Heads and tails: The notochord develops differently in the cranium and caudal fin of Atlantic Salmon (<scp><i>Salmo salar</i></scp>, L.)

Kryvi, Harald; Nordvik, Kari; Fjelldal, Per Gunnar; Eilertsen, Mariann; Helvik, Jon Vidar; Støren, Eivind; Long, John H.

doi:10.1002/ar.24562

Cited by 3 publications

(5 citation statements)

References 55 publications

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“…S7A). In addition, b13a −/− mutants either lacked or had a significantly reduced opisthural cartilage, a specialized structure derived from the notochordal sheath ( 38 ) that covers the posterior end of the notochord (yellow arrowheads, fig. S7A) ( 7 ).…”

Section: Resultsmentioning

confidence: 99%

“…The evolution of the homocercal tail involved reduction and internalization of this notochordal extension, resulting in an enclosed notochord ending in an opisthural cartilage over the last series of hypurals in stem teleost lineages (Fig. 1, B and D) ( 4 , 38 , 40 , 73 , 74 ). Many teleost lineages with derived morphologies, such as mormyrids, toadfishes, and atherinomorphs ( 75 – 77 ), further specialized by ossifying the notochord’s posterior end and losing the opisthural cartilage ( 1 – 3 ).…”

Section: Discussionmentioning

confidence: 99%

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Hox genes control homocercal caudal fin development and evolution

Cumplido,

Arratia,

Desvignes

et al. 2024

Sci. Adv.

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Ancient bony fishes had heterocercal tails, like modern sharks and sturgeons, with asymmetric caudal fins and a vertebral column extending into an elongated upper lobe. Teleost fishes, in contrast, developed a homocercal tail characterized by two separate equal-sized fin lobes and the body axis not extending into the caudal fin. A similar heterocercal-to-homocercal transition occurs during teleost ontogeny, although the underlying genetic and developmental mechanisms for either transition remain unresolved. Here, we investigated the role of hox13 genes in caudal fin formation as these genes control posterior identity in animals. Analysis of expression profiles of zebrafish hox13 paralogs and phenotypes of CRISPR/Cas9-induced mutants showed that double hoxb13a and hoxc13a mutants fail to form a caudal fin. Furthermore, single mutants display heterocercal-like morphologies not seen since Mesozoic fossil teleosteomorphs. Relaxation of functional constraints after the teleost genome duplication may have allowed hox13 duplicates to neo- or subfunctionalize, ultimately contributing to the evolution of a homocercal tail in teleost fishes.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Hox genes control homocercal caudal fin development and evolution

Cumplido,

Arratia,

Desvignes

et al. 2024

Sci. Adv.

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show abstract

“…5 and 12A), it is reasonable to infer that this distribution pattern of slow muscle fibers within the deep muscles of the caudal region has been evolutionarily and developmentally conserved across these closely related teleost species. From the evidence that slow muscle fibers were found in a deep muscle in the caudal region of several teleost species from different lineages, it is expected that there may be a developmental mechanism specific to teleost fish that differentiates slow muscle fibers in the deep muscles at the caudal level (Flammang, 2014; Flammang and Lauder, 2008, 2009; Kryvi et al, 2021; Nag, 1972). Further comparison of immunohistochemical features of slow and fast muscle fibers in more distantly related teleost species will reveal whether this is correct.…”

Section: Discussionmentioning

confidence: 99%

“…It also very well could be that the function of the notochord and its attached tissues at the most posterior level differs from that of equivalent tissues (notochord and neural tube) at the mid-trunk region. Indeed, it has been shown in salmon species ( Salmo salar ) that the posterior- and anterior regions of the notochord could be very different (Kryvi et al, 2021). Thus, it is reasonable to consider that applying the same molecular mechanisms directly to explain the differentiation processes of both trunk and tail muscle fibers could be challenging.…”

Section: Discussionmentioning

confidence: 99%

“…Presumably due to the complexity of the muscle arrangement and structure in the caudal region, there has been limited immunohistochemical research conducted on muscle fibers in this area. In fact, while early research showed that the caudal muscle of teleost species contains both slow and fast muscles, their distribution patterns in muscle tissues and their relative location with the other skeletal tissues have not been well investigated yet (Flammang and Lauder, 2008, 2009; Kryvi et al, 2021; Nag, 1972). Thus, in this study, we conducted a detailed immunohistochemical analysis of the musculoskeletal system in the twin-tail goldfish, especially, focusing on the caudal region.…”

Section: Introductionmentioning

confidence: 99%

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Evolutionary Insights into Muscle Fiber Distribution in the Twin Tails of Ornamental Goldfish

Ota,

Abe,

Wang

et al. 2024

Preprint

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Twin-tail ornamental goldfish have a bifurcated caudal fin with a morphology that is extremely diverged from the conventional body plan of the vertebrates. Here, we investigate the musculoskeletal histology of this bifurcated caudal fin. From some of the investigated twin-tail goldfish, we found a twin-tail goldfish specific muscle (hereafter referred to as the “medial caudal muscle”) between left and right bifurcated caudal fin skeletons. Our immunohistochemical analyses revealed that the medial caudal muscle showed mediolaterally biased distribution patterns of the slow and fast muscle fibers. Similar distribution patterns were also commonly observed in several deep muscles of wild-type goldfish as well as zebrafish, suggesting that these fishes share the same molecular developmental mechanisms even though their morphologies are highly diverged. These findings provide empirical evidence to consider how the histological features of a newly emerged morphology are influenced by pre-existing highly conserved developmental mechanisms.This manuscript is here published as a living communication (as described in Gnaiger, 2021). The authors intend to share findings when they are available, encourage feedback and discussion, and invite knowledge exchange.

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A new method for regionalization of the vertebral column in salmonids based on radiographic hallmarks

Sankar,

Kryvi,

Fraser

et al. 2024

Journal of Fish Biology

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Current procedures to establish vertebral column regionalization (e.g., histology) in fish are time consuming and difficult to apply. The aim of this study was to develop a more rapid and accurate radiology‐based method for Atlantic salmon (Salmo salar). A detailed analysis of 90 animals (4 kg) led to the establishment of region‐specific radiographic hallmarks. To elucidate its transferability to other salmonid species, radiography was carried out in brown trout (Salmo trutta), Arctic char (Salvelinus alpinus), rainbow trout (Oncorhynchus mykiss), pink salmon (Oncorhynchus gorbuscha), and Chinook salmon (Oncorhynchus tshawytscha). This method was also evaluated for whole ungutted fish. The vertebral column of Atlantic salmon can be subdivided into five regions (R1–R5) based on anatomy: postcranial (R1, V1, and V2), abdominal (R2, V3–V26), transitional (R3, V27–V36), caudal (R4, V37–V53), and ural (R5, V54–V59). The following specific radiographic hallmarks allow the identification of regions: (i) lack of ribs in R1, (ii) modified parapophysis of the first vertebra of R3, (iii) prominent hemal spine of the first vertebra of R4, and (iv) the separated hemal spine of the most cranial pre‐ural vertebra of R5. These hallmarks were all transferable to the other salmonid species assessed. The results include a further description of various region‐specific characteristics in Atlantic salmon. The method was found applicable for sedated/whole ungutted fish, verifying it as quick and easy compared to other regionalization methods. The regions defined by radiology in this study agree with the vertebral column regions recently defined for Chinook salmon (O. tshawytscha). Thus, and considering the results of this study on various salmonid species, the currently developed regionalization protocol can be generally used for salmonids.

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Heads and tails: The notochord develops differently in the cranium and caudal fin of Atlantic Salmon (Salmo salar, L.)

Cited by 3 publications

References 55 publications

Hox genes control homocercal caudal fin development and evolution

Hox genes control homocercal caudal fin development and evolution

Evolutionary Insights into Muscle Fiber Distribution in the Twin Tails of Ornamental Goldfish

A new method for regionalization of the vertebral column in salmonids based on radiographic hallmarks

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