Snežana Kojić

We report the identification and characterization of a novel 32-kDa protein expressed in skeletal muscle and located in the Z-disc of the sarcomere. We found that this protein binds to three other Z-disc proteins; therefore, we have named it FATZ, gamma-filamin/ABP-L, alpha-actinin and telethonin binding protein of the Z-disc. From yeast two-hybrid experiments we are able to show that the SR3-SR4 domains of alpha-actinin 2 are required to bind the COOH-terminal region of the FATZ as does gamma-filamin/ABP-L. Furthermore, by using a glutathione S-transferase overlay assay we find that FATZ also binds telethonin. The level of FATZ protein in muscle cells increases during differentiation, being clearly detectable before the onset of myosin. Although FATZ has no known interaction domains, it would appear to be involved in a complex network of interactions with other Z-band components. On the basis of the information known about its binding partners, we could envisage a central role for FATZ in the myofibrillogenesis. After screening our muscle expressed sequence tag data base and the public expressed sequence tag data bases, we were able to assemble two other muscle transcripts that show a high level of identity with FATZ in two different domains. Therefore, FATZ may be the first member of a small family of novel muscle proteins.

Remodeling is a stringently controlled process that enables adequate response of muscle cells to constant physical stresses. In this process, different kinds of stimuli have to be sensed and converted into biochemical signals that ultimately lead to alterations of muscle phenotype. Several multiprotein complexes located in the sarcomere and organized on the titin molecular spring have been identified as stress sensors and signal transducers. In this review, we focus on Ankrd1/CARP and Ankrd2/Arpp proteins,which belong to the muscle ankyrin repeat protein family (MARP) involved in a mechano-signaling pathway that links myofibrillar stress response to muscle gene expression. Apart from the mechanosensory function, they have an important role in transcriptional regulation, myofibrillar assembly, cardiogenesis and myogenesis. Their altered expression has been demonstrated in neuromuscular disorders, cardiovascular diseases, as well as in tumors, suggesting a role in pathological processes. Although analyzed in a limited number of patients, there is a considerable body of evidence that MARP proteins could be suitable candidates for prognostic and diagnostic biomarkers.