Abstract
Tropomyosin, a ubiquitous protein in animals and fungi, is associated with the actin cytoskeleton and is involved with stabilising actin filaments and regulating the interaction of the filament with other actin binding proteins. The protein is best known for its role in regulating the interaction between actin and myosin in muscle contraction but in recent years its role as a major player in the organisation and dynamics of the cytoskeleton has been increasingly recognised. In mammals Tpm is expressed from four distinct genes and alternate splicing of each gene can produce a total of up to 40 different mRNA variants most of which are expressed as proteins. We are expecting a renaissance in the study of tropomyosins as the roles of these different isoforms are beginning to be deciphered. However, it is our belief that such a renaissance is being limited by confusion over the naming systems for the tropomyosin isoforms. These result in even experienced workers struggling to reconcile work done in different laboratories and at different times. We propose here a systematic nomenclature for tropomyosin based on the best current practice. We recommend the adoption of these names and a cross-reference to the table of alternate names and accession numbers for protein sequences is included here. The National Center for Biotechnology Information (NCBI) website has been amended to include the nomenclature for the human, mouse and rat genes.
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Tropomyosin (Tpm) is a protein family associated with the stabilisation and regulation of the actin cytoskeleton (Gunning et al. 2008). It is expressed in opisthokonts including animals and fungi, but is not documented in plants, protists or procaryotes (Barua et al. 2011; Cranz-Mileva et al. 2013). Tpm polymerises head to tail as a two-chained coiled coil along both sides of a helical actin filament stabilising the actin structure and interacting with a range of other actin binding proteins to regulate the actin cytoskeleton. The protein was discovered in the 1940s as a component of the actin filaments of striated muscle (Bailey 1946) and this remains the best studied example of Tpm function. In striated muscle, together with troponin, it enables calcium regulation of striated muscle contraction by blocking (−Ca2+) or allowing (+Ca2+) myosin access to its binding site on actin (Gordon et al. 2000; Geeves 2012). Since the 1940s the different possible roles of Tpm and the number of interacting partners has multiplied (see special issue of J Muscle Res. Cell Motil., Marston & Gautel 2013). We now know that in mammalian cells Tpm is expressed from four separate genes and alternate promoter selection and splicing of each gene can produce up to 40 different mRNA variants most of which have been shown to be expressed as proteins in different tissues (Pittenger et al. 1994; Vindin and Gunning 2013).
The steady discovery of different splice variants in specific tissues has, over the years, led to a proliferation of different names for the isoforms, some identified with specific tissues but later found with a broader distribution. This has resulted in a great deal of confusion in the literature and it is often difficult, even for those of us in the field, to be sure which isoforms we are each referring to. It must be an even bigger nightmare for those trying to enter the field. The lack of a coherent nomenclature is an impediment to progress. We firmly believe that Tpm research is due for a renaissance from both the structure–function perspective in muscle research and the cytoplasmic perspective in the localisation-function of distinct isoforms and their binding partners. This is evidenced by the collection of articles published in a special issue of J Muscle Res Cell Motil devoted to Tpm Marston & Gautel (2013). This renaissance will be enhanced if we can establish a widely agreed-upon nomenclature that the majority of active researchers will use. It will be much better if we can establish this now as the field begins to expand and other pressures develop on the nomenclature.
After consulting colleagues working with Tpm we now make a specific proposal for how the nomenclature could be simplified and rationalised and to make it compatible with current best practice for gene and protein names. The proposal keeps as close as possible to some well-established historical precedents.
Our suggestion is that any publication dealing with the tropomyosin protein should designate, at the first use, the formal name of the protein isoform as proposed here, and then define the short form or abbreviation that will be used thereafter in the article text. Reference to Tables 1, 2, 3 and 4 here will allow cross-reference to any earlier versions of the names used e.g., α-fast skeletal tropomyosin is Tpm1.1.
Detailed proposals
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1.
The human tropomyosin genes should be known as TPM 1 through TPM 4 (Tpm 1 through Tpm 4 for mouse and rat tropomyosin) to be consistent with other gene nomenclatures.
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2.
The protein short name Tm is historically well established but Tpm is consistent with standard protein nomenclature and is therefore preferred in the formal name.
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3.
Tpm1 or Tpm2 specifies the protein is from gene TPM1 or TPM2 etc.
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4.
Alternate isoforms are numbered systematically from one (e.g., Tpm1.1 etc.), keeping as close as possible to any precedent. Thus Tpm2.3 is the tropomyosin isoform from gene 2 isoform 3.
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5.
In the formal name a subscript designates the tissue most closely associated, historically, with the protein isoform. Many such isoforms have been since found in multiple tissues and such designations are not always useful.
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St striated muscle, cardiac/skeletal tissue
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Sm smooth muscle,
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Br brain
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Cy other cytoplasmic
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6.
The splicing of the four exons that vary in vertebrates can be designated by a four letter code; a.a.b.d indicates exon 1 is splice form a, exon 2 is splice form a, exon 6 is splice form b and exon 9 is splice form d.
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A dash as in b.-.b.d indicates that exon 2 is missing and therefore this is a short form of Tpm.
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Previous publications of Tpm isoforms have indicated that exon 9 can be a combination of two splice forms at the mRNA level (e.g., Vindin and Gunning 2013) but these reflect splice variants in non-coding regions at the 3′ end of the mRNA transcripts. We have therefore omitted such isoforms from our list of expressed proteins.
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7.
The formal names of the two tropomyosins from the TPM 1 gene, found in the contractile filaments of smooth muscle, are then
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Tpm1.3Sm(a.a.b.d) and Tpm1.4Sm(a.a.a.d)
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The short form of the name would be Tpm1.3 and Tpm1.4
Tables 1, 2, 3 and 4 list the current, known Tpm protein isoforms and the proposed formal names. As far as possible the alternate names for the same protein that have been used in the past are included in columns two and three. We also include, in Table 5, the full set of human Tpm amino acid sequences in the order that the exons appear in the gene. This will allow any ambiguity in the literature to be checked against the names and exon sequences used here. A fuller list of animal Tpm sequences can be found in Barua et al. 2011 and Schevzov et al. 2011.
It is almost certain that additional isoforms of tropomyosin will be identified in these species. Consideration of all possible splicing combinations already established in at least one isoform leads to a calculation of 48 possible distinct isoforms in humans without consideration of currently unknown splicing alternatives. For example, Cooley and Bergtrom (2001) identified an increased number of potential isoforms from the TPM1 gene using RT-PCR. Our ability to detect and confirm additional isoforms will depend on both the extent of expression across, and the levels of expression in, different cell types.
The NCBI accession numbers for each isoform are included in Tables 1, 2, 3 and 4 and the human, mouse and rat genes on the NCBI website have been amended to use the nomenclature as listed here.
References
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Barua B, Pamula MC et al (2011) Evolutionarily conserved surface residues constitute actin binding sites of tropomyosin. Proc Nat Acad Sci USA 108(25):10150–10155
Cooley BC, Bergtrom G (2001) Multiple combinations of alternatively spliced exons in rat tropomyosin-alpha gene mRNA: evidence for 20 new isoforms in adult tissues and cultured cells. Arch Biochem Biophys 390(1):71–77
Cranz-Mileva S, Pamula MC et al (2013) A molecular evolution approach to study the roles of tropomyosin in fission yeast. PLoS ONE 8(10):e76726
Geeves MA (2012) Thin filament regulation. Compr Biophys 4:251–267
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Gunning P, O’Neill G et al (2008) Tropomyosin-based regulation of the actin cytoskeleton in time and space. Physiol Rev 88(1):1–35
Marston SB, Gautel M (eds) (2013) Tropomyosin form and function. J Muscle Res Cell Motil 34(3–4):1573–2657
Pittenger MF, Kazzaz JA et al (1994) Functional properties of non-muscle tropomyosin isoforms. Curr Opin Cell Biol 6(1):96–104
Schevzov G, Whittaker SP et al (2011) Tropomyosin isoforms and reagents. Bioarchitecture 1(4):135–164
Vindin H, Gunning P (2013) Cytoskeletal tropomyosins: choreographers of actin filament functional diversity. J Muscle Res Cell Motil 34(3–4):261–274
Acknowledgments
This work was supported by the following grants National Institutes of Health (USA): GM-093065 to SEH-D and Wellcome Trust Programme Grant 085309 to MAG. We thank Michael Murphy and Lillian Riddick at the NCBI for their assistance in verifying accession numbers and for including the proposed nomenclature in the NCBI website.
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Geeves, M.A., Hitchcock-DeGregori, S.E. & Gunning, P.W. A systematic nomenclature for mammalian tropomyosin isoforms. J Muscle Res Cell Motil 36, 147–153 (2015). https://doi.org/10.1007/s10974-014-9389-6
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DOI: https://doi.org/10.1007/s10974-014-9389-6