Exploring the sexual diversity of flatworms: Ecology, evolution, and the molecular biology of reproduction

Ramm, Steven A.

doi:10.1002/mrd.22669

Cited by 31 publications

(27 citation statements)

References 102 publications

(140 reference statements)

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“…the allocation of reproductive resources into male and female reproduction (Ramm, 2017;Schärer and Ramm, 2016). Sex allocation theory investigates how an organism should partition its reproductive resources in order to gain maximal fitness in a given ecological context (Charnov, 1982).…”

Section: Introductionmentioning

confidence: 99%

“…The genus itself contains ca. 200 described species (see http://turbellaria.umaine.edu/) differing widely in various aspects of their reproduction, such as mating behaviour, sperm and genital morphology, and sex allocation (Schärer et al, 2011;Janssen et al, 2015;Ramm, 2017). Many of these traits exhibit evidence of rapid and correlated evolution, with one important distinction being the transition between those species that mate by reciprocal copulation versus those that mate by hypodermic insemination (Schärer et al, 2011), as we explain in more detail below.…”

Section: Introductionmentioning

confidence: 99%

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Self-fertilization, sex allocation and spermatogenesis kinetics in the hypodermically-inseminating flatworm Macrostomum pusillum

Giannakara

Ramm

2017

Journal of Experimental Biology

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The free-living flatworm genus Macrostomum is an emerging model system for studying the links between sex allocation, sexual selection and mating system evolution, as well as the underlying developmental and physiological mechanisms responsible for wide intra-and inter-specific variability in reproductive phenotypes. Despite compelling comparative morphological evidence of sexual diversity, detailed experimental work on reproductive behaviour and physiology in Macrostomum has so far been largely limited to just two species, M. lignano and M. hystrix, an obligate and a preferential outcrosser, respectively. In this study, we establish that a third species, M. pusillum, exhibits a combination of reproductive traits strikingly different from both of its congeners. Unlike M. lignano, we demonstrate that M. pusillum does not adjust sex allocation or the speed of spermatogenesis to the prevailing social group size. Macrostomum pusillum's relatively simple sperm morphology likely explains the short spermatogenesis duration we report, and is linked to a hypodermically inseminating mode of fertilization, which we show also means that these worms are capable of self-fertilization. Surprisingly, and unlike M. hystrix, selfing in isolated worms commences after only a short (if any) delay compared with the onset of reproduction in grouped individuals, with little evidence of differential inbreeding depression in 'isolated' progeny. These combined results suggest that, in nature, M. pusillum may be regularly selfing, in contrast to the congeners studied to date. Our findings highlight the rapid and correlated evolution of reproductive traits, and reinforce the utility of the genus Macrostomum for understanding the evolutionary and developmental mechanisms responsible for this diversity.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Self-fertilization, sex allocation and spermatogenesis kinetics in the hypodermically-inseminating flatworm Macrostomum pusillum

Giannakara

Ramm

2017

Journal of Experimental Biology

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“…Ramm () provides a nice overview of the sexual diversity of flatworms, which are morphologically extremely variable and inhabit a striking range of ecological niches. A large number of quite well‐studied genetic model organisms belong to this group of animals, ranging from the free‐living planarian and Macrostomum spp.…”

Section: Flatwormsmentioning

confidence: 99%

“…Currently, the available data often seem to rely on only a few laboratory strains, making these sexual strategies difficult to understand in an individual versus population sex allocation context. Ramm (2016) provides a nice overview of the sexual diversity of flatworms, which are morphologically extremely variable and inhabit a striking range of ecological niches. A large number of quite well-studied genetic model organisms belong to this group of animals, ranging from the freeliving planarian and Macrostomum spp.…”

Section: Cnidariansmentioning

confidence: 99%

The varied ways of being male and female

Schärer

2017

Molecular Reproduction Devel

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SUMMARYOur understanding of sexual reproduction is mainly informed by research on gonochorists (i.e., species with separate sexes), including insects, birds, and mammals. But the male and female sexes are not two types of individuals; they actually represent two different reproductive strategies, and in many organisms, these two strategies are distributed among individuals in a population in a variety of ways. For example, sequential hermaphrodites (or sex-changers) exhibit one strategy early in life and later switch to the other, while simultaneous hermaphrodites exhibit both strategies at the same time. There are also many intermediate sexual systems that mix gonochorists and hermaphrodites in the same species and within many organismal groups, shifts occur between these sexual systems. A fascinating collection of six articles in this special issue on Hermaphroditism & Sex Determination impressively documents some important challenges to our understanding of sex determination, and the specification of male and female reproductive function when these need to occur within the same individual rather than in two separate individuals. Moreover, hermaphroditism changes how we need to think about reproductive allocation to sexual functions, how such allocation can be specified, as well as how the sexual system affects sexual conflict and the resulting antagonistic coevolution. Our understanding of sexual reproduction will profit greatly from exploring the varied ways of being male and female.

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“…However, the high motivation to mate more, in general, also increases the risk of receiving (excess) sperm and/or seminal fluid, and concomitantly increases risks of polyspermy, sexually transmitted pathogens and/or receipt of manipulative SFPs (Charnov, 1979; Schärer et al , 2015). Thus, it is likely that adaptations to gain control over the received ejaculate evolve in many simultaneous hermaphrodites, such as the sperm digestion common in gastropods (Baur, 1998; Michiels, 1998; Greeff & Michiels, 2017) and counter-adaptations to take control over own ejaculate such as bypassing the normal way of transferring sperm by hypodermic insemination in flatworms (Schärer et al , 2011; Ramm et al , 2015b; Ramm, 2016).…”

Section: Introductionmentioning

confidence: 99%

Genotype-by-environment interactions for seminal fluid expression and sperm competitive ability

Patlar

Ramm

2019

Preprint

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Sperm competition commonly occurs whenever females mate multiply, leading to variation in male paternity success. This can be due to variation in the various traits that might affect sperm competitive ability, which itself depends on both genetic and environmental factors, as well as on genotype‐by‐environment interactions (GEI). Seminal fluid is a major component of the male ejaculate that is often expected to mediate sperm competition, where different genotypes can differ in their seminal fluid expression as a response to different levels of sperm competition (i.e. exhibit GEI). We therefore here focussed on testing for GEI in expression of two recently identified seminal fluid transcripts, suckless‐1 and suckless‐2, which potentially modulate sperm competitive ability in the simultaneously hermaphroditic flatworm Macrostomum lignano via their effects on manipulating post‐mating partner behaviour and ultimately the fate of transferred ejaculates. In addition, we sought to test for GEI in sperm competitive ability in a standardized sperm competition (P1 and P2) assay, to investigate the relationship between natural variation in the expression of these seminal fluid transcripts generated through GEI and relative paternity success. We found GEI for the expression level of suckless‐1 and suckless‐2, as well as for sperm competitive ability. Moreover, we found a positive relation between the expression of suckless‐1 and relative paternity success (P1). This suggests that natural variation in the expression of this seminal fluid transcript indeed can influence sperm competition outcomes in M. lignano.

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Exploring the sexual diversity of flatworms: Ecology, evolution, and the molecular biology of reproduction

Cited by 31 publications

References 102 publications

Self-fertilization, sex allocation and spermatogenesis kinetics in the hypodermically-inseminating flatworm Macrostomum pusillum

Self-fertilization, sex allocation and spermatogenesis kinetics in the hypodermically-inseminating flatworm Macrostomum pusillum

The varied ways of being male and female

Genotype-by-environment interactions for seminal fluid expression and sperm competitive ability

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