25.10:
Introduction to Actin
In the cytoskeleton, actins are the building blocks of cytoskeletal microfilaments. Actin monomers have a round shape and are called globular or G-actin.
These monomers polymerize head-to-tail forming a tight, right-handed helical structure called filamentous or F-actin.
Each actin subunit has an outer and an inner domain joined by a smaller linker helix. Such an arrangement forms two clefts: the upper cleft binds an ATP and a magnesium ion. The lower hydrophobic cleft is specific for actin-binding proteins.
G-actin has a low ATPase activity that is enhanced in F-actin. When an ATP-G-Actin complex binds F-actin, ATP is hydrolyzed to ADP and phosphate, forming a highly stable filament.
The ATP-bound growing end of F-actin is called the plus-end, while the other end, bound to ADP, is the minus-end.
Actins have different isoforms, broadly classified into alpha, beta, and gamma. They are expressed in different cell types, such as α-actin in contractile muscle fibers, β-actin in cell cortex, and γ- actin in smooth muscle fibers.
25.10:
Introduction to Actin
Actin is a highly conserved cytoskeletal protein found abundantly in eukaryotic cells. It constitutes 10% weight of the total cellular protein in muscle cells, while in non-muscle cells, it is lower and makes up around 1–5 percent of the total cell protein. Actin found in the unicellular amoebae and complex multicellular animals is around 80% similar, demonstrating their conservation over a billion years of evolution. Actin coding genes are conserved within species and across different species. For example, actins present in the yeast Saccharomyces cerevisiae and humans are 87% similar.
Actin was first discovered by W. D. Halliburton in 1887 in muscle extracts as a protein that can induce coagulation of the muscle plasma. It was later purified from muscle extract by Brunó Ferenc Straub in 1942. Straub named it 'actin' due to its ability to activate the motor protein myosin. In the early seventies, actin was also found in non-muscle cells and Acanthamoeba. In the late 1970s, Multiple actin isoforms with issue-specific expression were discovered by sequencing actins using amino acid hydrolysis. These isoforms were nearly identical, with only a few amino acid substitutions. They were classified into α-, β-, and γ-actins based on their isoelectric points. For example, birds and mammals have six actin isoforms expressed at different cell types. Actins expressed in skeletal muscle cells are classified as α-skeletal-actin, in cardiac muscles as α-cardiac-actin, and those in smooth muscles as α-smooth-actin and γ-smooth-actin. Two other isoforms, β-cyto-actin and γ-cyto-actin, are ubiquitously expressed in these organisms.
Subsequent research on these proteins led to the discovery of their role in various cellular functions such as muscle contraction, cell migration, cell adhesion, cell division, protein trafficking, and membrane organization. The first X-ray structure of monomeric G-actin associated with DNAse I was solved only in 1990, resulting in the first atomic model of actin filaments. Several other structures in complex with different proteins have been reported since then.
Suggested Reading
- Vedula, P., & Kashina, A. (2018). The makings of the 'actin code': regulation of actin's biological function at the amino acid and nucleotide level. Journal of cell science, 131(9), jcs215509. https://doi.org/10.1242/jcs.215509
- Kudryashov, D. S., & Reisler, E. (2013). ATP and ADP actin states. Biopolymers, 99(4), 245–256. https://doi.org/10.1002/bip.22155
- Dominguez, R., & Holmes, K. C. (2011). Actin structure and function. Annual review of biophysics, 40,169–186. https://doi.org/10.1146/annurev-biophys-042910-155359
- Wang, H., Robinson, R.C. and Burtnick, L.D., 2010. The structure of native G‐actin. Cytoskeleton, 67(7), pp.456-465.