Electrolyte homeostasis is essential for life at the cellular level, in that, cells must respond to osmotic challenge to fend off changes in cellular water and ion content that could lead to rupture. On a larger scale, humans regulate blood pressure by maintaining an appropriate balance of sodium reabsorption and excretion in the kidney. Hypertension, a major health problem affecting more than 60 million Americans, is a result of a dysfunction in electrolyte homeostasis. Therefore, understanding mechanisms that control electrolyte homeostasis is important for human health. It is becoming increasingly clear that a core set of regulatory proteins senses and maintains electrolyte homeostasis. Our knowledge is lacking in how this is achieved at the molecular level. The molecular mechanisms of electrolyte homeostasis are of critical importance for both healthy and disease states in humans and thus must be understood in order unlock their therapeutic potential.
We aim to understand the network of proteins and signaling mechanisms, mainly regulatory phosphorylation events, which connect mechanisms of cell volume control and blood pressure homeostasis. The red blood cell holds great potential as a model system to understand the fundamental elements critical for electrolyte homeostasis. We will use a quantitative proteomic approach to study networks of signaling proteins that regulate electrolyte flux in red blood cells. We will focus our studies on the K-Cl cotransporters as a representative direct mediator of electrolyte flux and the kinases Wnk1 and Wnk4 as critical signaling components of ion flux. These studies will provide new insight into the upstream regulation of Wnk function and downstream signaling events that control electrolyte homeostasis by identifying critical regulatory phosphorylation sites. To link these observations to the in vivo setting, we will use SILAC technology in the mouse red blood cell to quantify critical regulatory phosphorylation sites that respond to specific physiologic perturbation. The purpose of this study is to provide a fundamental understanding of the mechanisms that coordinate electrolyte homeostasis. Furthermore, we are seeking mechanistic links in blood pressure control and cell volume regulation in order to find new target points to treat diseases such as hypertension and sickle cell anemia.

Public Health Relevance

The purpose of this study is to provide a fundamental understanding of the mechanisms that coordinate electrolyte homeostasis. Hypertension, a major health problem affecting more than 60 million Americans, is a result of a dysfunction in electrolyte homeostasis. Therefore, understanding mechanisms that control electrolyte homeostasis is important for human health. The purpose of this study is to provide a fundamental understanding of the mechanisms that coordinate electrolyte homeostasis. Hypertension, a major health problem affecting more than 60 million Americans, is a result of a dysfunction in electrolyte homeostasis. Therefore, understanding mechanisms that control electrolyte homeostasis is important for human health.

Agency
National Institute of Health (NIH)
Institute
National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK)
Type
Research Scientist Development Award - Research & Training (K01)
Project #
5K01DK089006-05
Application #
8719979
Study Section
Diabetes, Endocrinology and Metabolic Diseases B Subcommittee (DDK)
Program Officer
Rankin, Tracy L
Project Start
2010-09-02
Project End
2015-08-31
Budget Start
2014-09-01
Budget End
2015-08-31
Support Year
5
Fiscal Year
2014
Total Cost
$154,332
Indirect Cost
$11,432
Name
Yale University
Department
Genetics
Type
Schools of Medicine
DUNS #
043207562
City
New Haven
State
CT
Country
United States
Zip Code
06520
CastaƱeda-Bueno, Maria; Arroyo, Juan Pablo; Zhang, Junhui et al. (2017) Phosphorylation by PKC and PKA regulate the kinase activity and downstream signaling of WNK4. Proc Natl Acad Sci U S A 114:E879-E886
Lin, Dao-Hong; Yue, Peng; Yarborough 3rd, Orlando et al. (2015) Src-family protein tyrosine kinase phosphorylates WNK4 and modulates its inhibitory effect on KCNJ1 (ROMK). Proc Natl Acad Sci U S A 112:4495-500
Oza, Javin P; Aerni, Hans R; Pirman, Natasha L et al. (2015) Robust production of recombinant phosphoproteins using cell-free protein synthesis. Nat Commun 6:8168
Aerni, Hans R; Shifman, Mark A; Rogulina, Svetlana et al. (2015) Revealing the amino acid composition of proteins within an expanded genetic code. Nucleic Acids Res 43:e8
Pirman, Natasha L; Barber, Karl W; Aerni, Hans R et al. (2015) A flexible codon in genomically recoded Escherichia coli permits programmable protein phosphorylation. Nat Commun 6:8130
Colangelo, Christopher M; Ivosev, Gordana; Chung, Lisa et al. (2015) Development of a highly automated and multiplexed targeted proteome pipeline and assay for 112 rat brain synaptic proteins. Proteomics 15:1202-14
Rovner, Alexis J; Haimovich, Adrian D; Katz, Spencer R et al. (2015) Recoded organisms engineered to depend on synthetic amino acids. Nature 518:89-93
Sawyer, Nicholas; Gassaway, Brandon M; Haimovich, Adrian D et al. (2014) Designed phosphoprotein recognition in Escherichia coli. ACS Chem Biol 9:2502-7
Steinfeld, Justin B; Aerni, Hans R; Rogulina, Svetlana et al. (2014) Expanded cellular amino acid pools containing phosphoserine, phosphothreonine, and phosphotyrosine. ACS Chem Biol 9:1104-12
O'Donoghue, Patrick; Prat, Laure; Kucklick, Martin et al. (2014) Reducing the genetic code induces massive rearrangement of the proteome. Proc Natl Acad Sci U S A 111:17206-11

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