Defensive strategies of modular organisms

Dyrynda, P. E. J.

doi:10.1098/rstb.1986.0035

Cited by 60 publications

(32 citation statements)

References 31 publications

(39 reference statements)

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“…The morphological diversity of avicularia suggests that many facets of a defensive/protective strategy may have evolved among avicularium-bearing colonies. Defensive mechanisms displayed by sedentary marine invertebrates may be structural or chemical (Dyrynda 1986, Peters et al 2003, Sharp et al 2007. Possible defensive mechanisms displayed by avicularia may therefore be of a mechanical (the physical entrapment of organisms) or chemical (secretion of bioactive compounds) nature, or even both.…”

Section: Discussionmentioning

confidence: 99%

Polymorphism and variation in modular animals: morphometric and density analyses of bryozoan avicularia

Carter¹,

Gordon²,

Gardner³

2010

Mar. Ecol. Prog. Ser.

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Avicularia are polymorphic zooids characteristic of most species of cheilostome bryozoans. We examined the morphological diversity of avicularia to elucidate morphometric patterns in 38 cheilostome species from 11 superfamilies collected from a range of depths (habitats) around New Zealand. Multivariate statistical analyses of 4 types of avicularia (adventitious, interzooidal, vicarious and vibracula) showed that vicarious and vibracula were morphometrically invariable, and vibracula morphometrically distinct, even though these 4 types are dissimilar in their relationships to progenitor zooids and colony budding pattern. Adventitious types showed extensive overlap in morphospace with interzooidal and vicarious types. No depth-related effect on either morphometric variation or colony density of avicularia was discerned over the depth ranges studied (< 8, 20-300, and 600-1000 m). Inter-colony variability in avicularian density existed in some species, whilst the main contributor to morphometric grouping was the type of avicularia involved. Greatest avicularian density occurred in colonies of those species possessing 2 types of avicularia (e.g. Caberea spp. adventitious and vibracula). Adventitious avicularia were the most common type, were morphometrically diverse and occurred at higher densities within colonies than interzooidal and vicarious types. Such polymorphism, frequency and density of adventitious types in natural populations may represent an evolutionary shift towards maximisation of functional efficiency at a smaller spatial scale of the colony. By analysing polymorph variation we show how a modular development promotes flexibility in module production, arrangement and morphology.KEY WORDS: Avicularia · Polymorphism · Morphometrics · Modularity · Bryozoa · Functional diversity · New Zealand Resale or republication not permitted without written consent of the publisherMar Ecol Prog Ser 399: [117][118][119][120][121][122][123][124][125][126][127][128][129][130] 2010 Zooidal polymorphism in cheilostome bryozoans consists of primary feeding zooids (which occur in all colonies), modified feeding and non-feeding zooids such as sexual dimorphs, and non-feeding heterozooids modified for attachment (stolons) and colony reinforcement (Ryland 1970, Silén 1977, Dick & Mawatari 2005. Additionally, many cheilostomes produce zooids bearing defensive spines, the occurrence of which may be induced by the presence of a known predator (Harvell 1991(Harvell , 1992. Avicularia are also thought to have a defensive function (Kaufmann 1968, Winston 1984. These are modified zooids that lack a functional feeding apparatus (gut and tentacle crown) and acquire nutrients through a colony-wide transport system (funicular system) (Hyman 1959, Banta 1973, Silén 1977, Winston 1984, McKinney & Jackson 1989. Avicularia are morphologically diverse ( Fig. 1A-H), but the basic design resembles an autozooid with a hypertrophied operculum (mandible). In its relaxed state, the mandible normally lies open, exposing a modified ori...

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Section: Discussionmentioning

confidence: 99%

Polymorphism and variation in modular animals: morphometric and density analyses of bryozoan avicularia

Carter¹,

Gordon²,

Gardner³

2010

Mar. Ecol. Prog. Ser.

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“…Convergence of form and function has accompanied the evolution of modular growth in terrestrial plants and colonial marine invertebrates (Dyrynda 1986). Part of this convergence is related to optimal exploitation of resources (space and light) and the ability to translocate energy products from sources to sinks.…”

Section: Discussionmentioning

confidence: 99%

“…Carbon transfer between sources (sites that export assimilates) and sinks (sites that import assimilates) and its regulation within colonial organisms are critical aspects in their biology (Dyrynda 1986). In hermatypic corals, photosynthetic products are continuously translocated from the symbiotic zooxanthellae to the host tissue, thereby contributing to a variety of energetic requirements such as maintenance, synthesis of new cells, formation of skeletal matrix, mucus production, deposition of calcium carbonate, and storage of energy-rich compounds for coral reproduction (Muscatine & Cernichiari 1969;Crossland et al 1980a,b;Muscatine et al 1981Muscatine et al , 1984Rinkevich & Loya 1983Kellogg & Patton 1983;Stimson 1987).…”

Section: Introductionmentioning

confidence: 99%

Prudent sessile feeding by the corallivore snail, Coralliophila violacea on coral energy sinks

Oren

Brickner

Loya

1998

Proc. R. Soc. Lond. B

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Convergence of form and function has accompanied the evolution of modular growth in terrestrial plants and colonial marine invertebrates. Part of this convergence is related to the optimal exploitation of resources (space and light) and the ability to translocate energy products from sources to sink sites. Feeding on the energy pathways and energy sinks of terrestrial plants is a well-known phenomenon. Hermatypic corals, the major organisms constructing tropical reef environments, contain photosynthetic algae (zooxanthellae), energetic products of which are translocated towards sink sites located at the corals' growing tips and regenerating areas. Despite the plant^coral convergence in energy pathways and sinks, there has been no evidence to date that coral energy sinks are exploited by coral predators. Gastropods of the genus Coralliophila are found feeding on coral margins, causing small and localized tissue damage. However, the ability of these snails to continue to feed without moving over a long period remains puzzling. Using a 14 C labelling technique, we found that colony margins of the stony coral Porites function as major energy sinks. When snails inhabited these sites they incorporated signi¢cant amounts of 14 C, indicating that they had fed on photosynthetic products translocated from the interior of the colony. Furthermore, when snails aggregate in the interior of the colony, thereby causing large surface injuries, they induce the development of signi¢cant new sink sites. This mode of prudent sessile feeding maximizes the e¤ciency of energy exploitation by the predatory snail, while minimizing tissue damage to the coral. The fact that energy sink sites occur in many coral species suggests that the strategy of sink exploitation for nutrition could also occur in many other marine host^symbiont relationships.

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“…Modularity allows best use of light and space and provides for flexibility needed in ever changing environment. This idea is also a key to our view of plants growth (Dyrynda 1986 A module of a Dicot tree is usually a short internode with a node, leaf and bud (Wyk and Wyk 2007). A module of D. draco (i.e.…”

Section: Modularity and The Tree Architecture Of The Dragon Treementioning

confidence: 99%

Photomorphogenesis in Dracaena draco

Krawczyszyn¹,

Krawczyszyn²

2015

Trees

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Key message Sunlight is a key environmental factor in growth, flowering and shaping of the Dracaena draco tree. Unidirectional light deforms the tree and may cause it to tilt. Abstract Dracaena draco, a tree-like monocot, lives in cycles of vegetative growth and flowering. The cycles, as well as the tree growth form, are under genetic control. What controls their length has been unknown before. We propose that it is sunlight. Our trees of the same origin, growing for 20 years in the garden in varying sunlight conditions, started to flower when 9-12, 16 and 18-19 years old, for those growing in full sun, part shade and shade, respectively. In full sun, they grow shorter trunks than those in shade, catching overhead sun. Their branches also had shorter or longer growth and flowering cycles depending on sunlight availability. D. draco tree exhibited strong phototropic response and its crown was organized by the direction of growing tips. In full and in overhead sun, it had a regular form but asymmetrical in unidirectional, oblique sunlight. An asymmetrical crown and the absence of reaction wood may cause the D. draco tree tilting and progressive loss of balance.

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Defensive strategies of modular organisms

Cited by 60 publications

References 31 publications

Polymorphism and variation in modular animals: morphometric and density analyses of bryozoan avicularia

Polymorphism and variation in modular animals: morphometric and density analyses of bryozoan avicularia

Prudent sessile feeding by the corallivore snail, Coralliophila violacea on coral energy sinks

Photomorphogenesis in Dracaena draco

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