Evolution of extreme stomach pH in bilateria inferred from gastric alkalization mechanisms in basal deuterostomes

Stumpp, Meike; Hu, Marian Yong-An; Tseng, Yung‐Che; Guh, Ying Jeh; Chen, Yi Chih; Yu, Jr-Kai; Su, Yea-Huey; Hwang, Pung Pung

doi:10.1038/srep10421

Cited by 35 publications

(61 citation statements)

References 40 publications

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“…These data imply strong pH regulatory capabilities for gastric epithelia surrounding the stomach, but also highlight an additional energetic sink for urchin larvae that further increases the metabolic cost of living in low pH sea water (Stumpp et al . ).…”

Section: Discussionmentioning

confidence: 97%

“…ATP demand) are caused by a shift of energy partitioning towards processes needed to maintain acid–base homeostasis (Stumpp et al . , , ; Cyronak et al . ; Pan et al .…”

Section: Discussionmentioning

confidence: 99%

“…Remarkably, ATP used for ion transport and protein synthesis, two processes central to pH compensation in larval urchins (Stumpp et al . , ), can alone consume 64% and 84% of total available ATP in prefeeding stages and unfed urchin larvae when cultured in low pH sea water, respectively (Pan et al . ).…”

Section: Discussionmentioning

confidence: 99%

“…In low pH sea water, protons diffuse from extracellular spaces into the larval stomach, and stomach epithelial cells must therefore pump protons back into the extracellular fluid to maintain alkaline stomach conditions required for optimal digestive enzyme activity (Stumpp et al . , ). Early‐life stage urchins can at least partially compensate pH within the stomach: gastric pH decreases 0.3–0.5 units during chronic exposure to seawater pH of 7.7 or 7.4, yet still remains greater than 9 under both these pH regimes (Stumpp et al .…”

Section: Discussionmentioning

confidence: 99%

“…Prevailing theory posits that increases in metabolic rate (i.e. ATP demand) are caused by a shift of energy partitioning towards processes needed to maintain acid-base homeostasis (Stumpp et al 2012a(Stumpp et al , 2013(Stumpp et al , 2015Cyronak et al 2016;Pan et al 2015). In early-life stage urchins, the space containing the extracellular matrix between the epidermis and gastric epithelium is separated from external sea water by a highly permeable layer of cells, and fine-scale measurements show pH in this region conforms to that of sea water (Stumpp et al 2012a).…”

Section: Population-specific Responses To Seawater Acidification In Ementioning

confidence: 99%

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Transcriptomic responses to seawater acidification among sea urchin populations inhabiting a natural pH mosaic

et al. 2017

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Increasing awareness of spatial and temporal variation in ocean pH suggests some marine populations may be adapted to local pH regimes and will therefore respond differently to present-day pH variation and to long-term ocean acidification. In the Northeast Pacific Ocean, differences in the strength of coastal upwelling cause latitudinal variation in prevailing pH regimes that are hypothesized to promote local adaptation and unequal pH tolerance among resident populations. In this study, responses to experimental seawater acidification were compared among embryos and larvae from six populations of purple sea urchins (Strongylocentrotus purpuratus) inhabiting areas that differ in their frequency of low pH exposure and that prior research suggests are locally adapted to seawater pH. Transcriptomic analyses demonstrate urchin populations most frequently exposed to low pH seawater responded to experimental acidification by expressing genes within major ATP-producing pathways at greater levels than populations encountering low pH less often. Multiple genes within the tricarboxylic acid cycle, electron transport chain and fatty acid beta oxidation pathways were upregulated in urchin populations experiencing low pH conditions most frequently. These same metabolic pathways were significantly over-represented among genes both expressed in a population-specific manner and putatively under selection to enhance low pH tolerance. Collectively, these data suggest natural selection is acting on metabolic gene networks to redirect ATP toward maintaining acid-base homeostasis and enhance tolerance of seawater acidification. As a trade-off, marine populations more tolerant of low pH may have less energy to put towards other aspects of fitness and to respond to additional ocean change.

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Section: Discussionmentioning

confidence: 97%

“…ATP demand) are caused by a shift of energy partitioning towards processes needed to maintain acid–base homeostasis (Stumpp et al . , , ; Cyronak et al . ; Pan et al .…”

Section: Discussionmentioning

confidence: 99%