Ion Transport in the Regulation of Cell Proliferation in Cellular Physiology and Biochemistry

To characterize gene expression networks linked to AT1 angiotensin receptors in the kidney, we carried out genome-wide transcriptional analysis of RNA from kidneys of wild-type (WT) and AT1A receptor-deficient mice (KOs) at baseline and after 2 days of angiotensin II infusion (1,000 ng·kg−1·min−1). At baseline, 405 genes were differentially expressed (>1.5×) between WT and KO kidneys. Of these, >80% were upregulated in the KO group including genes involved in inflammation, oxidative stress, and cell proliferation. After 2 days of angiotensin II infusion in WT mice, expression of ≈805 genes was altered (18% upregulated, 82% repressed). Genes in metabolism and ion transport pathways were upregulated while there was attenuated expression of genes protective against oxidative stress including glutathione synthetase and mitochondrial superoxide dismutase 2. Angiotensin II infusion had little effect on blood pressure in KOs. Nonetheless, expression of >250 genes was altered in kidneys from KO mice during angiotensin II infusion; 14% were upregulated, while 86% were repressed including genes involved in immune responses, angiogenesis, and glutathione metabolism. Between WT and KO kidneys during angiotensin II infusion, 728 genes were differentially expressed; 10% were increased and 90% were decreased in the WT group. Differentially regulated pathways included those involved in ion transport, immune responses, metabolism, apoptosis, cell proliferation, and oxidative stress. This genome-wide assessment should facilitate identification of critical distal pathways linked to blood pressure regulation.

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Expression of ion transport genes in ionocytes isolated from larval zebrafish (Danio rerio) exposed to acidic or Na+-deficient water

AJP Regulatory Integrative and Comparative Physiology ◽

10.1152/ajpregu.00095.2020 ◽

2020 ◽

Vol 319 (4) ◽

pp. R412-R427

Author(s):

K. Shir-Mohammadi ◽

S. F. Perry

Keyword(s):

Gene Expression ◽

Cell Proliferation ◽

Ion Transport ◽

Danio Rerio ◽

Ionic Composition ◽

Low Ph ◽

Activity Level ◽

Whole Body ◽

Mrna Levels ◽

Acid Base

In zebrafish ( Danio rerio), a specific ionocyte subtype, the H+-ATPase-rich (HR) cell, is presumed to be a significant site of transepithelial Na+ uptake/acid secretion. During acclimation to environments differing in ionic composition or pH, ionic and acid–base regulations are achieved by adjustments to the activity level of HR cell ion transport proteins. In previous studies, the quantitative assessment of mRNA levels for genes involved in ionic and acid–base regulations relied on measurements using homogenates derived from the whole body (larvae) or the gill (adult). Such studies cannot distinguish whether any differences in gene expression arise from adjustments of ionocyte subtype numbers or transcriptional regulation specifically within individual ionocytes. The goal of the present study was to use fluorescence-activated cell sorting to separate the HR cells from other cellular subpopulations to facilitate the measurement of gene expression of HR cell-specific transporters and enzymes from larvae exposed to low pH (pH 4.0) or low Na+ (5 μM) conditions. The data demonstrate that treatment of larvae with acidic water for 4 days postfertilization caused cell-specific increases in H+-ATPase ( atp6v1aa), ca17a, ca15a, nhe3b, and rhcgb mRNA in addition to increases in mRNA linked to cell proliferation. In fish exposed to low Na+, expression of nhe3b and rhcgb was increased owing to HR cell-specific regulation and elevated numbers of HR cells. Thus, the results of this study demonstrate that acclimation to low pH or low Na+ environmental conditions is facilitated by HR cell-specific transcriptional control and by HR cell proliferation.

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Highlight on fusing multiple chromosomes in yeast into a single chromosome

10.7287/peerj.preprints.27462v1 ◽

2019 ◽

Author(s):

Wenfa Ng

Keyword(s):

Cell Viability ◽

Genetic Information ◽

Significant Loss ◽

Cell Physiology ◽

Chromosome Research ◽

Single Chromosome ◽

Biochemical Processes ◽

Cellular Physiology ◽

Physiology And Biochemistry ◽

Chromosome Level

Multiple biological mysteries remain in the definition and organization of genetic information into different chromosomes. Up to now, genome architecture at the chromosome level remain enigmatic concerning the reasons why evolution and natural selection arranged genetic information in separate segments in eukaryotic cells as compared to the single chromosome in the prokaryotic world. Specifically, one important unresolved question has been the role of chromosomes in cellular physiology and biochemical processes. By deleting the centromere and telomere regions of different chromosomes in Saccharomyces cerevisiae and fusing the different chromosomes into one chromosome, research reported by Shao and coworkers in Nature revealed the technical possibility of concatenating all genetic information into one segment. Furthermore, cell viability assays revealed that there was no significant loss of cell viability after the fusing of 16 chromosomes into a single chromosome. This highlighted that centromere and telomere sequences were not critical to overall cellular function, physiology and biochemistry. More importantly, the results highlighted that genetic information and its organisation at the sub-chromosome level play a more important role in defining cellular biochemical processes and physiology such as metabolism and cell division processes. Collectively, the technical feasibility of fusing multiple chromosomes into a single chromosome has been shown in new research that deleted the centromere and telomere regions of different chromosomes for fusing the resulting genetic information into a single chromosome. Little loss of viability and function in cells with a single chromosome and the stability of replicating the chromosome revealed that centromere and telomere sequences may not play critical roles in defining cellular physiology and biochemistry. More importantly, genomic information and its regulation was shown indirectly to have a more direct influence on cell physiology and metabolism than chromosomal architecture.

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Cellular Physiology and Biochemistry

10.33594/000000000 ◽

2021 ◽

Keyword(s):

Cellular Physiology ◽

Physiology And Biochemistry

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Publisher Correction: Compensatory ion transport buffers daily protein rhythms to regulate osmotic balance and cellular physiology

Nature Communications ◽

10.1038/s41467-021-26725-7 ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

Alessandra Stangherlin ◽

Joseph L. Watson ◽

David C. S. Wong ◽

Silvia Barbiero ◽

Aiwei Zeng ◽

...

Keyword(s):

Ion Transport ◽

Cellular Physiology ◽

Osmotic Balance

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Highlight on fusing multiple chromosomes in yeast into a single chromosome

10.7287/peerj.preprints.27462 ◽

2019 ◽

Author(s):

Wenfa Ng

Keyword(s):

Cell Viability ◽

Genetic Information ◽

Significant Loss ◽

Cell Physiology ◽

Chromosome Research ◽

Single Chromosome ◽

Biochemical Processes ◽

Cellular Physiology ◽

Physiology And Biochemistry ◽

Chromosome Level

Multiple biological mysteries remain in the definition and organization of genetic information into different chromosomes. Up to now, genome architecture at the chromosome level remain enigmatic concerning the reasons why evolution and natural selection arranged genetic information in separate segments in eukaryotic cells as compared to the single chromosome in the prokaryotic world. Specifically, one important unresolved question has been the role of chromosomes in cellular physiology and biochemical processes. By deleting the centromere and telomere regions of different chromosomes in Saccharomyces cerevisiae and fusing the different chromosomes into one chromosome, research reported by Shao and coworkers in Nature revealed the technical possibility of concatenating all genetic information into one segment. Furthermore, cell viability assays revealed that there was no significant loss of cell viability after the fusing of 16 chromosomes into a single chromosome. This highlighted that centromere and telomere sequences were not critical to overall cellular function, physiology and biochemistry. More importantly, the results highlighted that genetic information and its organisation at the sub-chromosome level play a more important role in defining cellular biochemical processes and physiology such as metabolism and cell division processes. Collectively, the technical feasibility of fusing multiple chromosomes into a single chromosome has been shown in new research that deleted the centromere and telomere regions of different chromosomes for fusing the resulting genetic information into a single chromosome. Little loss of viability and function in cells with a single chromosome and the stability of replicating the chromosome revealed that centromere and telomere sequences may not play critical roles in defining cellular physiology and biochemistry. More importantly, genomic information and its regulation was shown indirectly to have a more direct influence on cell physiology and metabolism than chromosomal architecture.

Download Full-text