SLC4A11 and MFSD3 Gene Expression Changes in Deoxynivalenol Treated IPEC-J2 Cells

Deoxynivalenol (DON) caused serious cytotoxicity for animal cells. However, genes involved in regulating DON toxicity and the underlying molecular mechanisms remain largely unknown. This study explored the role of SLC4A11 and MFSD3 in alleviating DON toxicity and analyzed the DNA methylation changes of these two genes. Viability and cell cycle analysis showed that DON exposure decreased the IPEC-J2 viability (P < 0.01), blocked the cell cycle in the G2/M phase (P < 0.01), and increased the rate of apoptosis (P < 0.05). Expression of the SLC4A11 and MFSD3 genes was significantly downregulated upon DON exposure (P < 0.01). Overexpression of SLC4A11 and MFSD3 can enhance the cell viability (P < 0.01). DNA methylation assays indicated that promoter methylation of SLC4A11 (mC-1 and mC-23) and MFSD3 (mC-1 and mC-12) were significantly higher compared with those in the controls and correlated negatively with mRNA expression (P < 0.05). Further analysis showed that mC-1 of SLC4A11 and MFSD3 was located in transcription factor binding sites for NF-1 and Sp1. Our findings revealed the novel biological functions of porcine SLC4A11 and MFSD3 genes in regulating the cytotoxic effects induced by DON, and may contribute to the detection of biomarkers and drug targets for predicting and eliminating the potential toxicity of DON.

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Endoreduplication in Maize Endosperm: An Approach for Increasing Crop Productivity

10.32747/2000.7575285.bard ◽

2000 ◽

Author(s):

Gideon Grafi ◽

Brian Larkins

Keyword(s):

Cell Cycle ◽

Dna Synthesis ◽

Storage Protein ◽

Molecular Mechanisms ◽

S Phase ◽

Cyclin B ◽

Regulatory Subunit ◽

Maize Endosperm ◽

M Phase

The focus of this research project is to investigate the role of endoreduplication in maize endosperm development and the extent to which this process contributes to high levels of starch and storage protein synthesis. Although endoreduplication has been widely observed in many cells and tissues, especially those with high levels of metabolic activity, the molecular mechanisms through which the cell cycle is altered to produce consecutive cycles of S-phase without an intervening M-phase are unknown. Our previous research has shown that changes in the expression of several cell cycle regulatory genes coincide with the onset of endoreduplication. During this process, there is a sharp reduction in the activity of the mitotic cyclin-dependent kinase (CDK) and activation of the S-phase CDK. It appears the M-phase CDK is stable, but its activity is blocked by a proteinaceous inhibitor. Coincidentally, the S-phase checkpoint protein, retinoblastoma (ZmRb), becomes phosphorylated, presumably releasing an E2F-type transcriptional regulator which promotes the expression of genes responsible for DNA synthesis. To investigate the role of these cell cycle proteins in endoreduplication, we have created transgenic maize plants that express various genes in an endosperm-specific manner using a storage protein (g-zein) promoter. During the first year of the grant, we constructed point mutations of the maize M-phase kinase, p34cdc2. One alteration replaced aspartic acid at position 146 with asparagine (p3630-CdcD146N), while another changed threonine 161 to alanine (p3630-CdcT161A). These mutations abolish the activity of the CDK. We hypothesized that expression of the mutant forms of p34cdc2 in endoreduplicating endosperm, compared to a control p34cdc2, would lead to extra cycles of DNA synthesis. We also fused the gene encoding the regulatory subunit of the M- phase kinase, cyclin B, under the g-zein promoter. Normally, cyclin B is expected to be destroyed prior to the onset of endoreduplication. By producing high levels of this protein in developing endosperm, we hypothesized that the M-phase would be extended, potentially reducing the number of cycles of endoreduplication. Finally, we genetically engineered the wheat dwarf virus RepA protein for endosperm-specific expression. RepA binds to the maize retinoblastoma protein and presumably releases E2F-like transcription factors that activate DNA synthesis. We anticipated that inactivation of ZmRb by RepA would lead to additional cycles of DNA synthesis.

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Epigenetic Regulation of Apoptosis and Cell Cycle in Osteosarcoma

Sarcoma ◽

10.1155/2011/679457 ◽

2011 ◽

Vol 2011 ◽

pp. 1-5 ◽

Cited By ~ 15

Author(s):

Krithi Rao-Bindal ◽

Eugenie S. Kleinerman

Keyword(s):

Cell Cycle ◽

Cell Cycle Regulation ◽

Molecular Mechanisms ◽

Genetic Mutations ◽

Epigenetic Mechanisms ◽

Epigenetic Alterations ◽

Novel Therapeutic Strategies ◽

Cycle Regulation ◽

Insight Into

The role of genetic mutations in the development of osteosarcoma, such as alterations in p53 and Rb, is well understood. However, the significance of epigenetic mechanisms in the progression of osteosarcoma remains unclear and is increasingly being investigated. Recent evidence suggests that epigenetic alterations such as methylation and histone modifications of genes involved in cell cycle regulation and apoptosis may contribute to the pathogenesis of this tumor. Importantly, understanding the molecular mechanisms of regulation of these pathways may give insight into novel therapeutic strategies for patients with osteosarcoma. This paper serves to summarize the described epigenetic mechanisms in the tumorigenesis of osteosarcoma, specifically those pertaining to apoptosis and cell cycle regulation.

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Role of Enzymes in Causing Neurological Disorders

International Journal of Research in Pharmaceutical Sciences ◽

10.26452/ijrps.v12i1.4092 ◽

2021 ◽

Vol 12 (1) ◽

pp. 466-476

Author(s):

Vysakh Visweswaran ◽

Roshni PR

Keyword(s):

Neurological Disorders ◽

Drug Targets ◽

Molecular Mechanisms ◽

Neurological Diseases ◽

Treatment Options ◽

Direct Result ◽

Permanent Disability ◽

Genetic Abnormalities ◽

Underlying Pathology

Diseases of the nervous system are always associated with poor prognosis and limited treatment options. The fragile nature of the neurons and their inability to replicate means that neurological disorders are associated with a permanent disability. Pharmacotherapy of neurological diseases requires understanding the molecular mechanisms involved in the disease pathology. In most of the cases a faulty cellular biochemical pathway is involved, resulting from a defective enzyme. This article focusses on role of enzymes in various neurological disorders. To review pertinent literature and summarise the role of enzymes in the underlying pathology of various neurological disorders. A comprehensive literature search was conducted using PubMed, SCOPUS, J-GATE and Google Scholar and relevant papers were collected using the keywords enzymes, Alzheimer's disease, redox, thiamine, depression, neurotransmitters, epileptogenesis. The literature review highlighted the role of enzymes in major neurological disorders and their potential to be used as drug targets and biomarkers. Identifying defective enzymes gives us new molecular targets to focus on for developing more effective pharmacotherapeutic options. They can be also considered as potential biomarkers. An abnormal enzyme is most often a direct result of an underlying genetic abnormality. Identifying and screening for these genetic abnormalities can be used in early identification and prevention of disease in individuals who have a genetic predisposition. The modern advances in genetic engineering shows a lot of promise in correcting these abnormalities and development of revolutionary cures although ethical concerns remain.

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DNA methylation regulates transcriptional homeostasis of algal endosymbiosis in the coral modelAiptasia

10.1101/213066 ◽

2017 ◽

Cited By ~ 3

Author(s):

Yong Li ◽

Yi Jin Liew ◽

Guoxin Cui ◽

Maha J Cziesielski ◽

Noura Zahran ◽

...

Keyword(s):

Dna Methylation ◽

Molecular Mechanisms ◽

Model System ◽

Epigenetic Mechanism ◽

Symbiotic Relationship ◽

Epigenetic Mechanisms ◽

Genome Wide ◽

Spurious Transcription ◽

Coral Reef Ecosystems

The symbiotic relationship between cnidarians and dinoflagellates is the cornerstone of coral reef ecosystems. Although research is focusing on the molecular mechanisms underlying this symbiosis, the role of epigenetic mechanisms, which have been implicated in transcriptional regulation and acclimation to environmental change, is unknown. To assess the role of DNA methylation in the cnidarian-dinoflagellate symbiosis, we analyzed genome-wide CpG methylation, histone associations, and transcriptomic states of symbiotic and aposymbiotic anemones in the model systemAiptasia. We find methylated genes are marked by histone H3K36me3 and show significant reduction of spurious transcription and transcriptional noise, revealing a role of DNA methylation in the maintenance of transcriptional homeostasis. Changes in DNA methylation and expression show enrichment for symbiosis-related processes such as immunity, apoptosis, phagocytosis recognition and phagosome formation, and unveil intricate interactions between the underlying pathways. Our results demonstrate that DNA methylation provides an epigenetic mechanism of transcriptional homeostasis during symbiosis.

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Size uniformity of animal cells is actively maintained by a p38 MAPK-dependent regulation of G1-length

10.1101/119867 ◽

2017 ◽

Author(s):

Shixuan Liu ◽

Miriam B. Ginzberg ◽

Nish Patel ◽

Marc Hild ◽

Bosco Leung ◽

...

Keyword(s):

Cell Cycle ◽

Cell Size ◽

P38 Mapk ◽

Cell Cycle Progression ◽

Molecular Mechanisms ◽

Mapk Pathway ◽

Small Cells ◽

Animal Cells ◽

Cycle Progression ◽

Size Uniformity

AbstractAnimal cells within a tissue typically display a striking regularity in their size. To date, the molecular mechanisms that control this uniformity are still unknown. We have previously shown that size uniformity in animal cells is promoted, in part, by size-dependent regulation of G1 length. To identify the molecular mechanisms underlying this process, we performed a large-scale small molecule screen and found that the p38 MAPK pathway is involved in coordinating cell size and cell cycle progression. Small cells display higher p38 activity and spend more time in G1 than larger cells. Inhibition of p38 MAPK leads to loss of the compensatory G1 length extension in small cells, resulting in faster proliferation, smaller cell size and increased size heterogeneity. We propose a model wherein the p38 pathway responds to changes in cell size and regulates G1 exit accordingly, to increase cell size uniformity.One-sentence summaryThe p38 MAP kinase pathway coordinates cell growth and cell cycle progression by lengthening G1 in small cells, allowing them more time to grow before their next division.

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Role of CDK1 in Translational Regulation in the M-Phase

10.20944/preprints202004.0530.v1 ◽

2020 ◽

Author(s):

Jaroslav Kalous ◽

Denisa Jansova ◽

Andrej Susor

Keyword(s):

Cell Cycle ◽

Protein Synthesis ◽

Translational Regulation ◽

Gene Expression Regulation ◽

Translational Initiation ◽

Initiation Factors ◽

Cellular Events ◽

M Phase ◽

Mitosis And Meiosis

Cyclin dependent kinase 1 (CDK1) has been primarily identified as a key cell cycle regulator in both mitosis and meiosis. Recently, an extramitotic function of CDK1 emerged when evidence was found that CDK1 is involved in many cellular events that are essential for cell proliferation and survival. In this review we summarize the involvement of active CDK1 in the initiation and elongation steps of protein synthesis in eukaryotes. During its activation CDK1 influences the initiation of protein synthesis, promotes the activity of specific translational initiation factors and affects the functioning of a subset of elongation factors. Our review provides insights into gene expression regulation during the transcriptionally silent cell cycle/M-phase and describes quantitative and qualitative translational changes based on the extramitotic role of the cell cycle master regulator CDK1, to optimize temporal synthesis of proteins to sustain division-related processes: mitosis and cytokinesis.

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Regulation of Cell Cycle Progression by Growth Factor-Induced Cell Signaling

Cells ◽

10.3390/cells10123327 ◽

2021 ◽

Vol 10 (12) ◽

pp. 3327

Author(s):

Zhixiang Wang

Keyword(s):

Cell Cycle ◽

Growth Factor ◽

Signaling Pathways ◽

Tyrosine Kinases ◽

Cell Cycle Progression ◽

Phase Cell ◽

Growth Factor Signaling ◽

Cycle Progression ◽

M Phase

The cell cycle is the series of events that take place in a cell, which drives it to divide and produce two new daughter cells. The typical cell cycle in eukaryotes is composed of the following phases: G1, S, G2, and M phase. Cell cycle progression is mediated by cyclin-dependent kinases (Cdks) and their regulatory cyclin subunits. However, the driving force of cell cycle progression is growth factor-initiated signaling pathways that control the activity of various Cdk–cyclin complexes. While the mechanism underlying the role of growth factor signaling in G1 phase of cell cycle progression has been largely revealed due to early extensive research, little is known regarding the function and mechanism of growth factor signaling in regulating other phases of the cell cycle, including S, G2, and M phase. In this review, we briefly discuss the process of cell cycle progression through various phases, and we focus on the role of signaling pathways activated by growth factors and their receptor (mostly receptor tyrosine kinases) in regulating cell cycle progression through various phases.

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Targeted Modulation of FAK/PI3K/PDK1/AKT and FAK/p53 Pathways by Cucurbitacin B for the Antiproliferation Effect Against Human Cholangiocarcinoma Cells

The American Journal of Chinese Medicine ◽

10.1142/s0192415x2050072x ◽

2020 ◽

Vol 48 (06) ◽

pp. 1475-1489

Author(s):

Sirinapha Klungsaeng ◽

Veerapol Kukongviriyapan ◽

Auemduan Prawan ◽

Sarinya Kongpetch ◽

Laddawan Senggunprai

Keyword(s):

Cell Cycle ◽

Cell Proliferation ◽

Tyrosine Kinases ◽

Molecular Mechanisms ◽

Inhibitory Effect ◽

Chemotherapeutic Agents ◽

Cucurbitacin B ◽

M Phase ◽

Cell Cycle Disruption

Inadequate responses to traditional chemotherapeutic agents in cholangiocarcinoma (CCA) emphasize a requirement for new effective compounds for the treatment of this malignancy. This study aimed to investigate the antiproliferative property of cucurbitacin B on KKU-100 CCA cells. The determination of underlying molecular mechanisms was also carried out. The results revealed that cucurbitacin B suppressed growth and replicative ability to form colonies of CCA cells, suggesting the antiproliferative effect of this compound against the cells. Flow cytometry analysis demonstrated that the interfering effect of cucurbitacin B on the CCA cell cycle at the G2/M phase was accountable for its antiproliferation property. Accompanied with cell cycle disruption, cucurbitacin B altered the expression of proteins involved in the G2/M phase transition including downregulation of cyclin A, cyclin D1, and cdc25A, and upregulation of p21. Additional molecular studies demonstrated that cucurbitacin B suppressed the activation of focal adhesion kinase (FAK) which consequently resulted in inhibition of its kinase-dependent and kinase-independent downstream targets contributing to the regulation of cell proliferation including PI3K/PDK1/AKT and p53 proteins. In this study, the transient knockdown of FAK using siRNA was employed to ascertain the role of FAK in CCA cell proliferation. Finally, the effect of cucurbitacin B on upstream receptor tyrosine kinases regulating FAK activation was elucidated. The results showed that the inhibitory effect of cucurbitacin B on FAK activation in CCA cells is mediated via interference of EGFR and HER2 expression. Collectively, cucurbitacin B might be a promising drug for CCA treatment by targeting FAK protein.

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SET8 prevents excessive DNA methylation by methylation-mediated degradation of UHRF1 and DNMT1

Nucleic Acids Research ◽

10.1093/nar/gkz626 ◽

2019 ◽

Author(s):

Huifang Zhang ◽

Qinqin Gao ◽

Shuo Tan ◽

Jia You ◽

Cong Lyu ◽

...

Keyword(s):

Cell Cycle ◽

Dna Methylation ◽

Cell Division ◽

Global Dna Methylation ◽

Protein Methylation ◽

Accessory Factor ◽

Protein Methyltransferase ◽

A Cell ◽

Do So

Abstract Faithful inheritance of DNA methylation across cell division requires DNMT1 and its accessory factor UHRF1. However, how this axis is regulated to ensure DNA methylation homeostasis remains poorly understood. Here we show that SET8, a cell-cycle-regulated protein methyltransferase, controls protein stability of both UHRF1 and DNMT1 through methylation-mediated, ubiquitin-dependent degradation and consequently prevents excessive DNA methylation. SET8 methylates UHRF1 at lysine 385 and this modification leads to ubiquitination and degradation of UHRF1. In contrast, LSD1 stabilizes both UHRF1 and DNMT1 by demethylation. Importantly, SET8 and LSD1 oppositely regulate global DNA methylation and do so most likely through regulating the level of UHRF1 than DNMT1. Finally, we show that UHRF1 downregulation in G2/M by SET8 has a role in suppressing DNMT1-mediated methylation on post-replicated DNA. Altogether, our study reveals a novel role of SET8 in promoting DNA methylation homeostasis and identifies UHRF1 as the hub for tuning DNA methylation through dynamic protein methylation.

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The centrosome–Golgi apparatus nexus

Philosophical Transactions of the Royal Society B Biological Sciences ◽

10.1098/rstb.2013.0462 ◽

2014 ◽

Vol 369 (1650) ◽

pp. 20130462 ◽

Cited By ~ 63

Author(s):

Rosa M. Rios

Keyword(s):

Golgi Apparatus ◽

Mammalian Cells ◽

Molecular Mechanisms ◽

Animal Cells ◽

Critical Feature ◽

Differentiated Cells ◽

Ribbon Structure ◽

Centrosomal Proteins ◽

Dependent Processes

A shared feature among all microtubule (MT)-dependent processes is the requirement for MTs to be organized in arrays of defined geometry. At a fundamental level, this is achieved by precisely controlling the timing and localization of the nucleation events that give rise to new MTs. To this end, MT nucleation is restricted to specific subcellular sites called MT-organizing centres. The primary MT-organizing centre in proliferating animal cells is the centrosome. However, the discovery of MT nucleation capacity of the Golgi apparatus (GA) has substantially changed our understanding of MT network organization in interphase cells. Interestingly, MT nucleation at the Golgi apparently relies on multiprotein complexes, similar to those present at the centrosome, that assemble at the cis -face of the organelle. In this process, AKAP450 plays a central role, acting as a scaffold to recruit other centrosomal proteins important for MT generation. MT arrays derived from either the centrosome or the GA differ in their geometry, probably reflecting their different, yet complementary, functions. Here, I review our current understanding of the molecular mechanisms involved in MT nucleation at the GA and how Golgi- and centrosome-based MT arrays work in concert to ensure the formation of a pericentrosomal polarized continuous Golgi ribbon structure, a critical feature for cell polarity in mammalian cells. In addition, I comment on the important role of the Golgi-nucleated MTs in organizing specialized MT arrays that serve specific functions in terminally differentiated cells.

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