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1. Evolutionary Patterns of Modularity in the Linkage Systems of the Skull in Wrasses and Parrotfishes

   https://doi.org/10.1093/iob/obad035  

   Gartner, S. M.; Larouche, O.; Evans, K. M.; Westneat, M. W. (September 2023, Integrative Organismal Biology)

   Synopsis The concept of modularity is fundamental to understanding the evolvability of morphological structures and is considered a central framework for the exploration of functionally and developmentally related subsets of anatomical traits. In this study, we explored evolutionary patterns of modularity and integration in the 4-bar linkage biomechanical system of the skull in the fish family Labridae (wrasses and parrotfishes). We measured evolutionary modularity and rates of shape diversification of the skull partitions of three biomechanical 4-bar linkage systems using 205 species of wrasses (family: Labridae) and a three-dimensional geometric morphometrics data set of 200 coordinates. We found support for a two-module hypothesis on the family level that identifies the bones associated with the three linkages as being a module independent from a module formed by the remainder of the skull (neurocranium, nasals, premaxilla, and pharyngeal jaws). We tested the patterns of skull modularity for four tribes in wrasses: hypsigenyines, julidines, cheilines, and scarines. The hypsigenyine and julidine groups showed the same two-module hypothesis for Labridae, whereas cheilines supported a four-module hypothesis with the three linkages as independent modules relative to the remainder of the skull. Scarines showed increased modularization of skull elements, where each bone is its own module. Diversification rates of modules show that linkage modules have evolved at a faster net rate of shape change than the remainder of the skull, with cheilines and scarines exhibiting the highest rate of evolutionary shape change. We developed a metric of linkage planarity and found the oral jaw linkage system to exhibit high planarity, while the rest position of the hyoid linkage system exhibited increased three dimensionality. This study shows a strong link between phenotypic evolution and biomechanical systems, with modularity influencing rates of shape change in the evolution of the wrasse skull. 

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2. Beaks promote rapid morphological diversification along distinct evolutionary trajectories in labrid fishes (Eupercaria: Labridae)

   https://doi.org/10.1093/evolut/qpad115  

   Evans, Kory M.; Larouche, Olivier; Gartner, Samantha M.; Faucher, Rose E.; Dee, Sylvia G.; Westneat, Mark W.; Stayton, ed., Tristan; Connallon, ed., Tim (June 2023, Evolution)

   Abstract The upper and lower jaws of some wrasses (Eupercaria: Labridae) possess teeth that have been coalesced into a strong durable beak that they use to graze on hard coral skeletons, hard-shelled prey, and algae, allowing many of these species to function as important ecosystem engineers in their respective marine habitats. While the ecological impact of the beak is well understood, questions remain about its evolutionary history and the effects of this innovation on the downstream patterns of morphological evolution. Here we analyze 3D cranial shape data in a phylogenetic comparative framework and use paleoclimate modeling to reconstruct the evolution of the labrid beak across 205 species. We find that wrasses evolved beaks three times independently, once within odacines and twice within parrotfishes in the Pacific and Atlantic Oceans. We find an increase in the rate of shape evolution in the Scarus+Chlorurus+Hipposcarus (SCH) clade of parrotfishes likely driven by the evolution of the intramandibular joint. Paleoclimate modeling shows that the SCH clade of parrotfishes rapidly morphologically diversified during the middle Miocene. We hypothesize that possession of a beak in the SCH clade coupled with favorable environmental conditions allowed these species to rapidly morphologically diversify. 

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3. Ecological shifts underlie parallels between ontogenetic and evolutionary allometries in parrotfishes

   https://doi.org/10.1098/rspb.2024.1897  

   Neves, Mayara P; Hugi, April; Chan, Howan; Arnold, Kaleigh; Titus, Kara; Westneat, Mark W; Zelditch, Miriam L; Brandl, Simon; Evans, Kory M (October 2024, Proceedings of the Royal Society B: Biological Sciences)

   During ontogeny, animals often undergo significant shape and size changes, coinciding with ecological shifts. This is evident in parrotfishes (Eupercaria: Labridae), which experience notable ecological shifts during development, transitioning from carnivorous diets as larvae and juveniles to herbivorous and omnivorous diets as adults, using robust beaks and skulls for feeding on coral skeletons and other hard substrates. These ontogenetic shifts mirror their evolutionary history, as parrotfishes are known to have evolved from carnivorous wrasse ancestors. Parallel shifts at ontogenetic and phylogenetic levels may have resulted in similar evolutionary and ontogenetic allometric trajectories within parrotfishes. To test this hypothesis, using micro-computed tomography (μCT) scanning and three-dimensional geometric morphometrics, we analyse the effects of size on the skull shape of the striped parrotfishScarus iseriand compare its ontogenetic allometry to the evolutionary allometries of 57 parrotfishes and 162 non-parrotfish wrasses. The youngS. iserihave skull shapes resembling non-parrotfish wrasses and grow towards typical adult parrotfish forms as they mature. There was a significant relationship between size and skull shapes and strong evidence for parallel ontogenetic and evolutionary slopes in parrotfishes. Our findings suggest that morphological changes associated with the ecological shift characterizing interspecific parrotfish evolution are conserved in their intraspecific ontogenies. 

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4. Community structure and microhabitat associations of cryptobenthic reef fishes in Veracruz, Mexico

   https://doi.org/10.1007/s00338-025-02763-1  

   Rivera-Higueras, Mariana; Hemingson, Christopher R; Pouchoulen_Alemán, Aurora_de Monserrat; Cipolla, Kyra_Jean M; Souza, Philip M; Brandl, Simon J (October 2025, Coral Reefs)

   Local habitat availability can strongly affect animal communities. On coral reefs, the biodiversity of small, bottom-dwelling (‘cryptobenthic’) reef fishes and drivers of their community assembly have yet to be explored in many locations. Here, we investigate how local and regional factors shape the structure and composition of cryptobenthic reef fish communities in the Veracruz Reef System National Park (VRS) in the Gulf of Mexico (GoM). Focusing on five reefs in the VRS, we surveyed cryptobenthic reef fish communities at scales of reef outcrops (~ 3–5 m2) and isolated microhabitats, while also quantifying the benthic composition of each reef to determine microhabitat availability. We found no significant differences in species richness or abundance across park regions and reef zones, but community composition differed qualitatively across reef zones. Furthermore, we discovered strong differences in cryptobenthic reef fishes’ preferences for various microhabitats, which are likely to drive community assembly and provide evidence for species-specific vulnerabilities to reef degradation. Caves harbored the highest biodiversity and abundance of cryptobenthic fishes, while gorgonian soft corals and algae supported the fewest species and individuals. The endemic gobies Tigrigobius redimiculus and Elacatinus jarocho both showed high abundance and occurrence but displayed opposite patterns of microhabitat specialization; T. redimiculus was categorized as a microhabitat generalist, while E. jarocho was revealed as a cave-dwelling specialist species. Overall, our quantitative exploration of the cryptobenthic reef fish community in the southwest GoM provides a crucial baseline for habitat and biodiversity monitoring in the region and highlights E. jarocho as an emblematic, endemic indicator species that will be vulnerable to extinction if further reduction of habitat complexity occurs. 

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5. The Role of Developmental Integration and Historical Contingency in the Origin and Evolution of Cypriniform Trophic Novelties

   https://doi.org/10.1093/icb/icz056  

   Hernandez, L P; Cohen, K E (May 2019, Integrative and Comparative Biology)

   Abstract While functional morphologists have long studied the evolution of anatomical structures, the origin of morphological novelties has received less attention. When such novelties first originate they must become incorporated into an integrated system to be rendered fully functional. Thus, developmental integration is key at the origin of morphological novelties. However, given enough evolutionary time such integration may be broken, allowing for a division of labor that is facilitated by subsequent decoupling of structures. Cypriniformes represent a diverse group of freshwater fishes characterized by several trophic novelties that include: kinethmoid-mediated premaxillary protrusion, a muscular palatal and post-lingual organ, hypertrophied lower pharyngeal jaws that masticate against the base of the neurocranium, novel pharyngeal musculature controlling movement of the hypertrophied lower pharyngeal jaws, and in a few species an incredibly complex epibranchial organ used to aggregate filtered phytoplankton. Here, we use the wealth of such trophic novelties in different cypriniform fishes to present case studies in which developmental integration allowed for the origin of morphological innovations. As proposed in case studies 1 and 2 trophic innovations may be associated with both morphological and lineage diversification. Alternatively, case studies 3 and 4 represent a situation where ecological niche was expanded but with no concomitant increase in species diversity. 

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