Your search keyword '"Reiff SB"' showing total 9 results

1. The Macronuclear Genome of $\textit{Stentor coeruleus}$ Reveals Tiny Introns in a Giant Cell

Author

Slabodnick, MM, Ruby, JG, Reiff, SB, Swart, EC, Gosai, S, Prabakaran, S, Witkowska, E, Larue, GE, Fisher, S, Freeman, RM, Gunawardena, J, Chu, W, Stover, NA, Gregory, BD, Nowacki, M, Derisi, J, Roy, SW, Marshall, WF, Sood, P, Prabakaran, Sudhakaran [0000-0002-6527-1085], and Apollo - University of Cambridge Repository

Subjects

genetic code, cell size, splicing, intron evolution, heterotrichidae, regeneration, ploidy, macronucleus, ciliate, U2 snRNA

Abstract

The giant, single-celled organism $\textit{Stentor coeruleus}$ has a long history as a model system for studying pattern formation and regeneration in single cells. $\textit{Stentor coeruleus}$ [1, 2] is a heterotrichous ciliate distantly related to familiar ciliate models, such as Tetrahymena or Paramecium. The primary distinguishing feature of $\textit{Stentor}$ is its incredible size: a single cell is 1 mm long. Early developmental biologists, including T.H. Morgan [3], were attracted to the system because of its regenerative abilities-if large portions of a cell are surgically removed, the remnant reorganizes into a normal-looking but smaller cell with correct proportionality [2, 3]. These biologists were also drawn to $\textit{Stentor}$ because it exhibits a rich repertoire of behaviors, including light avoidance, mechanosensitive contraction, food selection, and even the ability to habituate to touch, a simple form of learning usually seen in higher organisms [4]. While early microsurgical approaches demonstrated a startling array of regenerative and morphogenetic processes in this single-celled organism, $\textit{Stentor}$ was never developed as a molecular model system. We report the sequencing of the $\textit{Stentor coeruleus}$ macronuclear genome and reveal key features of the genome. First, we find that $\textit{Stentor}$ uses the standard genetic code, suggesting that ciliate-specific genetic codes arose after $\textit{Stentor}$ branched from other ciliates. We also discover that ploidy correlates with $\textit{Stentor}$'s cell size. Finally, in the $\textit{Stentor}$ genome, we discover the smallest spliceosomal introns reported for any species. The sequenced genome opens the door to molecular analysis of single-cell regeneration in $\textit{Stentor}$.

Published

2017

2. Author Correction: The 4D Nucleome Data Portal as a resource for searching and visualizing curated nucleomics data.

Author

Reiff SB, Schroeder AJ, Kırlı K, Cosolo A, Bakker C, Mercado L, Lee S, Veit AD, Balashov AK, Vitzthum C, Ronchetti W, Pitman KM, Johnson J, Ehmsen SR, Kerpedjiev P, Abdennur N, Imakaev M, Öztürk SU, Çamoğlu U, Mirny LA, Gehlenborg N, Alver BH, and Park PJ

Published

2022

3. The 4D Nucleome Data Portal as a resource for searching and visualizing curated nucleomics data.

Author

Reiff SB, Schroeder AJ, Kırlı K, Cosolo A, Bakker C, Mercado L, Lee S, Veit AD, Balashov AK, Vitzthum C, Ronchetti W, Pitman KM, Johnson J, Ehmsen SR, Kerpedjiev P, Abdennur N, Imakaev M, Öztürk SU, Çamoğlu U, Mirny LA, Gehlenborg N, Alver BH, and Park PJ

Subjects

Cell Nucleus genetics, Genome, Chromosomes genetics, Software

Abstract

The 4D Nucleome (4DN) Network aims to elucidate the complex structure and organization of chromosomes in the nucleus and the impact of their disruption in disease biology. We present the 4DN Data Portal ( https://data.4dnucleome.org/ ), a repository for datasets generated in the 4DN network and relevant external datasets. Datasets were generated with a wide range of experiments, including chromosome conformation capture assays such as Hi-C and other innovative sequencing and microscopy-based assays probing chromosome architecture. All together, the 4DN data portal hosts more than 1800 experiment sets and 36000 files. Results of sequencing-based assays from different laboratories are uniformly processed and quality-controlled. The portal interface allows easy browsing, filtering, and bulk downloads, and the integrated HiGlass genome browser allows interactive visualization and comparison of multiple datasets. The 4DN data portal represents a primary resource for chromosome contact and other nuclear architecture data for the scientific community., (© 2022. The Author(s).)

Published

2022

4. Replication and partitioning of the apicoplast genome of Toxoplasma gondii is linked to the cell cycle and requires DNA polymerase and gyrase.

Author

Martins-Duarte ÉS, Sheiner L, Reiff SB, de Souza W, and Striepen B

Subjects

Cell Division, Humans, Toxoplasmosis, Apicoplasts genetics, DNA Gyrase, DNA-Directed DNA Polymerase, Toxoplasma enzymology, Toxoplasma genetics

Abstract

Apicomplexans are the causative agents of numerous important infectious diseases including malaria and toxoplasmosis. Most of them harbour a chloroplast-like organelle called the apicoplast that is essential for the parasites' metabolism and survival. While most apicoplast proteins are nuclear encoded, the organelle also maintains its own genome, a 35 kb circle. In this study we used Toxoplasma gondii to identify and characterise essential proteins involved in apicoplast genome replication and to understand how apicoplast genome segregation unfolds over time. We demonstrated that the DNA replication enzymes Prex, DNA gyrase and DNA single stranded binding protein localise to the apicoplast. We show in knockdown experiments that apicoplast DNA Gyrase A and B, and Prex are required for apicoplast genome replication and growth of the parasite. Analysis of apicoplast genome replication by structured illumination microscopy in T. gondii tachyzoites showed that apicoplast nucleoid division and segregation initiate at the beginning of S phase and conclude during mitosis. Thus, the replication and division of the apicoplast nucleoid is highly coordinated with nuclear genome replication and mitosis. Our observations highlight essential components of apicoplast genome maintenance and shed light on the timing of this process in the context of the overall parasite cell cycle., (Copyright © 2021 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published

2021

5. Aurora kinase inhibitors delay regeneration in Stentor coeruleus at an intermediate step.

Author

Lin A, Summers D, Reiff SB, Tipton AR, Tang SK, and Marshall WF

Abstract

The giant unicellular ciliate Stentor coeruleus can be cut into pieces and each piece will regenerate into a healthy, full-sized individual. The molecular mechanism for how Stentor regenerates is a complete mystery, however, the process of regeneration shows striking similarities to the process of cell division. On a morphological level, the process of creating a second mouth in division or a new oral apparatus in regeneration have the same steps and occur in the same order. On the transcriptional level, genes encoding elements of the cell division and cell cycle regulatory machinery, including Aurora kinases, are differentially expressed during regeneration. This suggests that there may be some common regulatory mechanisms involved in both regeneration and cell division. If the cell cycle machinery really does play a role in regeneration, then inhibition of proteins that regulate the timing of cell division may also affect the timing of regeneration in Stentor. Here we show that two well-characterized Aurora kinase A+B inhibitors that affect the timing of regeneration. ZM447439 slows down regeneration by at least one hour. PF03814735 completely suppresses regeneration until the drug is removed. Here we provide the first direct experimental evidence that Stentor may harness the cell division machinery to regulate the sequential process of regeneration., Competing Interests: Conflict of interest The authors declare no conflicts of interest.

Published

2020

6. The Macronuclear Genome of Stentor coeruleus Reveals Tiny Introns in a Giant Cell.

Author

Slabodnick MM, Ruby JG, Reiff SB, Swart EC, Gosai S, Prabakaran S, Witkowska E, Larue GE, Fisher S, Freeman RM Jr, Gunawardena J, Chu W, Stover NA, Gregory BD, Nowacki M, Derisi J, Roy SW, Marshall WF, and Sood P

Subjects

Phylogeny, Whole Genome Sequencing, Ciliophora genetics, Genome, Protozoan, Introns genetics, Spliceosomes metabolism

Abstract

The giant, single-celled organism Stentor coeruleus has a long history as a model system for studying pattern formation and regeneration in single cells. Stentor [1, 2] is a heterotrichous ciliate distantly related to familiar ciliate models, such as Tetrahymena or Paramecium. The primary distinguishing feature of Stentor is its incredible size: a single cell is 1 mm long. Early developmental biologists, including T.H. Morgan [3], were attracted to the system because of its regenerative abilities-if large portions of a cell are surgically removed, the remnant reorganizes into a normal-looking but smaller cell with correct proportionality [2, 3]. These biologists were also drawn to Stentor because it exhibits a rich repertoire of behaviors, including light avoidance, mechanosensitive contraction, food selection, and even the ability to habituate to touch, a simple form of learning usually seen in higher organisms [4]. While early microsurgical approaches demonstrated a startling array of regenerative and morphogenetic processes in this single-celled organism, Stentor was never developed as a molecular model system. We report the sequencing of the Stentor coeruleus macronuclear genome and reveal key features of the genome. First, we find that Stentor uses the standard genetic code, suggesting that ciliate-specific genetic codes arose after Stentor branched from other ciliates. We also discover that ploidy correlates with Stentor's cell size. Finally, in the Stentor genome, we discover the smallest spliceosomal introns reported for any species. The sequenced genome opens the door to molecular analysis of single-cell regeneration in Stentor., (Copyright © 2017 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2017

7. The HU protein is important for apicoplast genome maintenance and inheritance in Toxoplasma gondii.

Author

Reiff SB, Vaishnava S, and Striepen B

Subjects

DNA-Binding Proteins genetics, Humans, Plastids metabolism, Protozoan Proteins genetics, Toxoplasma growth & development, Toxoplasma metabolism, Toxoplasmosis parasitology, DNA-Binding Proteins metabolism, Genome, Plastid, Plastids genetics, Protozoan Proteins metabolism, Toxoplasma genetics

Abstract

The apicoplast, a chloroplast-like organelle, is an essential cellular component of most apicomplexan parasites, including Plasmodium and Toxoplasma. The apicoplast maintains its own genome, a 35-kb DNA molecule that largely encodes proteins required for organellar transcription and translation. Interference with apicoplast genome maintenance and function is a validated target for drug therapy for malaria and toxoplasmosis. However, the many proteins required for genome maintenance and inheritance remain largely unstudied. Here we genetically characterize a nucleus-encoded homolog to the bacterial HU protein in Toxoplasma gondii. In bacteria, HU is a DNA-binding structural protein with fundamental roles in transcription, replication initiation, and DNA repair. Immunofluorescence assays reveal that in T. gondii this protein localizes to the apicoplast. We have found that the HU protein from Toxoplasma can successfully complement bacterial ΔhupA mutants, supporting a similar function. We were able to construct a genetic knockout of HU in Toxoplasma. This Δhu mutant is barely viable and exhibits significant growth retardation. Upon further analysis of the mutant phenotype, we find that this mutant has a dramatically reduced apicoplast genome copy number and, furthermore, suffers defects in the segregation of the apicoplast organelle. Our findings not only show that the HU protein is important for Toxoplasma cell biology but also demonstrate the importance of the apicoplast genome in the biogenesis of the organelle.

Published

2012

8. Malaria: The gatekeeper revealed.

Author

Reiff SB and Striepen B

Subjects

Animals, Humans, Malaria, Falciparum drug therapy, Models, Biological, Protein Binding, Protein Transport, Protozoan Proteins antagonists & inhibitors, Vacuoles metabolism, Vacuoles parasitology, Malaria, Falciparum parasitology, Plasmodium falciparum metabolism, Protozoan Proteins metabolism

Published

2009

9. A novel dynamin-related protein has been recruited for apicoplast fission in Toxoplasma gondii.

Author

van Dooren GG, Reiff SB, Tomova C, Meissner M, Humbel BM, and Striepen B

Subjects

Animals, Cells, Cultured, Dynamins genetics, Fibroblasts cytology, Fibroblasts metabolism, Humans, Microtubule-Associated Proteins classification, Microtubule-Associated Proteins genetics, Microtubule-Associated Proteins metabolism, Organelles ultrastructure, Phylogeny, Protozoan Proteins classification, Protozoan Proteins genetics, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Dynamins metabolism, Organelles metabolism, Protozoan Proteins metabolism, Toxoplasma cytology, Toxoplasma metabolism

Abstract

Background: Apicomplexan parasites cause numerous important human diseases, including malaria and toxoplasmosis. Apicomplexa belong to the Alveolata, a group that also includes ciliates and dinoflagellates. Apicomplexa retain a plastid organelle (the apicoplast) that was derived from an endosymbiotic relationship between the alveolate ancestor and a red alga. Apicoplasts are essential for parasite growth and must correctly divide and segregate into daughter cells upon cytokinesis. Apicoplast division depends on association with the mitotic spindle, although little is known about the molecular machinery involved in this process. Apicoplasts lack the conserved machinery that divides chloroplasts in plants and red algae, suggesting that these mechanisms are unique., Results: Here, we demonstrate that a dynamin-related protein in Toxoplasma gondii (TgDrpA) localizes to punctate regions on the apicoplast surface. We generate a conditional dominant-negative TgDrpA cell line to disrupt TgDrpA functions and demonstrate that TgDrpA is essential for parasite growth and apicoplast biogenesis. Fluorescence recovery after photobleaching and time-lapse imaging studies provide evidence for a direct role for TgDrpA in apicoplast fission., Conclusions: Our data suggest that DrpA was likely recruited from the alveolate ancestor to function in fission of the symbiont and ultimately replaced the conserved division machinery of that symbiont.

Published

2009