Gametogenesis in placental and non‐placental ovicellate cheilostome Bryozoa

Dyrynda, P. E. J.; King, P. E.

doi:10.1111/j.1469-7998.1983.tb02810.x

Cited by 37 publications

(35 citation statements)

References 21 publications

(35 reference statements)

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“…In Gymnolaemata, the largest bryozoan class with >1000 genera, matrotrophy was, until recently, known only in relatively few taxa -in the viviparous family Epistomiidae (genera Epistomia, Synnotum) and in the families Bugulidae (Bicellariella, Bugula), Candidae (Scrupocellaria), and Hippothoidae (Celleporella). These taxa are among the majority of gymnolaemates that brood their embryos in extrazooidal incubation chambers (ovicells) (Marcus 1938, 1941, Woollacott & Zimmer 1972, 1975, Dyrynda 1981, Dyrynda & King 1982, 1983, Dyrynda & Ryland 1982, Hughes 1987, Santagata & Banta 1996, Ostrovsky 1998.We report here the results of an extensive lightmicroscopic anatomical study, revealing that EEN is far more common in gymnolaemates than previously realized. The results point out seemingly independent appearances of matrotrophy.…”

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confidence: 75%

Independent evolution of matrotrophy in the major classes of Bryozoa: transitions among reproductive patterns and their ecological background

Ostrovsky¹,

Gordon²,

Lidgard³

2009

Mar. Ecol. Prog. Ser.

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Bryozoa are unique among invertebrates in possessing placenta-like analogues and exhibiting extraembryonic nutrition in all high-level (class) taxa. Extant representatives of the classes Stenolaemata and Phylactolaemata are evidently all placental. Within the Gymnolaemata, placentalike systems have been known since the 1910s in a few species, but are herein reported to be widespread within this class. Placental forms include both viviparous species, in which embryonic development occurs within the maternal body cavity, and brooding species, in which development proceeds outside the body cavity. We have also identified an unknown reproductive pattern involving macrolecithal oogenesis and placental nutrition from a new, taxonomically extensive anatomical study of 120 species in 92 genera and 48 families of the gymnolaemate order Cheilostomata. Results support the hypothesis of evolution of oogenesis and placentation among Cheilostomata from oligolecithal to macrolecithal oogenesis, followed by brooding, through incipient matrotrophy combining macrolecithal oogenesis and placentation, to oligolecithal oogenesis with subsequent placental brooding. The distribution of reproductive patterns within the phylum suggests that variations of placentation evolved in all 3 bryozoan classes, and possibly several times within both gymnolaemate orders. We infer that extraembryonic nutrition may be advantageous to species through enhanced developmental plasticity, and, in fast-growing ephemeral colonies, simultaneous volumetric growth and embryonic development may facilitate earlier larval release and occupation of vacant space. KEY WORDS: Matrotrophy · Placenta · Reproductive patterns · Evolution · BryozoaResale or republication not permitted without written consent of the publisher

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confidence: 75%

Independent evolution of matrotrophy in the major classes of Bryozoa: transitions among reproductive patterns and their ecological background

Ostrovsky¹,

Gordon²,

Lidgard³

2009

Mar. Ecol. Prog. Ser.

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“…Noteworthy, among bryozoans various degrees of matrotrophy are reported in the cheilostome genus Bugula alone, in which the embryonic enlargement ranges from 6.3‐ to 500‐fold in different species (Woollacott and Zimmer ; Dyrynda and King ; see also Table ). This closely reminds a continuum of variation in matrotrophic provisioning recorded in such fish genera as Poeciliopsis , Nomorhamphus , and Dermogenys (see Reznick et al , 2007a).…”

Section: Discussionmentioning

confidence: 99%

“…The same is true of species from the family Epistomiidae (pattern V) in which uninterrupted EEN is supported by intracolonial transport of nutrients via funicular cords (Marcus ; Dyrynda ; Dyrynda and King ). Thus, similarly to oogenesis, matrotrophic nutrition occurs independently of the presence or absence of a functioning polypide in the zooid (see Dyrynda and Ryland ; Dyrynda and King ; Ostrovsky , 2009). This suggests a high degree of colonial integration enabling an inter‐zooidal distribution of nutrients to nonfeeding (including, incubating) zooids.…”

Section: Discussionmentioning

confidence: 99%

“…Of more importance is that the first larvae will be released earlier in matrotrophs because their oogenesis is shorter. For instance, it takes about 6 weeks from the beginning of the egg formation in the ovary until the larval release in nonmatrotrophic cheilostome Chartella papyracea , and just 3 weeks in matrotrophic Bugula flabellata (Dyrynda and Ryland ; Dyrynda and King ). Such a strategy (simultaneous embryonic growth and development) would benefit the species with ephemeral colonies that live in seasonal waters, allowing them to occupy free biotopes/niches because of the more rapid production of the first generation of larvae.…”

Section: Discussionmentioning

confidence: 99%

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From Incipient to Substantial: Evolution of Placentotrophy in a Phylum of Aquatic Colonial Invertebrates

Ostrovsky

2013

Evolution

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Matrotrophy has long been known in invertebrates, but it is still poorly understood and has never been reviewed. A striking example of matrotrophy (namely, placentotrophy) is provided by the Bryozoa, a medium-sized phylum of the aquatic colonial filter feeders. Here I report on an extensive anatomical study of placental analogues in 21 species of the bryozoan order Cheilostomata, offering the first review on matrotrophy among aquatic invertebrates. The first anatomical description of incipient placentotrophy in invertebrates is presented together with the evidence for multiple independent origins of placental analogues in this order. The combinations of contrasting oocytic types (macrolecithal or microlecithal) and various degrees of placental development and embryonic enlargement during incubation, found in different bryozoan species, are suggestive of a transitional series from the incipient to the substantial placentotrophy accompanied by an inverse change in oogenesis, a situation reminiscent of some vertebrates. It seems that matrotrophy could trigger the evolution of sexual zooidal polymorphism in some clades. The results of this study show that this phylum, with its wide variety of reproductive patterns, incubation devices, and types of the simple placenta-like systems, offers a promising model for studying parallel evolution of placentotrophy in particular, and matrotrophy in general.

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“…These wide-ranging research results encompass different aspects of larval, post-settlement and colonial performance. Bugula neritina embryos grow about 500 times larger, favoured by a placenta-like mechanism [90], while the increase factor in other Bryozoa [25] varies between 7 and 30; in general, the larger the egg, the lesser the nutrient input during the embryonic stage.…”

Section: Discussionmentioning

confidence: 99%

Some Bryozoa species recently introduced into the Azores: reproductive strategies as a proxy for further spread

et al. 2016

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In the marine environment, control of invasive species' population levels, that is, keeping them at an abundance level which is below a density-dependent adverse effect, may be the most attainable goal for the management of introduced bryozoans. An improved understanding of reproductive strategies and life history traits is key in order to understand the spreading potential. The assessment of the magnitude and temporal dynamics of propagule pressure from the reproducing population important for the success of control actions and needs is to be determined prior to any field intervention. The reproductive cycle of three fouling bryozoans (Bugula neritina, Tricellaria inopinata and Virididentula dentata) in the waters of the Azores Archipelago was assessed. The study revealed that although the release of larvae can occur throughout the entire year, its intensity and developmental and the attachment success of the ancestrula are not even throughout the year and that each species' reproductive development needs to be determine independently. In the light of these findings, it is possible to determine the best time to apply field actions aimed at controlling invasive population's density levels, optimizing the always scarce financial resources for marine management.

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Gametogenesis in placental and non‐placental ovicellate cheilostome Bryozoa

Cited by 37 publications

References 21 publications

Independent evolution of matrotrophy in the major classes of Bryozoa: transitions among reproductive patterns and their ecological background

Independent evolution of matrotrophy in the major classes of Bryozoa: transitions among reproductive patterns and their ecological background

From Incipient to Substantial: Evolution of Placentotrophy in a Phylum of Aquatic Colonial Invertebrates

Some Bryozoa species recently introduced into the Azores: reproductive strategies as a proxy for further spread

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