostasis is discussed. In eukaryotic cells, secretory proteins synthesized at the endoplasmic reticulum (ER) pass through multiple distinct membrane-bound organelles comprising the secretory pathway. Transport of proteins and lipids between membrane compartments of the early secretory system is mediated by COPIand COPII-coated vesicles that capture cargo, bud from the donor membrane, and then target, dock, and fuse with an appropriate acceptor compartment (40). Both the COPI and COPII protein coat complexes employ a GTP switch mechanism for coating and uncoating. The COPII complex mediates selective protein export from the ER, while COPI-coated vesicles retrieve resident proteins to the ER and mediate intraGolgi transport (8, 38).

Published

2004

8. Chaperone Effects on Prion and Nonprion Aggregates

Author

E. G. Rikhvanov, Yury O. Chernoff, and Nina V. Romanova

Subjects

Protein Folding, Hot Temperature, Saccharomyces cerevisiae Proteins, biology, Prions, Saccharomyces cerevisiae, Cell Biology, Review, biology.organism_classification, Biochemistry, Hsp70, Cell biology, Co-chaperone, Cellular and Molecular Neuroscience, Infectious Diseases, JUNQ and IPOD, Heat shock protein, Chaperone (protein), biology.protein, Denaturation (biochemistry), Chemical chaperone, Heat-Shock Proteins

Abstract

Exposure to high temperature or other stresses induces a synthesis of heat shock proteins. Many of these proteins are molecular chaperones, and some of them help cells to cope with heat induced denaturation and aggregation of other proteins. In the last decade, chaperones have received increased attention in connection with their role in maintenance and propagation of the Saccharomyces cerevisiae prions, infectious or heritable agents transmitted at the protein level. Recent data suggest that functioning of the chaperones in reactivation of heat damaged proteins and in propagation of prions is based on the same molecular mechanisms but may lead to different consequences depending on the type of aggregate. In both cases the concerted and balanced action of “chaperones’ team”, including Hsp104, Hsp70, Hsp40 and possibly other proteins, determines whether a misfolded protein is to be incorporated into an aggregate, rescued to the native state or targeted for degradation.