Kaposi’s Sarcoma-Associated Herpesvirus LANA-Adjacent Regions with Distinct Functions in Episome Segregation or Maintenance

ABSTRACTKaposi’s sarcoma-associated herpesvirus (KSHV) latency-associated nuclear antigen (LANA) is a 1,162-amino-acid protein that mediates episome persistence of viral genomes. LANA binds the KSHV terminal-repeat (TR) sequence through its carboxy-terminal domain to mediate DNA replication. LANA simultaneously binds mitotic chromosomes and TR DNA to segregate virus genomes to daughter cell nuclei. Amino-terminal LANA attaches to chromosomes by binding histones H2A/H2B, and carboxy-terminal LANA contributes to mitotic-chromosome binding. Although amino- and carboxy-terminal LANA are essential for episome persistence, they are not sufficient, since deletion of all internal LANA sequence renders LANA highly deficient for episome maintenance. Internal LANA sequence upstream of the internal repeat elements contributes to episome segregation and persistence. Here, we investigate this region with a panel of LANA deletion mutants. Mutants retained the ability to associate with mitotic chromosomes and bind TR DNA. In contrast to prior results, deletion of most of this sequence did not reduce LANA’s ability to mediate DNA replication. Deletions of upstream sequence within the region compromised segregation of TR DNA to daughter cells, as assessed by retention of green fluorescent protein (GFP) expression from a replication-deficient TR plasmid. However, deletion of this upstream sequence did not reduce episome maintenance. In contrast, deletions that included an 80-amino-acid sequence immediately downstream resulted in highly deficient episome persistence. LANA with this downstream sequence deleted maintained the ability to replicate and segregate TR DNA, suggesting a unique role for the residues. Therefore, this work identifies adjacent LANA regions with distinct roles in episome segregation and persistence.IMPORTANCEKSHV LANA mediates episomal persistence of viral genomes. LANA binds the KSHV terminal-repeat (TR) sequence to mediate DNA replication and tethers KSHV DNA to mitotic chromosomes to segregate genomes to daughter cell nuclei. Here, we investigate LANA sequence upstream of the internal repeat elements that contributes to episome segregation and persistence. Mutants with deletions within this sequence maintained the ability to bind mitotic chromosomes or bind and replicate TR DNA. Deletion of upstream sequence within the region reduced segregation of TR DNA to daughter cells, but not episome maintenance. In contrast, mutants with deletions of 80 amino acids immediately downstream were highly deficient for episome persistence yet maintained the ability to replicate and segregate TR DNA, the two principal components of episome persistence, suggesting another role for the residues. In summary, this work identifies adjacent LANA sequence with distinct roles in episome segregation and persistence.

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Active gelation breaks time-reversal-symmetry of mitotic chromosome mechanics

10.1101/296566 ◽

2018 ◽

Author(s):

Matthäus Mittasch ◽

Anatol W. Fritsch ◽

Michael Nestler ◽

Juan M. Iglesias-Artola ◽

Kaushikaram Subramanian ◽

...

Keyword(s):

Symmetry Breaking ◽

Time Reversal ◽

Mitotic Chromosome ◽

Metaphase Plate ◽

Time Reversal Symmetry ◽

Newtonian Mechanics ◽

Arrow Of Time ◽

Cell Nuclei ◽

Mitotic Chromosomes ◽

Daughter Cells

AbstractIn cell division, mitosis is the phase in which duplicated sets of chromosomes are mechanically aligned to form the metaphase plate before being segregated in two daughter cells. Irreversibility is a hallmark of this process, despite the fundamental laws of Newtonian mechanics being time symmetric.Here we show experimentally that mitotic chromosomes receive the arrow of time by time-reversal-symmetry breaking of the underlying mechanics in prometaphase. By optically inducing hydrodynamic flows within prophase nuclei, we find that duplicated chromatid pairs initially form a fluid suspension in the nucleoplasm: although showing little motion on their own, condensed chromosomes are free to move through the nucleus in a time-reversible manner. Actively probing chromosome mobility further in time, we find that this viscous suspension of chromatin transitions into a gel after nuclear breakdown. This gel state, in which chromosomes cannot be moved by flows, persists even when chromosomes start moving to form the metaphase plate. Complemented by minimal reconstitution experiments, our active intra-nuclear micro-rheology reveals time-reversal-symmetry breaking of chromosome mechanics to be caused by the transition from a purely fluid suspension into an active gel.Graphical abstractOne sentence summaryFlows induced in living cell nuclei reveal the rheological changes that bring chromosomes under mechanical control during mitosis.

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Nuclear Lamins a and B1

The Journal of Cell Biology ◽

10.1083/jcb.151.6.1155 ◽

2000 ◽

Vol 151 (6) ◽

pp. 1155-1168 ◽

Cited By ~ 253

Author(s):

Robert D. Moir ◽

Miri Yoon ◽

Satya Khuon ◽

Robert D. Goldman

Keyword(s):

Green Fluorescent Protein ◽

Nuclear Envelope ◽

Daughter Cell ◽

Fluorescent Protein ◽

Lamin A ◽

Cell Nuclei ◽

Nuclear Lamins ◽

Daughter Cells ◽

Lamin B1 ◽

Green Fluorescent

At the end of mitosis, the nuclear lamins assemble to form the nuclear lamina during nuclear envelope formation in daughter cells. We have fused A- and B-type nuclear lamins to the green fluorescent protein to study this process in living cells. The results reveal that the A- and B-type lamins exhibit different pathways of assembly. In the early stages of mitosis, both lamins are distributed throughout the cytoplasm in a diffusible (nonpolymerized) state, as demonstrated by fluorescence recovery after photobleaching (FRAP). During the anaphase-telophase transition, lamin B1 begins to become concentrated at the surface of the chromosomes. As the chromosomes reach the spindle poles, virtually all of the detectable lamin B1 has accumulated at their surfaces. Subsequently, this lamin rapidly encloses the entire perimeter of the region containing decondensing chromosomes in each daughter cell. By this time, lamin B1 has assembled into a relatively stable polymer, as indicated by FRAP analyses and insolubility in detergent/high ionic strength solutions. In contrast, the association of lamin A with the nucleus begins only after the major components of the nuclear envelope including pore complexes are assembled in daughter cells. Initially, lamin A is found in an unpolymerized state throughout the nucleoplasm of daughter cell nuclei in early G1 and only gradually becomes incorporated into the peripheral lamina during the first few hours of this stage of the cell cycle. In later stages of G1, FRAP analyses suggest that both green fluorescent protein lamins A and B1 form higher order polymers throughout interphase nuclei.

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A short sequence immediately upstream of the internal repeat elements is critical for KSHV LANA mediated DNA replication and impacts episome persistence

Virology ◽

10.1016/j.virol.2013.10.026 ◽

2014 ◽

Vol 448 ◽

pp. 344-355 ◽

Cited By ~ 9

Author(s):

Erika De León Vázquez ◽

Franceline Juillard ◽

Bernard Rosner ◽

Kenneth M. Kaye

Keyword(s):

Dna Replication ◽

Short Sequence ◽

Repeat Elements ◽

Internal Repeat

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Phosphorylation Regulates Binding of the Human Papillomavirus Type 8 E2 Protein to Host Chromosomes

Journal of Virology ◽

10.1128/jvi.01140-12 ◽

2012 ◽

Vol 86 (18) ◽

pp. 10047-10058 ◽

Cited By ~ 18

Author(s):

Vandana Sekhar ◽

Alison A. McBride

Keyword(s):

Human Papillomavirus ◽

Posttranslational Modifications ◽

S Phase ◽

Chromatin Binding ◽

Genome Maintenance ◽

Mitotic Chromosomes ◽

E2 Protein ◽

Viral Genomes ◽

Daughter Cells ◽

Host Nucleus

The papillomavirus E2 proteins are indispensable for the viral life cycle, and their functions are subject to tight regulation. The E2 proteins undergo posttranslational modifications that regulate their properties and roles in viral transcription, replication, and genome maintenance. During persistent infection, the E2 proteins from many papillomaviruses act as molecular bridges that tether the viral genomes to host chromosomes to retain them within the host nucleus and to partition them to daughter cells. The betapapillomavirus E2 proteins bind to pericentromeric regions of host mitotic chromosomes, including the ribosomal DNA loci. We recently reported that two residues (arginine 250 and serine 253) within the chromosome binding region of the human papillomavirus type 8 (HPV8) E2 protein are required for this binding. In this study, we show that serine 253 is phosphorylated, most likely by protein kinase A, and this modulates the interaction of the E2 protein with cellular chromatin. Furthermore, we show that this phosphorylation occurs in S phase, increases the half-life of the E2 protein, and promotes chromatin binding from S phase through mitosis.

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Sequential Counteracting Kinases Restrict an Asymmetric Gene Expression Program to early G1

Molecular Biology of the Cell ◽

10.1091/mbc.e10-02-0174 ◽

2010 ◽

Vol 21 (16) ◽

pp. 2809-2820 ◽

Cited By ~ 25

Author(s):

Emily Mazanka ◽

Eric L. Weiss

Keyword(s):

Gene Expression ◽

Cell Cycle ◽

Daughter Cell ◽

Kinase Activity ◽

Hippo Signaling ◽

Transcriptional Program ◽

Cell Nuclei ◽

Daughter Cells ◽

Spatiotemporal Regulation ◽

Expression Program

Gene expression is restricted to specific times in cell division and differentiation through close control of both activation and inactivation of transcription. In budding yeast, strict spatiotemporal regulation of the transcription factor Ace2 ensures that it acts only once in a cell's lifetime: at the M-to-G1 transition in newborn daughter cells. The Ndr/LATS family kinase Cbk1, functioning in a system similar to metazoan hippo signaling pathways, activates Ace2 and drives its accumulation in daughter cell nuclei, but the mechanism of this transcription factor's inactivation is unknown. We found that Ace2's nuclear localization is maintained by continuous Cbk1 activity and that inhibition of the kinase leads to immediate loss of phosphorylation and export to the cytoplasm. Once exported, Ace2 cannot re-enter nuclei for the remainder of the cell cycle. Two separate mechanisms enforce Ace2's cytoplasmic sequestration: 1) phosphorylation of CDK consensus sites in Ace2 by the G1 CDKs Pho85 and Cdc28/CDK1 and 2) an unknown mechanism mediated by Pho85 that is independent of its kinase activity. Direct phosphorylation of CDK consensus sites is not necessary for Ace2's cytoplasmic retention, indicating that these mechanisms function redundantly. Overall, these findings show how sequential opposing kinases limit a daughter cell specific transcriptional program to a brief period during the cell cycle and suggest that CDKs may function as cytoplasmic sequestration factors.

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Targeting mitotic chromosomes: a conserved mechanism to ensure viral genome persistence

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2008.1642 ◽

2009 ◽

Vol 276 (1662) ◽

pp. 1535-1544 ◽

Cited By ~ 21

Author(s):

Katherine M Feeney ◽

Joanna L Parish

Keyword(s):

Host Cell ◽

Genetic Material ◽

Membrane Integrity ◽

Mitotic Chromosomes ◽

Nuclear Retention ◽

Viral Genomes ◽

Daughter Cells ◽

Dna Damage Checkpoints ◽

Low Copy Number ◽

Dividing Cells

Viruses that maintain their genomes as extrachromosomal circular DNA molecules and establish infection in actively dividing cells must ensure retention of their genomes within the nuclear envelope in order to prevent genome loss. The loss of nuclear membrane integrity during mitosis dictates that paired host cell chromosomes are captured and organized by the mitotic spindle apparatus before segregation to daughter cells. This prevents inaccurate chromosomal segregation and loss of genetic material. A similar mechanism may also exist for the nuclear retention of extrachromosomal viral genomes or episomes during mitosis, particularly for genomes maintained at a low copy number in latent infections. It has been heavily debated whether such a mechanism exists and to what extent this mechanism is conserved among diverse viruses. Research over the last two decades has provided a wealth of information regarding the mechanisms by which specific tumour viruses evade mitotic and DNA damage checkpoints. Here, we discuss the similarities and differences in how specific viruses tether episomal genomes to host cell chromosomes during mitosis to ensure long-term persistence.

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The mitotic spindle mediates inheritance of the Golgi ribbon structure

The Journal of Cell Biology ◽

10.1083/jcb.200809090 ◽

2009 ◽

Vol 184 (3) ◽

pp. 391-397 ◽

Cited By ~ 35

Author(s):

Jen-Hsuan Wei ◽

Joachim Seemann

Keyword(s):

Mitotic Spindle ◽

Daughter Cell ◽

Daughter Cells ◽

Spindle Poles ◽

Golgi Membranes ◽

Ribbon Structure ◽

Golgi Ribbon

The mammalian Golgi ribbon disassembles during mitosis and reforms in both daughter cells after division. Mitotic Golgi membranes concentrate around the spindle poles, suggesting that the spindle may control Golgi partitioning. To test this, cells were induced to divide asymmetrically with the entire spindle segregated into only one daughter cell. A ribbon reforms in the nucleated karyoplasts, whereas the Golgi stacks in the cytoplasts are scattered. However, the scattered Golgi stacks are polarized and transport cargo. Microinjection of Golgi extract together with tubulin or incorporation of spindle materials rescues Golgi ribbon formation. Therefore, the factors required for postmitotic Golgi ribbon assembly are transferred by the spindle, but the constituents of functional stacks are partitioned independently, suggesting that Golgi inheritance is regulated by two distinct mechanisms.

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Persistent Human Papillomavirus Infection

Viruses ◽

10.3390/v13020321 ◽

2021 ◽

Vol 13 (2) ◽

pp. 321

Author(s):

Ashley N. Della Fera ◽

Alix Warburton ◽

Tami L. Coursey ◽

Simran Khurana ◽

Alison A. McBride

Keyword(s):

Human Papillomavirus ◽

Dna Replication ◽

Cellular Proliferation ◽

Basal Cells ◽

Viral Dna ◽

Viral Dna Replication ◽

Viral Genomes ◽

Cellular Environment ◽

E6 And E7 ◽

Cellular Replication

Persistent infection with oncogenic human papillomavirus (HPV) types is responsible for ~5% of human cancers. The HPV infectious cycle can sustain long-term infection in stratified epithelia because viral DNA is maintained as low copy number extrachromosomal plasmids in the dividing basal cells of a lesion, while progeny viral genomes are amplified to large numbers in differentiated superficial cells. The viral E1 and E2 proteins initiate viral DNA replication and maintain and partition viral genomes, in concert with the cellular replication machinery. Additionally, the E5, E6, and E7 proteins are required to evade host immune responses and to produce a cellular environment that supports viral DNA replication. An unfortunate consequence of the manipulation of cellular proliferation and differentiation is that cells become at high risk for carcinogenesis.

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Interaction of the Putative Human Cytomegalovirus Portal Protein pUL104 with the Large Terminase Subunit pUL56 and Its Inhibition by Benzimidazole-d-Ribonucleosides

Journal of Virology ◽

10.1128/jvi.79.23.14660-14667.2005 ◽

2005 ◽

Vol 79 (23) ◽

pp. 14660-14667 ◽

Cited By ~ 48

Author(s):

Alexandra Dittmer ◽

John C. Drach ◽

Leroy B. Townsend ◽

Anke Fischer ◽

Elke Bogner

Keyword(s):

Dna Replication ◽

Human Cytomegalovirus ◽

Unit Length ◽

Large Subunit ◽

Intracellular Localization ◽

Direct Interaction ◽

Portal Protein ◽

Specific Association ◽

Carboxy Terminal

ABSTRACT Herpesvirus DNA replication leads to unit length genomes that are translocated into preformed procapsids through a unique portal vertex. The translocation is performed by the terminase that cleaves the DNA and powers the insertion by its ATPase activity. Recently, we demonstrated that the putative human cytomegalovirus (HCMV) portal protein, pUL104, also forms high-molecular-weight complexes. Analyses now have been performed to determine the intracellular localization and identification of interaction partners of pUL104. In infected cells, HCMV pUL104 was found to be predominantly localized throughout the nucleus as well as in cytoplasmic clusters at late times of infection. The latter localization was abolished by phosphonoacetic acid, an inhibitor of viral DNA replication. Immunofluorescence revealed that pUL104 colocalized with pUL56, the large subunit of the HCMV terminase. Specific association of in vitro translated pUL104 with the carboxy-terminal half of GST-UL56C was detected. By using coimmunoprecipitations a direct interaction with pUL56 was confirmed. In addition, this interaction was no longer detected when the benzimidazole-d-nucleosides BDCRB or Cl4RB were added, thus indicating that these HCMV inhibitors block the insertion of the DNA into the capsid by preventing a necessary interaction of pUL56 with the portal. Electron microscopy revealed that in the presence of Cl4RB DNA is not packaged into capsids and these capsids failed to egress from the nucleus. Furthermore, pulsed-field gel electrophoresis showed that DNA concatemers synthesized in the presence of the compound failed to be processed.

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Daughter cells of Saccharomyces cerevisiae from old mothers display a reduced life span.

The Journal of Cell Biology ◽

10.1083/jcb.127.6.1985 ◽

1994 ◽

Vol 127 (6) ◽

pp. 1985-1993 ◽

Cited By ~ 215

Author(s):

B K Kennedy ◽

N R Austriaco ◽

L Guarente

Keyword(s):

Saccharomyces Cerevisiae ◽

Life Span ◽

Daughter Cell ◽

Young Mothers ◽

Young Mother ◽

Yeast Saccharomyces Cerevisiae ◽

Daughter Cells ◽

Per Se ◽

Mother Cells ◽

Maximum Occurrence

The yeast Saccharomyces cerevisiae typically divides asymmetrically to give a large mother cell and a smaller daughter cell. As mother cells become old, they enlarge and produce daughter cells that are larger than daughters derived from young mother cells. We found that occasional daughter cells were indistinguishable in size from their mothers, giving rise to a symmetric division. The frequency of symmetric divisions became greater as mother cells aged and reached a maximum occurrence of 30% in mothers undergoing their last cell division. Symmetric divisions occurred similarly in rad9 and ste12 mutants. Strikingly, daughters from old mothers, whether they arose from symmetric divisions or not, displayed reduced life spans relative to daughters from young mothers. Because daughters from old mothers were larger than daughters from young mothers, we investigated whether an increased size per se shortened life span and found that it did not. These findings are consistent with a model for aging that invokes a senescence substance which accumulates in old mother cells and is inherited by their daughters.

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