RBM3 and CIRP expressions in targeted temperature management treated cardiac arrest patients—A prospective single center study

Rosenthal, Lisa-Maria; Leithner, Christoph; Tong, Giang; Streitberger, Kaspar Josche; Krech, Jana; Storm, Christian; Schmitt, Katharina

doi:10.1371/journal.pone.0226005

Cited by 17 publications

(14 citation statements)

References 36 publications

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“…The GO and pathway enrichment analysis was of great importance for interpreting the molecular mechanisms of the key cellular activities in PCOS. RPS5 [ 37 ], RBM3 [ 38 ], BAK1 [ 39 ], NDUFC2 [ 40 ], NDUFS4 [ 41 ], NDUFS5 [ 42 ], UQCRFS1 [ 43 ], COX6B1 [ 44 ], NDUFA13 [ 45 ], PRMT1 [ 46 ], RDX (radixin) [ 47 ], EPHB4 [ 48 ], SYNE2 [ 49 ], DNAH5 [ 50 ], NEDD4L [ 51 ], PDE4B [ 52 ] and CTNND1 [ 53 ] plays a critical role in the process of cardiovascular disease, but these genes might be linked with development of PCOS. Ostergaard et al [ 54 ], Zi et al [ 55 ], Kunej et al [ 56 ], Van der Schueren et al [ 57 ], Jin et al [ 58 ], Emdad et al [ 59 ], Liu et al [ 60 ], Scherag et al [ 61 ], Shi and Long [ 62 ], Sharma et al [ 63 ], Parente et al [ 64 ], Saint-Laurent et al [ 65 ] and Lee [ 66 ] demonstrated that over expression of COA3, PHB (prohibitin), UQCRC1, COX4I1, IFI27, MTDH (metadherin), S100A16, SDCCAG8, GLI2, NTN1, NLGN2, FGFR3 and PTPRN2 could cause obesity, but these genes might be involved in progression of PCOS.…”

Section: Discussionmentioning

confidence: 99%

Identification of key pathways and genes in polycystic ovary syndrome via integrated bioinformatics analysis and prediction of small therapeutic molecules

Devarbhavi

Telang

Vastrad³

et al. 2021

Reprod Biol Endocrinol

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To enhance understanding of polycystic ovary syndrome (PCOS) at the molecular level; this investigation intends to examine the genes and pathways associated with PCOS by using an integrated bioinformatics analysis. Based on the expression profiling by high throughput sequencing data GSE84958 derived from the Gene Expression Omnibus (GEO) database, the differentially expressed genes (DEGs) between PCOS samples and normal controls were identified. We performed a functional enrichment analysis. A protein-protein interaction (PPI) network, miRNA- target genes and TF - target gene networks, were constructed and visualized, with which the hub gene nodes were identified. Validation of hub genes was performed by using receiver operating characteristic (ROC) and RT-PCR. Small drug molecules were predicted by using molecular docking. A total of 739 DEGs were identified, of which 360 genes were up regulated and 379 genes were down regulated. GO enrichment analysis revealed that up regulated genes were mainly involved in peptide metabolic process, organelle envelope and RNA binding and the down regulated genes were significantly enriched in plasma membrane bounded cell projection organization, neuron projection and DNA-binding transcription factor activity, RNA polymerase II-specific. REACTOME pathway enrichment analysis revealed that the up regulated genes were mainly enriched in translation and respiratory electron transport and the down regulated genes were mainly enriched in generic transcription pathway and transmembrane transport of small molecules. The top 10 hub genes (SAA1, ADCY6, POLR2K, RPS15, RPS15A, CTNND1, ESR1, NEDD4L, KNTC1 and NGFR) were identified from PPI network, miRNA - target gene network and TF - target gene network. The modules analysis showed that genes in modules were mainly associated with the transport of respiratory electrons and signaling NGF, respectively. We find a series of crucial genes along with the pathways that were most closely related with PCOS initiation and advancement. Our investigations provide a more detailed molecular mechanism for the progression of PCOS, detail information on the potential biomarkers and therapeutic targets.

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Section: Discussionmentioning

confidence: 99%

Identification of key pathways and genes in polycystic ovary syndrome via integrated bioinformatics analysis and prediction of small therapeutic molecules

Devarbhavi

Telang

Vastrad³

et al. 2021

Reprod Biol Endocrinol

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show abstract

“…The GO and pathway enrichment analysis was of great importance for interpreting the molecular mechanisms of the key cellular activities in PCOS. RPS5 [37], RBM3 [38], BAK1 [39], NDUFC2 [40], NDUFS4 [41], NDUFS5 [42], UQCRFS1 [43], COX6B1 [44], NDUFA13 [45], PRMT1 [46], RDX (radixin) [47], EPHB4 [48], SYNE2 [49], DNAH5 [50], NEDD4L [51], PDE4B [52] and CTNND1 [53] plays a critical role in the process of cardiovascular disease, but these genes might be linked with development of PCOS. Ostergaard et al [54], Zi et al [55], Kunej et al [56], Van der Schueren et al [57], Jin et al [58], Emdad et al [59], Liu et al [60], Scherag et al [61], Shi and Long [62], Sharma et al [63], Parente et al [64], Saint-Laurent et al [65] and Lee [66] demonstrated that over expression of COA3, PHB (prohibitin), UQCRC1, COX4I1, IFI27, MTDH (metadherin), S100A16, SDCCAG8, GLI2, NTN1, NLGN2, FGFR3 and PTPRN2 could cause obesity, but these genes might be involved in progression of PCOS.…”

Section: Discussionmentioning

confidence: 99%

Identification of Key Pathways and Genes in Polycystic Ovary Syndrome via Integrated Bioinformatics Analysis and Prediction of Small Therapeutic Molecules

Devarbhavi

Telang

Vastrad³

et al. 2020

Preprint

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To add a enhance understanding of polycystic ovary syndrome (PCOS) at the molecular level, this investigation aimed to find the genes and crucial pathways linked with PCOS by using integrated bioinformatics analysis. Based on the expression profiling by high throughput sequencing data GSE84958 derived from the Gene Expression Omnibus, the differentially expressed genes (DEGs) between PCOS samples and normal controls were identified. With DEGs, we performed a series of functional enrichment analyses. Then, a protein–protein interaction (PPI) network, miRNA - target genes and TF - target gene networks were constructed and visualized, with which the hub gene nodes were screened out. Finally, validation of hub genes was performed by using receiver operating characteristic (ROC) and RT-PCR. Molecular docking studies performed. A total of 739 DEGs were screened out, among which 360 genes were up regulated and 379 genes were down regulated. GO enrichment analysis indicated that up regulated genes were mainly involved in peptide metabolic process, organelle envelope and RNA binding and the down regulated genes were significantly enriched in plasma membrane bounded cell projection organization, neuron projection and DNA-binding transcription factor activity, RNA polymerase II-specific. REACTOME pathway enrichment analysis showed that the up regulated genes were mainly enriched in translation and respiratory electron transport and the down regulated genes were mainly enriched in generic transcription pathway and transmembrane transport of small molecules. The top 10 hub genes in the constructed PPI network, miRNA - target gene network and TF - target gene network were SAA1, ADCY6, POLR2K, RPS15, RPS15A, CTNND1, ESR1, NEDD4L, KNTC1 and NGFR. The modules analysis showed that genes in the top 2 significant modules of PPI network were mainly associated with respiratory electron transport and signalling by NGF, respectively. We find a series of crucial genes along with the pathways that were most closely related with PCOS initiation and advancement. Our investigations provide a more detailed molecular mechanism for the progression of PCOS, detail information on the potential biomarkers and therapeutic targets.

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“…Показано, что RBM3 участвует в реализации эффектов нейропротекции, а представители БХШ рассматриваются как перспективные молекулы-прототипы новых лекарственных средств [30]. БХШ в нейрональной культуре снижает индуцированную оксидом азота гибель клеток, а понижение температуры корковых нейронов приводит к увеличению FGF21 и RBM3, что может предполагать наличие положительной связи и взаимодействия этих стрессбелков [31].…”

Section: молекулярные механизмы низкотемпературных технологийunclassified

Mechanisms of low-temperature rehabilitation technologies. Extreme aerocriotherapy

Шевелев

Petrova

Yuriev

et al. 2021

Physical and rehabilitation medicine, medical rehabilitation

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The mechanisms of increasing the resistance of cells to significant temperature and damaging effects are typical, and cellular tolerance, ensuring the effectiveness of systemic regulation, is an important part of increasing the adaptive and rehabilitative potential of the entire organism. The expression of early genes encoding a wide range of stress-protective proteins increases the resistance of cells not only to significant temperature stimuli, but also to ischemia, hypoxia, and other damaging factors, forming the effects of cross-adaptation. Even a small change in temperature is significant enough to trigger the processes of genomic reprogramming. It seems to us important to consider the mechanisms of low-temperature therapeutic and rehabilitation technologies from the standpoint of cellular response to temperature stimuli. Currently, a large number of low temperature technologies (HT) are used in medical rehabilitation, which can be divided into two groups: moderately low temperature effects (from 30C to +20C) and extremely low temperature effects (from 30C to 180C), which includes the technology of extreme aerocriotherapy (EACT). The purpose of the review is to analyze the systemic and local mechanisms of EACT implemented with the participation of the main known stress-protective proteins.

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RBM3 and CIRP expressions in targeted temperature management treated cardiac arrest patients—A prospective single center study

Cited by 17 publications

References 36 publications

Identification of key pathways and genes in polycystic ovary syndrome via integrated bioinformatics analysis and prediction of small therapeutic molecules

Identification of key pathways and genes in polycystic ovary syndrome via integrated bioinformatics analysis and prediction of small therapeutic molecules

Identification of Key Pathways and Genes in Polycystic Ovary Syndrome via Integrated Bioinformatics Analysis and Prediction of Small Therapeutic Molecules

Mechanisms of low-temperature rehabilitation technologies. Extreme aerocriotherapy

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