Troponin I is required for myofibrillogenesis and sarcomere formation in Drosophila flight muscle

doi:10.1242/jcs.01024

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JCS ePress online publication date 16 Mar 2004
doi: 10.1242/jcs.01024

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Research Article

Troponin I is required for myofibrillogenesis and sarcomere formation in Drosophila flight muscle

Upendra Nongthomba, Sam Clark, Mark Cummins, Maqsood Ansari, Meg Stark, and John C. Sparrow^*
^* Author for correspondence (e-mail: jcs1{at}york.ac.uk)

Myofibrillar proteins assemble to form the highly ordered repetitivecontractile structural unit known as a sarcomere. Studies ofmyogenesis in vertebrate cell culture and embryonic developmentalsystems have identified some of the processes involved duringsarcomere formation. However, isoform changes during vertebratemuscle development and a lack of mutants have made it difficultto determine how these proteins assemble to form sarcomeres.The indirect flight muscles (IFMs) of Drosophila provide a uniquegenetic system with which to study myofibrillogenesis in vivo.We show in this paper that neither sarcomeric myosin nor actinare required for myoblast fusion or the subsequent morphogenesisof muscle fibres, i.e. fibre morphogenesis does not depend onmyofibrillogenesis. However, fibre formation and myofibrillogenesisare very sensitive to the interactions between the sarcomericproteins. A troponin I (TnI) mutation, hdp³, leads to an absenceof TnI in the IFMs and tergal depressor of trochanter (TDT)muscles due to a transcript-splicing defect. Sarcomeres do notform and the muscles degenerate. TnI is part of the thin filamenttroponin complex which regulates muscle contraction. The effectsof the hdp³ mutation are probably caused by unregulated acto-myosininteractions between the thin and thick filaments as they assemble.We have tested this proposal by using a transgenic myosin constructto remove the force-producing myosin heads. The defects in sarcomericorganisation and fibre degeneration in hdp³ IFMs are suppressed,although not completely, indicating the need for inhibitionof muscle contraction during muscle development. We show thatmRNA and translated protein products of all the major thin filamentproteins are reduced in hdp³ muscles and discuss how this andprevious studies of thin filament protein mutants indicate acommon co-ordinated control mechanism that may be the primarycause of the muscle defects.

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