A Year of (Bio)chemical Elements

For March, it’s a renal three-fer: sodium, potassium and chlorine

Quira Zeidan
March 01, 2019

Every month in 2019 we are looking at one or more chemical elements essential for life in commemoration of the 150th anniversary of Mendeleev’s periodic table. For January and February, we selected hydrogen and iron, respectively, and described their function in biochemical reactions involving electron transport.

Sodium-Potassium-Chlorine The Na+/K+ pump uses energy from the breakdown of adenosine triphosphate into adenosine diphosphate and inorganic phosphate to move 3 Na ions out to the extracellular space and 2 K ions into the cytoplasm, creating a charge imbalance across the cellular membrane. CNX OpenStax/Wikimedia Commons

March is National Kidney Month, so we are highlighting three elements central to renal function: sodium, or Na; potassium, or K; and chlorine, or Cl.

Sodium and potassium, atomic numbers 11 and 19, respectively, are highly reactive metals with similar chemical properties, both listed in group 1, the alkali metals, of the periodic table. Both have a single valence electron in their outer shell, which they readily donate, creating positive ions, or Na+ and K+ cations. Chlorine, a gas at room temperature with atomic number 17, is a highly reactive element with an affinity for electrons. As a strong oxidizing agent, chlorine is abundant as chloride anions, or Cl-, that combine with Na+, K+ and other cations to form chloride salts.

Sodium is the seventh most abundant element on Earth, and potassium is the 17th. They exist in rock-forming minerals such as salt and granite. Chlorine is the 21st most abundant element in the Earth’s crust, occurring exclusively as ionic chloride compounds. Sodium and chlorine, constantly leached by water from mineral salts, are the most abundant elements dissolved in the oceans.

Sodium and potassium ions are crucial for most cells. Microorganisms use transmembrane ion pumps, such as the Na+/H+ antiporter or Na+ translocation systems coupled to metabolic reactions, to move Na+ ions against their concentration gradient, generating electrochemical energy to drive solute transport or to move flagellar motors (in bacteria) and to produce reducing power for biochemical reactions. K+ is the main monovalent cation in prokaryotes; it is essential to maintain intracellular pH, to generate energy via electrochemical gradients and to sustain turgor pressure.

In animals, the Na+/K+ ion pump pushes sodium and potassium across the cell membrane in opposite directions, maintaining a low Na+ concentration and a high K+ concentration inside the cell. This ionic imbalance between the cytosol and the extracellular medium creates a transmembrane potential — or voltage difference — essential to conducting electrical signals in excitable neurons and myocytes. A similar ion transporter moves H+ and K+ ions across the membrane of parietal cells, helping mammals acidify stomach contents and digest food.

Chloride ions are also necessary for all known life. Some prokaryotes use chloride compounds as a carbon and energy source and chlorine ions as terminal electron acceptors during anaerobic growth. In most cells at rest, the concentration of Cl- is lower in the cytosol than in the extracellular fluid via activity of gated ion channels that contribute to the polarization of cellular membranes. In animals, parietal cells in the stomach secrete Cl- ions to produce hydrochloric acid required for food breakdown. In humans, the defective protein in the disease cystic fibrosis is an ion channel specific for Cl- whose impaired activity results in less bactericidal activity — and more infections — in the lungs.

Latest in this section

Pulse points: 2020
Allison Frick
Folic Acid Awareness Week
Moh'd Mohanad A. Al-Dabet
How to catch an HIF
Martin J. Spiering
Quira Zeidan

Quira Zeidan is the ASBMB’s education and public outreach coordinator.

Join the ASBMB Today mailing list

Sign up to get updates on articles, interviews and events.

Latest in Science

Science highlights or most popular articles

Pulse points: 2020
Wellness

Pulse points: 2020

January 16, 2020

Research can spark change. Here are examples of how scientific inquiry exposes health risks and leads to new treatments for disease.

JLR junior associate editors organize virtual issues
Journal News

JLR junior associate editors organize virtual issues

January 14, 2020

The junior associate editors of the Journal of Lipid Research have organized four virtual issues highlighting cutting-edge research published by the journal.

Taking the measure of glycans
Journal News

Taking the measure of glycans

January 12, 2020

When Lorna De Leoz invited laboratories to participate in her glycomics study, she hoped for 20 responses. Instead, she was deluged by emails from around the world.

Folic Acid Awareness Week
Health Observance

Folic Acid Awareness Week

January 11, 2020

The National Birth Defects Prevention Network and related organizations observed Folic Acid Awareness Week this week to educate the public, in particular mothers-to-be, about the role that folic acid plays in preventing congenital disabilities.

How to catch an HIF
Journal News

How to catch an HIF

January 10, 2020

The 1995 discovery of hypoxia-inducible factor by the lab of Gregg Semenza was a major milestone in figuring out how cells sense oxygen.

Holidays may break our resolve, but not our microbiomes
Wellness

Holidays may break our resolve, but not our microbiomes

January 10, 2020

The connection between what we eat and which bacteria wind up dominating our gut is well established, but a few weeks of eating nonhabitual foods are unlikely to alter the composition of your gut bacteria significantly.