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Function and Classification

MyoD, along with Myf5, is responsible for muscle cell differentiation and establishment of the myogenic lineage. It is a member of the basic helix loop helix (bHLH) family and myogenic factors subfamily of proteins ^[1].

1 Structure
2 DNA Interaction
3 Regulation
4 Knockout Effects

Structure

MyoD has a basic region at its amino-terminal end, which functions in binding the transcription factor to a region of the DNA known as the E-box. At the carboxyl-terminal end is MyoD's HLH domain. The HLH domain functions in protein-protein interactions and forms homodimeric and heterodimeric complexes ^[2].MyoD also contains an acidic activation domain. The activity of this activation domain has been observed to increase drastically upon deletion of residues in other parts of the protein. This suggests that the acidic activation domain is buried within the protein in vivo and can be activated by subtle changes in structure ^[3]. MyoD's ability to activate endogenous genes has been shown to rely on two regions. The first is a region rich in cysteine and histidine residues that is between the acidic activation domain and the bHLH domain. The second is a region near the carboxyl terminus of the protein. These regions are conserved in proteins with shared functionality ^[4]

DNA Interaction

MyoD, along with most other bHLH proteins, recognizes the concensus DNA sequence CAN NTG, where N can be any base. This sequence is known as the E-box and is bound by MyoD's in DNA's major groove. MyoD's basic region residues indirectly establish selectivity for specific E-box sequences by influencing the conformation in which the basic region binds DNA. There are responsible for the DNA interaction that provides MyoD's myogenic effect: Arg111, Ala114, Thr115, and Lys124 ^[5].

Regulation

MyoD is subject to regulation both by complex formation with other proteins and by DNA binding. Differences in E-box sequences, as well as sequences flanking the E-box, and in complex formation determine the transcription factor's effect and allow differentiation into a diverse array of muscle cells ^[6]. MyoD is only functional when bound to DNA. It has been proposed that DNA binding, with its accompanying structural changes, is required in vivo to free the acidic activation domain and activate MyoD's myogenic functions ^[7].

MyoD functions as a transcriptional activator only as a heterodimer with E proteins, which are a sub-family of bHLH proteins. This interaction takes place in the bHLH domain of both proteins. In one experiment, forced binding of E12 to MyoD that had been inhibited using E protein fragments substantially restored MyoD's activity ^[8]. The myogenic ability of MyoD is inhibited by the presence of another bHLH protein known as Twist. Twist inhibits MyoD by competitively binding E proteins and preventing MyoD-E protein heterodimers from forming ^[9].

The protein IFRD1 is an activating cofactor of MyoD. This protein and MyoD cooperatively activate muscle-specific enhancers. This same cofactor also represses NF-κB, which has been shown to inhibit MyoD mRNA translation ^[10].

NFATc1 is a transcription factor that inhibits MyoD activity. This is inhibition is accomplished through physically obstructing MyoD's activation domain, preventing transcriptional activity. This process functions to convert fast-twitch muscle to slow-twitch muscle ^[11].

MyoD is degraded by ubiquination of its N-terminal Lys residue. Data suggests that this occurs through attachment of ubiquitin at the N-terminal residue, followed by synthesis of a polyubiquitin chain on an internal Lys residue, which sufficiently disrupts MyoD's structure to cause degradation. This process is a major pathway of selective protein degradation in eukaryotic cells ^[12].

Knockout Effects

Knockout mutations of the MyoD gene have been shown to produce no distinct skeletal muscle phenotype due to an increase in Myf5 activation. Mutants lacking both MyoD and Myf5 fail to develop skeletal musculature all together ^[13].

References

[1] [2] [3] [4] [5] http://www.ncbi.nlm.nih.gov/pmc/articles/PMC232510/

↑ Phospho Site Plus. http://www.phosphosite.org/proteinAction.do?id=3637&showAllSites=true (accessed October 6, 2015)
↑ Jones S. An overview of the basic helix-loop-helix proteins. Genome Biol. 2004;5(6):226. Epub 2004 May 28. PMID:15186484 doi:http://dx.doi.org/10.1186/gb-2004-5-6-226
↑ Weintraub, H., Dwarki, V. J., Verma, I., Davis, R., Hollenberg, S., Snider, L., Lassar, A., Tapscott, S. J. Muscle-specific transcriptional activation by MyoD. Genes & Dev. 1991. 5. 1377-1386
↑ Gerber, A. N., Klesert, T. R., Berstrom, D. A., Tapscott, S. J. Two domains of MyoD mediate transcriptional activation of genes in repressive chromatin: a mechanism for lineage determination in myogenesis. Genes & Dev. 1997. 11. 436-450
↑ Kophengnavong, T., Michnowicz, J. E., & Blackwell, T. K. Establishment of Distinct MyoD, E2A, and Twist DNA Binding Specificities by Different Basic Region-DNA Conformations. Molecular and Cellular Biology, 2000, 20. 261–272.
↑ Jones S. An overview of the basic helix-loop-helix proteins. Genome Biol. 2004;5(6):226. Epub 2004 May 28. PMID:15186484 doi:http://dx.doi.org/10.1186/gb-2004-5-6-226
↑ Weintraub, H., Dwarki, V. J., Verma, I., Davis, R., Hollenberg, S., Snider, L., Lassar, A., Tapscott, S. J. Muscle-specific transcriptional activation by MyoD. Genes & Dev. 1991. 5. 1377-1386
↑ Yang Z, MacQuarrie KL, Analau E, Tyler AE, Dilworth FJ, Cao Y, Diede SJ, Tapscott SJ. MyoD and E-protein heterodimers switch rhabdomyosarcoma cells from an arrested myoblast phase to a differentiated state. Genes Dev. 2009 Mar 15;23(6):694-707. doi: 10.1101/gad.1765109. PMID:19299559 doi:http://dx.doi.org/10.1101/gad.1765109
↑ Hamamori, Y., Wu, H. Y., Sartorelli, V., & Kedes, L. The basic domain of myogenic basic helix-loop-helix (bHLH) proteins is the novel target for direct inhibition by another bHLH protein, Twist. Molecular and Cellular Biology. 1997. 17. 6563–6573.
↑ Micheli L, Leonardi L, Conti F, Maresca G, Colazingari S, Mattei E, Lira SA, Farioli-Vecchioli S, Caruso M, Tirone F. PC4/Tis7/IFRD1 stimulates skeletal muscle regeneration and is involved in myoblast differentiation as a regulator of MyoD and NF-kappaB. J Biol Chem. 2011 Feb 18;286(7):5691-707. doi: 10.1074/jbc.M110.162842. Epub 2010, Dec 2. PMID:21127072 doi:http://dx.doi.org/10.1074/jbc.M110.162842
↑ Federation AJ, Bradner JE, Meissner A. The use of small molecules in somatic-cell reprogramming. Trends Cell Biol. 2014 Mar;24(3):179-87. doi: 10.1016/j.tcb.2013.09.011. Epub, 2013 Oct 31. PMID:24183602 doi:http://dx.doi.org/10.1016/j.tcb.2013.09.011
↑ Breitschopf K, Bengal E, Ziv T, Admon A, Ciechanover A. A novel site for ubiquitination: the N-terminal residue, and not internal lysines of MyoD, is essential for conjugation and degradation of the protein. EMBO J. 1998 Oct 15;17(20):5964-73. PMID:9774340 doi:http://dx.doi.org/10.1093/emboj/17.20.5964
↑ Arnold, H. H.; Braun, T. Targeted inactivation of myogenic factor genes reveals their role during mouse myogenesis: a review. Int. J. Dev. Biol. 1996. 40. 345-353

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Function and Classification

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Structure

DNA Interaction

Regulation

Knockout Effects

References

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