Calcium signaling

Calcium signaling is the use of calcium ions (Ca²⁺) to communicate and drive intracellular processes often as a step in signal transduction. Ca²⁺ is important for a wide variety of cellular signaling pathways. Once Ca²⁺ enters the cytosol of the cytoplasm it exerts allosteric regulatory effects on many enzymes and proteins. Ca²⁺ signaling can activate certain ion channels for short term changes (like changes to electrochemical gradients) in the cell. For longer-term changes (like changes in gene transcription^[1]), Ca²⁺ can act as a second messenger through indirect signal transduction pathways, such as in G protein-coupled receptor pathways.

Shows Ca²⁺ release from the endoplasmic reticulum through phospholipase C (PLC) pathway.

Calcium Concentration Regulation

The resting concentration of Ca²⁺ in the cytoplasm is normally maintained around 100 nM. This is 20,000- to 100,000-fold lower than typical extracellular concentration.^[2][3] To maintain this low concentration, Ca²⁺ is naturally buffered by different organelles and proteins within the cell. To change Ca²⁺ levels in the cytosol, it can be actively pumped out of the cell (from the cytosol to the extracellular space), into the endoplasmic reticulum (ER), or into the mitochondria. Calcium signaling occurs when the cell is stimulated to release Ca²⁺ ions from intracellular stores (the ER or mitochondria), or when Ca²⁺ enters the cell through plasma membrane ion channels.^[2] Under certain conditions, the intracellular Ca²⁺ concentration may begin to oscillate at a specific frequency.^[4]

Phospholipase C pathway

Phospholipase C cleaving PIP2 into IP3 and DAG

Specific signals can trigger a sudden increase in the cytoplasmic Ca²⁺ levels to 500–1,000 nM by opening channels in the ER or the plasma membrane. The most common signaling pathway that increases cytoplasmic calcium concentration is the phospholipase C (PLC) pathway.

1. Many cell surface receptors, including G protein-coupled receptors and receptor tyrosine kinases, activate the PLC enzyme.
2. PLC uses hydrolysis of the membrane phospholipid PIP₂ to form IP₃ and diacylglycerol (DAG), two classic secondary messengers.
3. DAG attaches to the plasma membrane and recruits protein kinase C (PKC).
4. IP₃ diffuses to the ER and is bound to the IP3 receptor.
5. The IP₃ receptor serves as a Ca²⁺ channel, and releases Ca²⁺ from the ER.
6. The Ca²⁺ bind to PKC and other proteins and activate them.^[5]

Depletion from the endoplasmic reticulum

Depletion of Ca²⁺ from the ER will lead to Ca²⁺ entry from outside the cell by activation of "Store-Operated Channels" (SOCs).^[6] This inflow of Ca²⁺ is referred to as Ca²⁺-release-activated Ca²⁺ current (ICRAC). The mechanisms through which ICRAC occurs are currently still under investigation. Although Orai1 and STIM1, have been linked by several studies, for a proposed model of store-operated calcium influx. Recent studies have cited the phospholipase A2 beta,^[7] nicotinic acid adenine dinucleotide phosphate (NAADP),^[8] and the protein STIM 1^[9] as possible mediators of ICRAC.

Role as a Second Messenger

Calcium is a ubiquitous second messenger with wide-ranging physiological roles.^[3] These include muscle contraction, neuronal transmission (as in an excitatory synapse), cellular motility (including the movement of flagella and cilia), fertilization, cell growth (proliferation), neurogenesis, learning and memory as with synaptic plasticity, and secretion of saliva.^[10][11] High levels of cytoplasmic Ca²⁺ can also cause the cell to undergo apoptosis.^[12] Other biochemical roles of calcium include regulating enzyme activity, permeability of ion channels,^[13] activity of ion pumps, and components of the cytoskeleton.^[14]

Many of Ca²⁺ mediated events occur when the released Ca²⁺ binds to and activates the regulatory protein calmodulin. Calmodulin may activate the Ca²⁺-calmodulin-dependent protein kinases, or may act directly on other effector proteins.^[15] Besides calmodulin, there are many other Ca²⁺-binding proteins that mediate the biological effects of Ca²⁺.

In muscle contraction

Comparison of smooth muscle and skeletal muscle contraction

Contractions of skeletal muscle fiber are caused due to electrical stimulation. This process is caused by the depolarization of the transverse tubular junctions. Once depolarized the sarcoplasmic reticulum (SR) releases Ca²⁺ into the myoplasm where it will bind to a number of calcium sensitive buffers. The Ca²⁺ in the myoplasm will diffuse to Ca²⁺ regulator sites on the thin filaments. This leads to the actual contraction of the muscle.^[16]

Contractions of smooth muscle fiber are dependent on how a Ca²⁺ influx occurs. When a Ca²⁺ influx occurs, cross bridges form between myosin and actin leading to the contraction of the muscle fibers. Influxes may occur from extracellular Ca²⁺ diffusion via ion channels. This can lead to three different results. The first is a uniform increase in the Ca²⁺ concentration throughout the cell. This is responsible for increases in vascular diameters. The second is a rapid time dependent change in the membrane potential which leads to a very quick and uniform increase of Ca²⁺. This can cause a spontaneous release of neurotransmitters via sympathetic or parasympathetic nerve channels. The last potential result is a specific and localized subplasmalemmal Ca²⁺ release. This type of release increases the activation of protein kinase, and is seen in cardiac muscle where it causes excitation-concentration coupling. Ca²⁺ may also result from internal stores found in the SR. This release may be caused by Ryaodine (RYRs) or IP₃ receptors. RYRs Ca²⁺ release is spontaneous and localized. This has been observed in a number of smooth muscle tissues including arteries, portal vein, urinary bladder, ureter tissues, airway tissues, and gastrointestinal tissues. IP₃ Ca²⁺ release is caused by activation of the IP₃ receptor on the SR. These influxes are often spontaneous and localized as seen in the colon and portal vein, but may lead to a global Ca²⁺ wave as observed in many vascular tissues.^[17]

In neurons

In neurons, concurrent increases of cytosolic and mitochondrial Ca²⁺ are important to synchronize the electrical activity of a neuron with it's mitochondrial energy metabolism. The calcium levels of the mitochondrial matrix need to stay around 10-30 μM to activate isocitrate dehydrogenase, which is one of the key regulatory enzymes of the Krebs cycle.^[18][19]

The Endoplasmic Reticulum (ER), in neurons, may serve in a network integrating numerous extracellular and intracellular signals in a binary membrane system with the plasma membrane. Such an association with the plasma membrane creates the relatively new perception of the ER and theme of "a neuron within a neuron."^[20] The ER's structural characteristics, including its ability to act as a Ca²⁺ store and use specific Ca²⁺ releasing proteins, serve to create a system that may release regenerative waves of Ca²⁺ which balance cytosolic Ca²⁺ levels. These networks may communicate both locally and globally in the cell. Ca²⁺ signals are integrated through extracellular and intracellular fluxes, and have been implicated to play roles in synaptic plasticity, memory, neurotransmitter release, neuronal excitability, and long term changes at the gene transcription level. Ca²⁺ signaling is also related to ER stress. Along with the unfolded protein response, improper signaling pathways can cause ER associated degradation (ERAD) and autophagy.^[21]

One key Ca²⁺ signaling pathway in neurons involves the release of neurotransmitters. When an action potential reaches the end of a neuron, voltage-gated calcium channels open. This allows Ca²⁺ to enter the neuron locally and interact with synaptotagmin and other SNARE proteins. These proteins sense the spikes in Ca²⁺ levels and trigger the release of synaptic vesicles which deposit neurotransmitters into the synapse.

Astrocytes have a direct relationship with neurons through them releasing gliotransmitters. These transmitters allow communication between neurons and are triggered by calcium levels increasing around astrocytes from inside stores. This increase in calcium can also be caused by other neurotransmitters. Some examples of gliotransmitters are ATP and glutamate.^[22] Activation of these neurons will lead to a 10-fold increase in the concentration of calcium in the cytosol from 100 nanomolar to 1 micromolar.^[23]

In fertilization

Ca²⁺ influx during fertilization has been observed in many species as a trigger for development of the oocyte. These influxes may occur as a single increase in concentration as seen with fish and echinoderms, or may occur with the concentrations oscillating as observed in mammals. The triggers to these Ca²⁺ influxes may differ. The influx have been observed to occur via membrane Ca²⁺ conduits and Ca²⁺ stores in the sperm. It has also been seen that sperm binds to membrane receptors that lead to a release in Ca²⁺ from the ER. The sperm has also been observed to release a soluble factor that is specific to that species. This prevents cross species fertilization to occur. These soluble factors lead to activation of IP₃ which causes a Ca²⁺ release from the ER via IP₃ receptors.^[24] It has also been seen that some model systems mix these methods such as seen with mammals.^[25][26] Once the Ca²⁺ is released from the ER the egg starts the process of forming a fused pronucleus and the restart of the mitotic cell cycle.^[27] Ca²⁺ release is also responsible for the activation of NAD⁺ kinase which leads to membrane biosynthesis, and the exocytosis of the oocytes cortical granules which leads to the formation of the hyaline layer allowing for the slow block to polyspermy.

See also

• Nanodomain
• European Calcium Society