Cell cycle acceleration and changes in essential nuclear functions induced by simulated microgravity in a synchronized <i>Arabidopsis</i> cell culture

Kamal, Khaled Y.; Herranz, Raúl; Loon, Jack J. W. A. van; Medina, F. Javier

doi:10.1111/pce.13422

Cited by 25 publications

(27 citation statements)

References 82 publications

(127 reference statements)

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“…In contrast with the downregulation of phototropism and related biosynthetic and metabolic pathways, we found two very clearly upregulated functions in microgravity‐grown seedlings when compared to 1‐ g spaceflight samples: ribosome biosynthesis and oxidative phosphorylation (Appendices S16 and S17). In both true microgravity (Matía et al., ) and different simulated microgravity facilities using both seedlings and cell cultures (Manzano et al., ; Kamal et al., ), ribosome biogenesis was reduced. Our recent spaceflight results showed that red light can compensate for this effect (Valbuena et al., ), particularly by increasing cell growth (measured by means of ribosome biosynthesis in the nucleolus) that was depleted without light stimulation.…”

Section: Discussionmentioning

confidence: 99%

“…In terms of cell growth and cell proliferation, it has been shown that when seedlings are grown in darkness, there is a lack of balance between these key plant development functions in microgravity (Matía et al., ). Further evidence for this observation was provided by analyzing a dark‐grown, synchronized cell culture grown in simulated microgravity (Kamal et al., ). Recent spaceflight results show that red light can compensate for this effect (Valbuena et al., ), particularly increasing cell growth (measured by means of ribosome biosynthesis in the nucleolus) that was depleted without light stimulation.…”

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confidence: 91%

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RNA‐seq analyses of Arabidopsis thaliana seedlings after exposure to blue‐light phototropic stimuli in microgravity

Vandenbrink

Herranz

Poehlman

et al. 2019

American J of Botany

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Kiss. 2019. RNA-seq analyses of Arabidopsis thaliana seedlings after exposure to blue-light phototropic stimuli in microgravity. PREMISE: Plants synthesize information from multiple environmental stimuli when determining their direction of growth. Gravity, being ubiquitous on Earth, plays a major role in determining the direction of growth and overall architecture of the plant. Here, we utilized the microgravity environment on board the International Space Station (ISS) to identify genes involved influencing growth and development of phototropically stimulated seedlings of Arabidopsis thaliana.METHODS: Seedlings were grown on the ISS, and RNA was extracted from 7 samples (pools of 10-15 plants) grown in microgravity (μg) or Earth gravity conditions (1-g). Transcriptomic analyses via RNA sequencing (RNA-seq) of differential gene expression was performed using the HISAT2-Stringtie-DESeq2 RNASeq pipeline. Differentially expressed genes were further characterized by using Pathway Analysis and enrichment for Gene Ontology classifications. RESULTS:For 296 genes that were found significantly differentially expressed between plants in microgravity compared to 1-g controls, Pathway Analysis identified eight molecular pathways that were significantly affected by reduced gravity conditions. Specifically, light-associated pathways (e.g., photosynthesis-antenna proteins, photosynthesis, porphyrin, and chlorophyll metabolism) were significantly downregulated in microgravity. CONCLUSIONS:Gene expression in A. thaliana seedlings grown in microgravity was significantly altered compared to that of the 1-g control. Understanding how plants grow in conditions of microgravity not only aids in our understanding of how plants grow and respond to the environment but will also help to efficiently grow plants during long-range space missions. ACKNOWLEDGMENTSFunding was provided by grants NNX12A065G and 80NSSC17K0546 from NASA (PI = J. Z. Kiss). We thank the reviewers for insightful comments and review in preparation of this manuscript. DATA AVAILABILITYAll sequences generated in this study are deposited in NASA GenLab (https ://genel ab.nasa.gov/) as data set GLDS 251. SUPPORTING INFORMATIONAdditional Supporting Information may be found online in the supporting information tab for this article. APPENDIX S1. FASTQC results for pooled sample #111: microgravity (A) forward and (B) reverse paired-end reads. APPENDIX S2. FASTQC results for pooled sample #114: microgravity (A) forward and (B) reverse paired-end reads. APPENDIX S3. FASTQC results for pooled sample #116: microgravity (A) forward and (B) reverse paired-end reads. APPENDIX S4. FASTQC results for pooled sample #120: microgravity (A) forward and (B) reverse paired-end reads. APPENDIX S5. FASTQC results for pooled sample #175: 1-g (A) forward and (B) reverse paired-end reads.APPENDIX S6. FASTQC results for pooled sample # 179: 1-g (A) forward and (B) reverse paired-end reads. APPENDIX S7. FASTQC results for pooled sample # 235-239: 1-g (A) forward and (B) reverse paired-end reads. AP...

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 91%

RNA‐seq analyses of Arabidopsis thaliana seedlings after exposure to blue‐light phototropic stimuli in microgravity

Vandenbrink

Herranz

Poehlman

et al. 2019

American J of Botany

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“…These reference times have been confirmed by flow cytometry in a parallel experiment with aliquots of the same cell culture system and microgravity simulator conditions as described here [28]. Cells were recovered from the agorose and frozen until RNA extraction.…”

Section: Microgravity Simulator and Experimental Designmentioning

confidence: 69%

“…Since we had previously established that there was a quick entry into M phase under simulated microgravity conditions [28], agarose-embedded cultures (synchronous and asynchronous subpopulations) were exposed to simulated microgravity conditions for different experimental durations accordingly. To obtain the maximum enrichment in each cell cycle subpopulation (higher than 2/3 of the cell population), the exposure time was 7h RPM / 10h 1g control hours for the G2/M synchronized samples, 14h RPM / 16h 1g control for the G1 synchronized cells and 14h RPM / 14h 1g control for the asynchronous reference cells.…”

Section: Microgravity Simulator and Experimental Designmentioning

confidence: 99%

“…The simulated microgravity methodology has already been validated in this cell culture system [26,27], and an effect on cell cycle regulation was observed in non-synchronous populations [25]. To reveal the transcriptional mechanisms of the plant response to the simulated microgravity environment, we performed a microarraybased transcriptomic approach on immobilized and synchronized cell cultures (enriched in G2/M and G1 cells as described in [28]) grown under simulated microgravity conditions produced in a Random Positioning Machine (RPM). This allowed us to confirm and extend previously described alterations in cell cycle and to provide new insights into the stress pathways involved in the response to altered gravity conditions.…”

Section: Introductionmentioning

confidence: 99%

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Differential transcriptional profile through cell cycle progression in Arabidopsis cultures under simulated microgravity

et al. 2019

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Plant cell proliferation is affected by microgravity during spaceflight, but involved molecular mechanisms, key for space agronomy goals, remain unclear. To investigate transcriptomic changes in cell cycle phases caused by simulated microgravity, an Arabidopsis immobilized synchronous suspension culture was incubated in a Random Positioning Machine. After simulation, a transcriptomic analysis was performed with two subpopulations of cells (G2/M and G1 phases enriched) and an asynchronous culture sample. Differential expression was found at cell proliferation, energy/redox and stress responses, plus unknown biological processes gene ontology groups. Overall expression inhibition was a common response to simulated microgravity, but differences peak at the G2/M phase and stress response components change dramatically from G2/M to the G1 subpopulation suggesting a differential adaptation response to simulated microgravity through the cell cycle. Cell cycle adaptation using both known stress mechanisms and unknown function genes may cope with reduced gravity as an evolutionary novel environment.

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Advances in Microgravity Directed Tissue Engineering

Cui¹,

Liu

Zhao

et al. 2023

Adv Healthcare Materials

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Tissue engineering aims to generate functional biological substitutes to repair, sustain, improve, or replace tissue function affected by disease. With the rapid development of space science, the application of simulated microgravity has become an active topic in the field of tissue engineering. There is a growing body of evidence demonstrating that microgravity offers excellent advantages for tissue engineering by modulating cellular morphology, metabolism, secretion, proliferation, and stem cell differentiation. To date, there have been many achievements in constructing bioartificial spheroids, organoids, or tissue analogs with or without scaffolds in vitro under simulated microgravity conditions. Here, the current status, recent advances, challenges, and prospects of microgravity related to tissue engineering are reviewed. Current simulated‐microgravity devices and cutting‐edge advances of microgravity for biomaterials‐dependent or biomaterials‐independent tissue engineering to offer a reference for guiding further exploration of simulated microgravity strategies to produce engineered tissues are summarized and discussed.

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Cell cycle acceleration and changes in essential nuclear functions induced by simulated microgravity in a synchronized Arabidopsis cell culture

Cited by 25 publications

References 82 publications

RNA‐seq analyses of Arabidopsis thaliana seedlings after exposure to blue‐light phototropic stimuli in microgravity

RNA‐seq analyses of Arabidopsis thaliana seedlings after exposure to blue‐light phototropic stimuli in microgravity

Differential transcriptional profile through cell cycle progression in Arabidopsis cultures under simulated microgravity

Advances in Microgravity Directed Tissue Engineering

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