Expression of a novel combination of fast and slow troponin T isoforms in rabbit extraocular muscles

Complex tropomyosin and troponin T isoform expression patterns in orbital and global fibers of adult dog and rat extraocular muscles

We reported marked differences in the myosin heavy and light chain (MHC and MLC) isoform composition of fast and slow fibers between the global and orbital layers of dog extraocular muscles. Many dog extraocular fibers, especially orbital fibers, have MHC and MLC isoform patterns that are distinct from those in limb skeletal muscles. Additional observations suggested possible differences in the tropomyosin (Tm) and troponin T (TnT) isoform composition of global and orbital fibers. Therefore, we tested, using SDS-PAGE and immunoblotting, whether differences in Tm and TnT isoform expression do, in fact, exist between global and orbital layers of dog and rat EOMs and to compare expression patterns among identified fast and slow single fibers from both muscle layers. The Tm isoforms expressed in global fast and slow fibers are the same as in limb fast (α-Tm and β-Tm) and slow (γ-Tm and β-Tm) fibers, respectively. Orbital slow orbital fibers, on the other hand, each co-express all three sarcomeric Tm isoforms (α, β and γ). The results indicate that fast global and orbital fibers express only fast isoforms of TnT, but the relative amounts of the individual isoforms are different from those in limb fast muscle fibers and an abundant fast TnT isoform in the orbital layer was not detected in fast limb muscles. Slow fibers in both layers express slow TnT isoforms and the relative amounts also differ from those in limb slow fibers. Unexpectedly, significant amounts of cardiac TnT isoforms were also detected in slow fibers, especially in the orbital layer in both species. TnI and TnC isoform patterns are the same as in fast and slow fibers in limb muscles. These results expand the understanding of the elaborate diversity in contractile protein isoform expression in mammalian extraocular muscle fibers and suggest that major differences in calcium-activation properties exist among these fibers, based upon Tm and TnT isoform expression patterns.

Development transitions of thin filament proteins in rat extraocular muscles

Extraocular muscles are a unique subset of striated muscles. During postnatal development, the extraocular muscles undergo a number of myosin isoform transitions that occur between postnatal day P10 (P10) and P15. These include: (1) loss of embryonic myosin from the global layer resulting in the expression restricted to the orbital layer; (2) the onset of expression of extraocular myosin and the putative tonic myosin (myh 7b/14); and (3) the redistribution of nonmuscle myosin IIB from a subsarcolemmal position to a sarcomeric distribution in the slow fibers of the global layer. For this study, we examined the postnatal appearance and distribution of α-actinin, tropomyosin, and nebulin isoforms during postnatal development of the rat extraocular muscles. Although sarcomeric α-actinin is detectable from birth, α-actinin 3 appears around P15. Both tropomyosin-1 and -2 are present from birth in the same distribution as in the adult animal. The expression of nebulin was monitored by gel electrophoresis and western blots. At P5-10, nebulin exhibits a lower molecular mass than observed P15 and later during postnatal development. The changes in α-actinin 3 and nebulin expression between P10 and P15 coincide with transitions in myosin isoforms as detailed above. These data point to P10-P15 as the critical period for the maturation of the extraocular muscles, coinciding with eyelid opening.

Regulation of troponin T expression during muscle development in sea bream Sparus auratus Linnaeus: the potential role of thyroid hormones

In the sea bream Sparus auratus three stage-specific fast troponin T (fTnT) isoforms have been cloned and correspond to embryonic-, larval- and adult-specific isoforms. Characterisation, using database searches, of the putative genomic organisation of Fugu rubripes and Tetraodon nigroviridis fTnT indicates that alternative exon splicing in the 5 region of the gene generates the different isoforms. Moreover, comparison of teleost fTnTs suggests that alternative splicing of fTnT appears to be common in teleosts. A different temporal expression pattern for each fTnT splice varotnt is found during sea bream development and probably relates to differing functional demands, as a highly acidic embryonic form (pI 5.16) is substituted by a basic larval form (pI 9.57). Thyroid hormones (THs), which play an important regulatory role in muscle development in flatfish and tetrapods, appear also to influence TnT gene expression in the sea bream. However, THs have a divergent action on different sea bream TnT genes and although the slow isoform (sTnT1) is TH-responsive, fTnT, sTnT2 and the itronless isoform (iTnT) are unaffected. The present results taken together with those published for flatfish seem to suggest differences may exist in the regulation of larval muscle development in teleosts.

Troponin T isoform expression is modulated during Atlantic halibut metamorphosis

BACKGROUND

Flatfish metamorphosis is a thyroid hormone (TH) driven process which leads to a dramatic change from a symmetrical larva to an asymmetrical juvenile. The effect of THs on muscle and in particular muscle sarcomer protein genes is largely unexplored in fish. The change in Troponin T (TnT), a pivotal protein in the assembly of skeletal muscles sarcomeres and a modulator of calcium driven muscle contraction, during flatfish metamophosis is studied.

RESULTS

In the present study five cDNAs for halibut TnT genes were cloned; three were splice variants arising from a single fast TnT (fTnT) gene; a fourth encoded a novel teleost specific fTnT-like cDNA (AfTnT) expressed exclusively in slow muscle and the fifth encoded the teleost specific sTnT2. THs modified the expression of halibut fTnT isoforms which changed from predominantly basic to acidic isoforms during natural and T4 induced metamorphosis. In contrast, expression of red muscle specific genes, AfTnT and sTnT2, did not change during natural metamorphosis or after T4 treatment. Prior to and after metamorphosis no change in the dorso-ventral symmetry or temporal-spatial expression pattern of TnT genes and muscle fibre organization occurred in halibut musculature.

CONCLUSION

Muscle organisation in halibut remains symmetrical even after metamorphosis suggesting TH driven changes are associated with molecular adaptations. We hypothesize that species specific differences in TnT gene expression in teleosts underlies different larval muscle developmental programs which better adapts them to the specific ecological constraints.

Muscle protein expression of pikeperches (Stizostedion lucioperca and S. volgense)

The purpose of the present study was to investigate the muscle protein expression in two pikeperches (Stizostedion lucioperca and S. volgense) through intra- and intermyomeric composition of white muscles. Using denaturing 10% sodium dodecylsulfate-polyacrylamide gel electrophoresis, muscle protein expression was studied in relation to within- and between-species morphological development, sex, maturity and age of pikeperches. Myosin, actin and troponin have a distinct role in the contraction and length tension of muscle fibers of these species. No obvious intramyomeric differences were found in the myosin heavy chain of both species. Myosin light chains (15-38 kDa) have different expression in different age groups. The muscle protein of the fingerling and adult S. lucioperca had high molecular weight (50 kDa) myosin in contrast to the other Percid species. The molecular weight of actins increased comparatively in low-age-group fish. ATP is stored in myosin and released to cause contraction when myosin comes in contact with actin of the experimental fish. Troponin regulates increasing concentration of light-chain myosin in mature fish. Because troponin T has been implicated in the regulation of skeletal muscle kinetics, muscle contraction kinetics was predicted in different age groups. The muscle proteins of both sexes of these species have polymorphism in various age groups but have no difference in similar aged fish. No muscle protein dimorphism was found in these Percid species. The white muscle protein composition and contractile properties affect power production during fast, unsteady movement and swimming.

Biological organization of the extraocular muscles

Extraocular muscle is fundamentally distinct from other skeletal muscles. Here, we review the biological organization of the extraocular muscles with the intent of understanding this novel muscle group in the context of oculomotor system function. The specific objectives of this review are threefold. The first objective is to understand the anatomic arrangement of the extraocular muscles and their compartmental or layered organization in the context of a new concept of orbital mechanics, the active pulley hypothesis. The second objective is to present an integrated view of the morphologic, cellular, and molecular differences between extraocular and the more traditional skeletal muscles. The third objective is to relate recent data from functional and molecular biology studies to the established extraocular muscle fiber types. Developmental mechanisms that may be responsible for the divergence of the eye muscles from a skeletal muscle prototype also are considered. Taken together, a multidisciplinary understanding of extraocular muscle biology in health and disease provides insights into oculomotor system function and malfunction. Moreover, because the eye muscles are selectively involved or spared in a variety of neuromuscular diseases, knowledge of their biology may improve current pathogenic models of and treatments for devastating systemic diseases.

Structural details of rat extraocular muscles and three-dimensional reconstruction of the rat inferior rectus muscle and muscle-pulley interface

Light microscopy, electron microscopy and morphometry revealed structural details and allowed generation of a three-dimensional reconstruction of the pulley and muscle-pulley interface of extraocular muscle. The inferior rectus orbital layer was bifurcate in shape and extended anterior to the pulley. The putative pulley structure itself was asymmetric; loosely attached at the orbital aspect it adhered tightly to the global aspect of muscle. Orbital multiply innervated fiber proportion increased anterior to the pulley insertion site. Additionally longitudinal variation in juxtaposition of orbital and global layers was noted. These newly described structural details provide novel mechanistic insight for extraocular muscle function in rats.

Constitutive properties, not molecular adaptations, mediate extraocular muscle sparing in dystrophic mdx mice

Extraocular muscle (EOM) is spared in Duchenne muscular dystrophy. Here, we tested putative EOM sparing mechanisms predicted from existing dystrophinopathy models. Data show that mdx mouse EOM contains dystrophin-glycoprotein complex (DGC)-competent and DGC-deficient myofibers distributed in a fiber type-specific pattern. Up-regulation of a dystrophin homologue, utrophin, mediates selective DGC retention. Counter to the DGC mechanical hypothesis, an intact DGC is not a precondition for EOM sarcolemmal integrity, and active adaptation at the level of calcium homeostasis is not mechanistic in protection. A partial, fiber type-specific retention of antiischemic nitric oxide to vascular smooth muscle signaling is not a factor in EOM sparing, because mice deficient in dystrophin and alpha-syntrophin, which localizes neuronal nitric oxide synthase to the sarcolemma, have normal EOMs. Moreover, an alternative transmembrane protein, alpha7beta1 integrin, does not appear to substitute for the DGC in EOM. Finally, genomewide expression profiling showed that EOM does not actively adapt to dystrophinopathy but identified candidate genes for the constitutive protection of mdx EOM. Taken together, data emphasize the conditional nature of dystrophinopathy and the potential importance of nonmechanical DGC roles and support the hypothesis that broad, constitutive structural cell signaling, and/or biochemical differences between EOM and other skeletal muscles are determinants of differential disease responsiveness.

The superfast extraocular myosin (MYH13) is localized to the innervation zone in both the global and orbital layers of rabbit extraocular muscle

Extraocular muscles (EOMs) are the most molecularly heterogeneous and physiologically diverse mammalian striated muscles. They express the entire array of striated muscle myosins, including a specialized myosin heavy chain MYH13, which is restricted to extraocular and laryngeal muscles. EOMs also exhibit a breadth of contractile activity, from superfast saccades to slow tracking and convergence movements. These movements are accomplished by the action of six ultrastructurally defined fiber types that differ from the type IIa, IIb, IIx and I fibers found in other skeletal muscles. Attempts to associate different eye movements with either the expression of different myosins or the activity of particular EOM fiber types are complicated by the molecular heterogeneity of several of the fiber types, and by electromyography studies showing that the majority of extraocular motor units participate in both fast and slow eye movements. To better understand the role of MYH13 in ocular motility, we generated MYH13-sequence-specific antibodies and used SDS-PAGE to quantify the regional distribution of myosin in EOM and to characterize its heterogeneity in single fibers. These studies demonstrate that MYH13 is preferentially expressed in the majority of orbital and global fibers in the central innervation zone of rabbit EOM. Many individual fibers express MYH13 with the fast IIb myosin and varying amounts of IIx myosin. The differential localization of MYH13, coupled with specialization of the sarcoplasmic reticulum and thin filament systems, probably explains how activation of the endplate band region enables the majority of EOM fibers to contribute to superfast contractions.

Extraocular muscle: cellular adaptations for a diverse functional repertoire

Oculomotor control systems are considerably more complex and diverse than are spinal skeletomotor systems. Moreover, individual skeletal muscles are frequently functional role-specific, while all extraocular muscles operate across a very wide dynamic range. We contend that the novel phenotype of the extraocular muscles is a direct consequence of the functional demands imposed upon this muscle group by the central eye movement controllers. This review highlights five basic themes of extraocular muscle biology that set them apart from more typical skeletal muscles, specifically, the (a) novel innervation pattern, (b) heterogeneity in contractile proteins, (c) structural and functional compartmentalization of the rectus and oblique muscles, (d) diversity of extraocular muscle fiber types, and (e) relationship between the novel muscle phenotype and the differential response of these muscles in neuromuscular and endocrine disease. Finally, new data from broad genome-wide profiling studies are reviewed, with global gene expression patterns lending substantial support to the notion that the extraocular muscles are fundamentally different from traditional skeletal muscle. This novel eye muscle phenotype represents an adaptation that exploits the full range of variability in skeletal muscle to meet the needs of visuomotor systems.

Longitudinal variation in muscle protein expression and contraction kinetics of largemouth bass axial muscle

The present study investigates muscle protein expression in largemouth bass Micropterus salmoides through intra- and intermyomeric comparisons of white muscle. Using denaturing SDS-polyacrylamide gel electrophoresis, muscle protein expression in the arm and cone regions of sequential myomeres was compared for three bass. Low percentage (4.75 %) polyacrylamide-SDS gels and cyanogen bromide (CNBr) peptide mapping revealed no obvious intramyomeric differences between the myosin heavy chains of the arm and cone regions. Electrophoresis of myofibrils and muscle homogenates on higher percentage gels also failed to demonstrate any significant differences between arm and cone regions in either the myosin light chains or any of the major insoluble and soluble contractile proteins. Two differences were discovered intermyomerically: (i) the ratio of two troponin T isoforms changed from head to tail and (ii) caudal muscle had a lower total parvalbumin content than rostral muscle. Since troponin T and parvalbumin have been implicated in the regulation of skeletal muscle kinetics, longitudinal variation in muscle contraction kinetics was predicted. Subsequent experiments revealed that bass rostral white muscle showed faster rates of activation and relaxation than more caudal muscle, as has been observed in white muscle of other fish species. Rostral–caudal variations in white muscle protein composition and contractile properties are predicted to affect patterns of power production during fast, unsteady swimming.

Extraocular muscle is defined by a fundamentally distinct gene expression profile

Skeletal muscle fibers are defined by patterned covariation of key traits that determine contractile and metabolic characteristics. Although the functional properties of most skeletal muscles result from their proportional content of a few conserved muscle fiber types, some, typically craniofacial, muscles exhibit fiber types that appear to lie outside the common phenotypic range. We analyzed gene expression profiles of three putative muscle classes, limb, masticatory, and extraocular muscle (EOM), in adult mice by high-density oligonucleotide arrays. Pairwise comparisons using conservative acceptance criteria identified expression differences in 287 genes between EOM and limb and/or masticatory muscles. Use of significance analysis of microarrays methodology identified up to 400 genes as having an EOM-specific expression pattern. Genes differentially expressed in EOM reflect key aspects of muscle biology, including transcriptional regulation, sarcomeric organization, excitation-contraction coupling, intermediary metabolism, and immune response. These patterned differences in gene expression define EOM as a distinct muscle class and may explain the unique response of these muscles in neuromuscular diseases.

X linked dominant congenital isolated bilateral ptosis: the definition and characterisation of a new condition

AIMS

To characterise the inheritance of ptosis in one particular pedigree.

METHODS

The pedigree was analysed clinically and genetically to assess the mode of inheritance and to ascribe a gene locus for the condition.

RESULTS

Affected members of the pedigree have bilateral symmetrical congenital isolated ptosis, a condition which is linked to genetic markers on the X chromosome in this family.

CONCLUSION

A pedigree with dominantly inherited congenital bilateral ptosis is presented. The pedigree exhibits X linked dominant inheritance. A new ophthalmic condition was thereby characterised-namely, X linked dominant congenital isolated bilateral ptosis.

Eye muscle sparing by the muscular dystrophies: lessons to be learned?

The devastating consequences of the various muscular dystrophies are even more obvious when a muscle or muscle group is spared. The study of the exceptional cell or tissue responses may prove to be of considerable value in the analysis of disease mechanisms. The small muscles responsible for eye movements, the extraocular muscles, have functional and morphological characteristics that set them aside from other skeletal muscles. Notably, these muscles are clinically unaffected in Duchenne/Becker, limb-girdle, and congenital muscular dystrophies, pathologies due to a broken mechanical or signaling linkage between the cytoskeleton and the extracellular matrix. Uncovering the strategies used by the extraocular muscles to "naturally" protect themselves in these diseases should contribute to knowledge of both pathogenesis and treatment. We propose that careful investigation of the cellular determinants of extraocular muscle-specific properties may provide insights into how these muscles avoid or adapt to the cascade of events leading to myofiber degeneration in the muscular dystrophies.

Contractile activation characteristics of single permeabilized fibres from levator palpebrae superioris, orbicularis oculi and vastus lateralis muscles from humans

1. We investigated the contractile activation characteristics of single membrane-permeabilized fibres from the following muscles from humans: the levator palpebrae superioris (LPS), an extraocular muscle; the orbicularis oculi (OO), a facial muscle; and the vastus lateralis (VL), a major muscle of the thigh. 2. Single permeabilized muscle fibres were isolated from each of the different muscles, attached to a sensitive force transducer and activated by rapid immersion in buffered solutions of varying [Ca2+] and [Sr2+]. Fibres were allocated into discrete populations based on their contractile characteristics, including their differential force responses during Ca2+ and Sr2+ activation. 3. With the exception of one fibre from the LPS, all 152 fibres sampled from the three different human muscles could be classified into either population I (slow, type I) or population II (fast, type II) based on their force-pCa(pSr) relations. The LPS muscle fibre which was unable to be classified into the two major fibre populations displayed a combination of the typical force-pCa(pSr) relations for mammalian fast and slow muscle fibres. 4. Although fibres from the LPS, OO and VL muscles had similar differential sensitivities to Ca2+and Sr2+, the steepness of the force-pCa(pSr) curves for fibres from the LPS and OO muscles were highly variable compared with those for fibres from the VL muscle. Specific forces (N cm-2) of the smaller diameter fibres from the LPS and OO muscles were significantly lower than those of fibres from the VL muscle. 5. The differences in the contractile activation characteristics between fibres from the VL muscle and those of fibres from facial (OO) muscles and extraocular (LPS) muscles, reflect the differences in their fibre composition that are responsible for their functional specificity.

The development of extraocular muscle calcium homeostasis parallels visuomotor system maturation

Extraocular muscle is modulated by unique genetic and epigenetic factors to produce an atypical phenotype. As a prelude to regulation studies, we characterized the development of cation homeostasis in the predominately fast-twitch extraocular muscles. By atomic absorption spectroscopy, total muscle calcium content declined from birth to postnatal day 27 and, thereafter, stabilized at a low level in limb but increased dramatically in extraocular muscle (to 40x limb values). By ELISA, the slow isoform of sarcoplasmic reticulum Ca2+-ATPase predominated in neonatal eye muscle, but subsequently was largely replaced by the fast isoform. This replacement in eye muscle was completed later than in limb. Residual, slow Ca2+-ATPase likely resides in an unusual slow tonic fiber type characteristic of eye muscle. Maturation of the definitive extraocular muscle Ca2+-ATPase pattern paralleled myofiber Ca2+ and sarcoplasmic reticulum content. These data show that, like myosin heavy chain expression patterns, the development of cation homeostatic mechanisms in extraocular muscle parallels landmarks in the maturation of vision and eye movement control systems. Findings suggest that cation homeostasis in extraocular muscle may be susceptible to perturbations of the developing visual sensory system, as we have previously shown for myosin.

Characterisation of troponin-T from salmonid fish

Five major troponin-T isoforms were isolated from the myotomal muscles of Atlantic salmon: three from fast muscle (Tn-T1F, Tn-T2F and Tn-T3F) and two from slow muscle (Tn-T1S and Tn-T2S). In addition to their presence in troponin preparations, these proteins were also recognised to be Tn-T on the basis of immunoreaction with anti-troponin-T antibodies and partial amino acid sequence. The electrophoretic mobility in the presence of SDS of the various Tn-Ts increases in the order: 1S < 1F < 2S < 2F < or = 3F. Compositional analysis shows that the higher M(r) forms (1F and 1S) contain considerably more proline, glutamic acid and alanine than the lower-M(r) forms (2F, 3F and 2S). Every isoform lacks cysteine and phosphoserine is present only in isoforms 2F and 3F. All of the Tn-Ts, with the exception of isoform 1F, are N-terminally blocked. CNBr fragments from same cell type Tn-Ts yield identical sequences over at least fifteen Edman cycles. Two full-length cDNA sequences, presumed to represent 1S and 3F, or isoforms that are highly similar, are reported. As documented for higher vertebrate Tn-Ts, the predicted primary structures display a non-uniform distribution of charged amino acids and greater divergence at each end than in the central section. The most striking difference between the two salmonid proteins is the presence of a N-terminal (proline-, glutamic acid- and alanine-rich) extension of about fifty amino acids in Tn-T1s (278 amino acids) that is missing from the fast muscle Tn-T (223 amino acids). The sequences also differ in that 1S lacks the known phosphorylation site while the fast-type isoform contains serine next to the initiating methionine. Of the two, the slow isoform has accumulated the greater number of substitutions.

The oculomotor periphery: the clinician's focus is no longer a basic science stepchild

The study of the oculomotor periphery, the extraocular muscles and their orbital attachments, is undergoing a rapid expansion. This is an important progression for both basic and clinical communities as, for too long, the ophthalmologist has worked primarily in the periphery and the basic researcher has been occupied with study of the central components of the oculomotor system. From recent studies, it is clear that the morphology, cell and molecular biology, and genetics of the eye muscles and their corresponding motoneuron pools, and muscle attachments within the orbit are more complex than has heretofore been appreciated.

Thyroid-associated ophthalmopathy: pathogenesis and clinical management

The pathogenesis of thyroid-associated ophthalmopathy is autoimmune. The questions to which answers are eagerly awaited are the identification of the autoantigen(s) and the definition of the autoimmune processes (cellular or humoral) responsible. Cellular and humoral immune responses and modulation by cytokines, against orbital tissues have been described. A link between the thyroid and the orbit seems inevitable, possibly in the form of a cross-reactive antigen, and top of the list of candidate antigens is the TSH receptor. Optimal treatment of TAO necessitates careful assessment. Thoughtful planning and timing and choice of intervention with conventional therapies, can lead to satisfactory results in the majority of cases. In addition to treating the severe complications, such as optic neuropathy, corneal exposure and muscle misalignment, corrective surgery to reconstruct the appearance of the patient's eyes should be made available.

Role of innervation for development and maintenance of troponin subunit isoform patterns in fast- and slow-twitch muscles of the rabbit

This study investigates the neural influence on the establishment and maintenance of muscle type-specific expression patterns of the three troponin (Tn) subunits, troponin T (TnT), troponin C (TnC), and troponin I (TnI) during postnatal development and in the adult rabbit. For this purpose, we followed changes in the expression of fast and slow TnT, TnC, and TnI isoforms at the protein and mRNA level in slow- and fast-twitch muscles. During postnatal development all fast Tn isoforms increased in fast-twitch muscle. Sequential transitions (TnTs-->TnT3f-->TnT1f) occurred in the TnT isoform pattern. These changes occurred in parallel with sequential transitions in the pattern of myosin heavy chain (HC) isoforms. Neonatal slow-twitch muscle displayed more mature (slow) isoform patterns for both TnT subunits and myosin HCs than fast-twitch muscle. Although the expression of slow TnC in slow-twitch muscle required innervation, denervation had little effect on slow TnT and TnI which seemed to be controlled by an intrinsic program. In fast-twitch muscle, denervation enhanced the expression of all slow Tn subunit isoforms. In addition, it led to a pronounced increase of the slow TnT2s isoform such that the amount of TnT2s exceeded that of TnT1s. The effects of denervation together with previous data on low-frequency stimulated muscle indicate that the expression of fast Tn isoforms in fast-twitch muscle is neurally controlled. The pattern of slow Tn isoforms in slow-twitch muscle seems to be regulated by an intrinsic program and, in addition, by neural influences.

Transitions from fetal to fast troponin T isoforms are coordinated with changes in tropomyosin and alpha-actinin isoforms in developing rabbit skeletal muscle

In adult fast skeletal muscle, specific combinations of thin filament and Z-line protein isoforms are coexpressed. To determine whether the expression of these sets of proteins, designated the TnT1f, TnT2f, and TnT3f programs, is coordinated during development, we characterized the transitions in troponin T (TnT), tropomyosin (Tm), and alpha-actinin isoforms that occur in developing fetal and neonatal rabbit skeletal muscle. Two coordinated developmental transitions were identified, and a novel pattern of thin filament expression was found in fetal muscle. In fetal muscle, new TnT species--whose protein and immunochemical properties suggest that they are the products of a new TnT gene--are expressed in combination with beta 2 Tm and alpha-actinin1f/s. This pattern, which is found in both back and hindlimb muscles, is specific to fetal and early neonatal muscle. Just prior to birth, there is a transition from the fetal program to the isoforms that define the TnT3f program, TnT3f, and alpha beta Tm. Like the fetal program, expression of the TnT3f program appears to be a general feature of muscle development, because it occurs in a variety of fast muscles as well as in the slow muscle soleus. The transition to adult patterns of thin filament expression begins at the end of the first postnatal week. Based on studies of erector spinae, the isoforms comprising the TnT2f program, TnT2f, alpha 2 Tm, and alpha-actinin2f, appear and increase coordinately at this time. The transitions, first to the TnT3f program, and then to adult patterns of expression indicate that synthesis of the isoforms comprising each program is coordinated during muscle specialization and throughout muscle development. In addition, these observations point to a dual role for the TnT3f program, which is the major thin filament program in some adult muscles, but appears to bridge the transition from developmentally to physiologically regulated patterns of thin filament expression during the late fetal and early neonatal development.

N-terminal amino acid sequences of three functionally different troponin T isoforms from rabbit fast skeletal muscle

The different isoforms of fast skeletal muscle troponin T (TnT) are generated by alternative splicing of several 5' exons in the fast TnT gene. In rabbit skeletal muscle this process results in three major fast TnT species, TnT1f, TnT2f and TnT3f, that differ in a region of 30 to 40 amino acid residues near the N terminus. Differential expression of these three isoforms modulates the activation of the thin filament by calcium. To establish a basis for further structure-function studies, we have sequenced the N-terminal region of these proteins. TnT2f is the fast TnT sequenced by Pearlstone et al. The larger species TnT1f contains six additional amino acid residues identical in sequence and position to those encoded by exon 4 in the rat fast skeletal muscle TnT gene. TnT3f also contains that sequence but lacks 17 amino acid residues spanning the region encoded by exons 6 and 7 of the rat gene. These three TnTs appear to be generated by discrete alternative splicing pathways, each differing by a single event. Comparison of these TnT sequences with those from chicken fast skeletal muscle and bovine heart shows that the splicing pattern resulting in the excision of exon 4 is evolutionarily conserved and leads to a more calcium-sensitive thin filament.