Geometric frustration in the myosin superlattice of vertebrate muscle

Geometric frustration results from an incompatibility between minimum energy arrangements and the geometry of a system, and gives rise to interesting and novel phenomena. Here, we report geometric frustration in a native biological macromolecular system---vertebrate muscle. We analyse the disorder in the myosin filament rotations in the myofibrils of vertebrate striated (skeletal and cardiac) muscle, as seen in thin-section electron micrographs, and show that the distribution of rotations corresponds to an archetypical geometrically frustrated system---the triangular Ising antiferromagnet. Spatial correlations are evident out to at least six lattice spacings. The results demonstrate that geometric frustration can drive the development of structure in complex biological systems, and may have implications for the nature of the actin--myosin interactions involved in muscle contraction. Identification of the distribution of myosin filament rotations with an Ising model allows the extensive results on the latter to be applied to this system. It shows how local interactions (between adjacent myosin filaments) can determine long-range order and, conversely, how observations of long-range order (such as patterns seen in electron micrographs) can be used to estimate the energetics of these local interactions. Furthermore, since diffraction by a disordered system is a function of the second-order statistics, the derived correlations allow more accurate diffraction calculations, which can aid in interpretation of X-ray diffraction data from muscle specimens for structural analysis.

Hox Proteins in the Regulation of Muscle Development

Hox genes encode evolutionary conserved transcription factors that specify the anterior–posterior axis in all bilaterians. Being well known for their role in patterning ectoderm-derivatives, such as CNS and spinal cord, Hox protein function is also crucial in mesodermal patterning. While well described in the case of the vertebrate skeleton, much less is known about Hox functions in the development of different muscle types. In contrast to vertebrates however, studies in the fruit fly, Drosophila melanogaster, have provided precious insights into the requirement of Hox at multiple stages of the myogenic process. Here, we provide a comprehensive overview of Hox protein function in Drosophila and vertebrate muscle development, with a focus on the molecular mechanisms underlying target gene regulation in this process. Emphasizing a tight ectoderm/mesoderm cross talk for proper locomotion, we discuss shared principles between CNS and muscle lineage specification and the emerging role of Hox in neuromuscular circuit establishment.

Ssdp influences Wg expression and embryonic somatic muscle identity in Drosophila melanogaster

The somatic muscles of the Drosophila embryo and larvae share structural and functional similarities with vertebrate skeletal muscles and serve as a powerful model for studying muscle development. Here we show that the evolutionarily conserved Ssdp protein is required for the correct patterning of somatic muscles. Ssdp is part of the conserved Chi/LDB-Ssdp (ChiLS) complex that is a core component of the conserved Wg/Wnt enhanceosome, which responds to Wg signals to regulate gene transcription. Ssdp shows isoform specific expression in developing somatic muscles and its loss of function leads to an aberrant somatic muscle pattern due to a deregulated muscle identity program. Ssdp mutant embryos fail to maintain adequate expression levels of muscle identity transcription factors and this results in aberrant muscle morphology, innervation, attachment and fusion. We also show that the epidermal expression of Wg is downregulated in Ssdp mutants and that Ssdp interacts with Wg to regulate the properties of a subset of ventral muscles. Thus, our data unveil the dual contribution of Ssdp to muscle diversification by regulating the expression of muscle-intrinsic identity genes and by interacting with the extrinsic factor, Wg. The knowledge gained here about Ssdp and its interaction with Wg could be relevant to vertebrate muscle development.

Computational analysis of vertebrate myoglobins reveals aggregation resistance in aquatic birds and higher surface hydrophobicity in fish

Myoglobin is the major oxygen carrying protein in vertebrate muscle. Previous studies identified in secondarily aquatic mammalian lineages high myoglobin net charge, which serves to prevent aggregation at the extremely high intracellular myoglobin concentrations found in these species. However, it is unknown how aquatic birds that dive for extended durations prevent myoglobin aggregation at their high intracellular myoglobin concentrations. It is also unknown whether secondarily aquatic lineages reduced the surface hydrophobicity of their myoglobins to prevent aggregation. Here, we used a deep learning-predicted distance-based protein folding algorithm to model the tertiary structures of 302 vertebrate myoglobin orthologs and performed a comparative analysis of their predicted net charge and surface hydrophobicities. The results suggest that aquatic avian divers, such as penguins and diving ducks, evolved highly charged myoglobins to reduce aggregation propensity and allow greater storage of oxygen for extended underwater foraging. High myoglobin net charge was also identified in golden eagles, a species that routinely suffers high-altitude hypoxia. Although no general association was found between myoglobin surface hydrophobicity and intracellular concentration, comparison of predicted net charge and surface hydrophobicities revealed significant differences between major vertebrate classes; bird myoglobins are the most positively charge, reptile myoglobins are the most negatively charged, and the myoglobins of ray-finned fish (Actinopterygii) have higher surface hydrophobicity than those of lobe-finned fish (Sarcopterygii). Our findings indicate the convergent evolution of high myoglobin net charge in aquatic birds and mammals, and offer novel insights into the diversification of myoglobin among vertebrate clades.

The myosin interacting-heads motif present in live tarantula muscle explains tetanic and posttetanic phosphorylation mechanisms

Striated muscle contraction involves sliding of actin thin filaments along myosin thick filaments, controlled by calcium through thin filament activation. In relaxed muscle, the two heads of myosin interact with each other on the filament surface to form the interacting-heads motif (IHM). A key question is how both heads are released from the surface to approach actin and produce force. We used time-resolved synchrotron X-ray diffraction to study tarantula muscle before and after tetani. The patterns showed that the IHM is present in live relaxed muscle. Tetanic contraction produced only a very small backbone elongation, implying that mechanosensing—proposed in vertebrate muscle—is not of primary importance in tarantula. Rather, thick filament activation results from increases in myosin phosphorylation that release a fraction of heads to produce force, with the remainder staying in the ordered IHM configuration. After the tetanus, the released heads slowly recover toward the resting, helically ordered state. During this time the released heads remain close to actin and can quickly rebind, enhancing the force produced by posttetanic twitches, structurally explaining posttetanic potentiation. Taken together, these results suggest that, in addition to stretch activation in insects, two other mechanisms for thick filament activation have evolved to disrupt the interactions that establish the relaxed helices of IHMs: one in invertebrates, by either regulatory light-chain phosphorylation (as in arthropods) or Ca2+-binding (in mollusks, lacking phosphorylation), and another in vertebrates, by mechanosensing.

Energetic and physical limitations on the breaching performance of large whales

The considerable power needed for large whales to leap out of the water may represent the single most expensive burst maneuver found in nature. However, the mechanics and energetic costs associated with the breaching behaviors of large whales remain poorly understood. In this study we deployed whale-borne tags to measure the kinematics of breaching to test the hypothesis that these spectacular aerial displays are metabolically expensive. We found that breaching whales use variable underwater trajectories, and that high-emergence breaches are faster and require more energy than predatory lunges. The most expensive breaches approach the upper limits of vertebrate muscle performance, and the energetic cost of breaching is high enough that repeated breaching events may serve as honest signaling of body condition. Furthermore, the confluence of muscle contractile properties, hydrodynamics, and the high speeds required likely impose an upper limit to the body size and effectiveness of breaching whales.

One-to-one innervation of vocal muscles allows precise control of birdsong

SummaryThe motor control resolution of any animal behavior is limited to the minimal force step available when activating muscles, which is set by the number and size distribution of motor units (MUs) and muscle specific force [1, 2]. Birdsong is an excellent model system for understanding sequence learning of complex fine motor skills [3], but we know surprisingly little how the motor pool controlling the syrinx is organized [4] and how MU recruitment drives changes in vocal output [5]. Here we combine measurements of syringeal muscle innervation ratios with muscle stress and an in vitro syrinx preparation to estimate MU size distribution and the control resolution of fundamental frequency (fo), a key vocal parameter, in zebra finches. We show that syringeal muscles have extremely small MUs, with 50% innervating ≤ 3, and 13 – 17% innervating a single muscle fiber. Combined with the lowest specific stress (5 mN/mm2) known to skeletal vertebrate muscle, small force steps by the major fo controlling muscle provide control of 50 mHz to 4.2 Hz steps per MU. We show that the song system has the highest motor control resolution possible in the vertebrate nervous system and suggest this evolved due to strong selection on fine gradation of vocal output. Furthermore, we propose that high-resolution motor control was a key feature contributing to the radiation of songbirds that allowed diversification of song and speciation by vocal space expansion.

Fer1l6 is essential for the development of vertebrate muscle tissue in zebrafish

The precise spatial and temporal expression of genes is essential for proper organismal development. Despite their importance, however, many developmental genes have yet to be identified. We have determined that Fer1l6, a member of the ferlin family of genes, is a novel factor in zebrafish development. We find that Fer1l6 is expressed broadly in the trunk and head of zebrafish larvae and is more restricted to gills and female gonads in adult zebrafish. Using both genetic mutant and morpholino knockdown models, we found that loss of Fer1l6 led to deformation of striated muscle tissues, delayed development of the heart, and high morbidity. Further, expression of genes associated with muscle cell proliferation and differentiation were affected. Fer1l6 was also detected in the C2C12 cell line, and unlike other ferlin homologues, we found Fer1l6 expression was independent of the myoblast-to-myotube transition. Finally, analysis of cell and recombinant protein–based assays indicate that Fer1l6 colocalizes with syntaxin 4 and vinculin, and that the putative C2 domains interact with lipid membranes. We conclude that Fer1l6 has diverged from other vertebrate ferlins to play an essential role in zebrafish skeletal and cardiac muscle development.

Evolution of the highly repetitive PEVK region of titin across mammals

ABSTRACTThe protein titin plays a key role in vertebrate muscle where it acts like a giant molecular spring. Despite its importance and conservation over vertebrate evolution, a lack of high quality annotations in non-model species makes comparative evolutionary studies of titin challenging. The PEVK region of titin—named for its high proportion of Pro-Glu-Val-Lys amino acids—is particularly difficult to annotate due to its abundance of alternatively spliced isoforms and short, highly repetitive exons. To understand PEVK evolution across mammals, we first developed a bioinformatics tool, PEVK_Finder, to annotate PEVK exons from genomic sequences of titin and then applied it to a diverse set of mammals. PEVK_Finder consistently outperforms standard annotation tools across a broad range of conditions and improves annotations of the PEVK region in non-model mammalian species. We find that the PEVK region can be divided into two subregions (PEVK-N, PEVK-C) with distinct patterns of evolutionary constraint and divergence. The bipartite nature of the PEVK region has implications for titin diversification. In the PEVK-N region, certain exons are conserved and may be essential, but natural selection also acts on particular codons. This region is also rich in glutamate and may contribute to actin binding. In the PEVK-C, exons are more homogenous and length variation of the PEVK region may provide the raw material for evolutionary adaptation in titin function. Taken together, we find that the very complexity that makes titin a challenge for annotation tools may also promote evolutionary adaptation.