Open Access Articles- Top Results for Adenylate cyclase

Adenylate cyclase

Adenylate cyclase
EC number
CAS number 9012-42-4
IntEnz IntEnz view
ExPASy NiceZyme view
MetaCyc metabolic pathway
PRIAM profile
PDB structures RCSB PDB PDBe PDBsum
Gene Ontology AmiGO / EGO

Adenylate cyclase (EC, also commonly known as adenylyl cyclase, abbreviated AC) is an enzyme with key regulatory roles in essentially all cells. It is the most polyphyletic known enzyme: six distinct classes have been described, all catalyzing the same reaction but representing unrelated gene families with no known sequence or structural homology. The best known AC class is class III or AC-III (Roman numerals are used for classes). AC-III occurs widely in eukaryotes and has important roles in many human tissues.

All classes of AC catalyze the conversion of adenosine triphosphate (ATP) to 3',5'-cyclic AMP (cAMP) and pyrophosphate. Divalent cations, usually magnesium (Mg), are generally required and appear to be closely involved in the enzymatic mechanism. The cAMP produced by AC then serves as a regulatory signal via specific cAMP-binding proteins, either transcription factors or other enzymes (e.g., cAMP-dependent kinases).

File:Adenylate kinase.png
Adenylate Cyclase catalyzes the conversion of ATP to 3',5'-cyclic AMP

Class I AC

Class I AC's occur in many bacteria including E. coli. This was the first class of AC to be characterized. It was observed that E. coli deprived of glucose produce cAMP that serves as an internal signal to activate expression of genes for importing and metabolizing other sugars. cAMP exerts this effect by binding the transcription factor CRP, also known as CAP. Class I AC's are large cytosolic enzymes (~100 kDa) with a large regulatory domain (~50 kDa) that indirectly senses glucose levels. As of 2012, no crystal structure is available for class I AC.

Class II AC

These AC's are toxins secreted by pathogenic bacteria such as Bacillus anthracis and Bordetella pertussis during infection. These bacteria also secrete proteins that enable the AC-II to enter host cells, where the exogenous AC activity undermines normal cellular processes. The genes for Class II AC's are known as cyaA. Several crystal structures are known for AC-II enzymes.

Class III AC

These AC's are the most familiar based on extensive study due to their important roles in human health. They are also found in some bacteria, notably Mycobacterium tuberculosis where they appear to have a key role in pathogenesis. Most AC-III's are integral membrane proteins involved in transducing extracellular signals into intracellular responses. A Nobel Prize was awarded to Earl Sutherland in 1971 for discovering the key role of AC-III in human liver, where adrenaline indirectly stimulates AC to mobilize stored energy in the "fight or flight" response. The effect of adrenaline is via a G protein signaling cascade, which transmits chemical signals from outside the cell across the membrane to the inside of the cell (cytoplasm). The outside signal (in this case, adrenaline) binds to a receptor, which transmits a signal to the G protein, which transmits a signal to adenylate cyclase, which transmits a signal by converting adenosine triphosphate to cyclic adenosine monophosphate (cAMP). cAMP is known as a second messenger.[1]

cAMP (cyclic adenosine monophosphate) is an important molecule in eukaryotic signal transduction, a so-called second messenger. Adenylate cyclases are often activated or inhibited by G proteins, which are coupled to membrane receptors and thus can respond to hormonal or other stimuli. Following activation of adenylate cyclase, the resulting cAMP acts as a second messenger by interacting with and regulating other proteins such as protein kinase A and cyclic nucleotide-gated ion channels.

Photoactivatable adenylate cyclase (PAC) was discovered in E. gracilis and can be expressed in other organisms through genetic manipulation. Shining blue light on a cell containing PAC activates it and abruptly increases the rate of conversion of ATP to cAMP. This is a useful technique for researchers in neuroscience because it allows them to quickly increase the intracellular cAMP levels in particular neurons, and to study the effect of that increase in neural activity on the behavior of the organism. For example, PAC expression in certain neurons has been shown to alter the grooming behavior in fruit flies exposed to blue light.[2] Channelrhodopsin-2 is also used in a similar fashion.

AC-III structure

File:Adenylyl cyclase.png
Structure of adenylate cyclase

Most class III adenylyl cyclases are transmembrane proteins with 12 transmembrane segments. The protein is organized with 6 transmembrane segments, then the C1 cytoplasmic domain, then another 6 membrane segments, and then a second cytoplasmic domain called C2. The important parts for function are the N-terminus and the C1 and C2 regions. The C1a and C2a subdomains are homologous and form an intramolecular 'dimer' that forms the active site. In Mycobacterium tuberculosis, the AC-III polypeptide is only half as long, comprising one 6-transmembrane domain followed by a cytoplasmic domain, but two of these form a functional homodimer that resembles the mammalian architecture.

Types of AC-III

There are ten known isoforms of adenylate cyclases in mammals:

These are also sometimes called simply AC1, AC2, etc., and, somewhat confusingly, sometimes Roman numerals are used for these isoforms that all belong to the overall AC class III. They differ mainly in how they are regulated, and are differentially expressed in various tissues throughout mammalian development.

AC-III regulation

Adenylate cyclase is dually regulated by G proteins (Gs stimulating activity and Gi inhibiting it), and by forskolin, as well as other isoform-specific effectors:

  • Isoforms III, V and VIII are also stimulated by Ca2+/calmodulin.
  • Isoforms I and VI are inhibited by Ca2+ in a calmodulin-independent manner.
  • Isoforms II, IV and IX are stimulated by beta gamma subunits of the G protein.
  • Isoforms I, V and VI are most clearly inhibited by Gi, while other isoforms show less dual regulation by the inhibitory G protein.
  • Soluble AC (sAC) is not a transmembrane form and is not regulated by G proteins or forskolin, instead acts as a bicarbonate/pH sensor. It is anchored at various locations within the cell and, with phosphodiesterases, forms local cAMP signalling domains.[3]

In neurons, calcium-sensitive adenylate cyclases are located next to calcium ion channels for faster reaction to Ca2+ influx; they are suspected of playing an important role in learning processes. This is supported by the fact that adenylate cyclases are coincidence detectors, meaning that they are activated only by several different signals occurring together. In peripheral cells and tissues adenylate cyclases appear to form molecular complexes with specific receptors and other signaling proteins in an isoform-specific manner.

Class IV

AC-IV was first reported in the bacterium Aeromonas hydrophila, and the structure of the AC-IV from Yersinia pestis has been reported. These are the smallest of the AC enzyme classes; the AC-IV from Yersinia is a dimer of 19 kDa subunits with no known regulatory components.

Class V and VI

These forms of AC have been reported in specific bacteria (Prevotella ruminicola and Rhizobium etti, respectively) and have not been extensively characterized.

Additional images


  1. ^ Reece J, Campbell N (2002). Biology. San Francisco: Benjamin Cummings. p. 207. ISBN 0-8053-6624-5. 
  2. ^ Schröder-Lang S, Schwärzel M, Seifert R, Strünker T, Kateriya S, Looser J, Watanabe M, Kaupp UB, Hegemann P, Nagel G (January 2007). "Fast manipulation of cellular cAMP level by light in vivo". Nat. Methods 4 (1): 39–42. PMID 17128267. doi:10.1038/nmeth975. 
  3. ^ Rahman N, Buck J, Levin LR. pH sensing via bicarbonate-regulated "soluble" adenylyl cyclase (sAC) Front Physiol. 2013 Nov 25;4:343. eCollection 2013. Review. PMID 4324443

Further reading

  • Sodeman W, Sodeman T (2005). "Physiologic- and Adenylate Cyclase-Coupled Beta-Adrenergic Receptors". Sodeman's Pathologic Physiology: Mechanisms of Disease. W B Saunders Co. pp. 143–145. ISBN 978-0721610108. 

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