A baitbox for all seasons: temporal shifts in a vector’s propagule supply characteristics and implications for invasion ecology

Invasion dynamics are influenced by both vector operation and propagule pressure. Which propagules are entrained in a vector depends on how, where, and when a vector operates, but the timing and effects of vector operations on species delivery patterns is poorly resolved. Using the live marine baitworm trade, we tested vector selectivity across 3 boreal seasons (summer 2011, fall 2011, and spring 2012). We compared macroinvertebrate assemblages at the source (Maine, US east coast field) and in baitboxes upon delivery (Mid-Atlantic distributors, US east coast) and quantified live and dead biota to test for interactive effects of season and vector stage (i.e. source vs. destination) on per capita abundance, species richness, diversity, functional richness, and community composition. In all, we identified 46262 hitchhiking macro-organisms from 56 distinct taxa. Among live biota, taxonomic richness, functional group richness, and abundance differed by vector stage and season. Community composition showed seasonality for functional groups, but not for taxonomic groups. Vector stage affected dead community composition more than season, implying that vector operations (i.e. handling at source and during shipping) filter species transfers differentially. Dead communities were typically composed of the most abundant live organisms in the same baitboxes, emphasizing how important propagule pressure is to successful transport. Some combinations of 5 key functional traits (body size, feeding mode, growth form, modularity, and motility) were associated with increased survival during vector transfer. Successful species transfers are correlated with specific functional traits and propagule pressure, both of which are influenced by seasonal variation.

Assessing the effects of habitat patches ensuring propagule supply and different costs inclusion in marine spatial planning through multivariate analyses

Marine Protected Areas are considered key tools for conservation of coastal ecosystems. However, manyreserves are characterized by several problems mainly related to inadequate zonings that often do notprotect high biodiversity and propagule supply areas precluding, at the same time, economic importantzones for local interests. The Gulf of Naples is here employed as a study area to assess the effects ofinclusion of different conservation features and costs in reserve design process. In particular eight scenariosare developed using graph theory to identify propagule source patches and fishing and exploitationactivities as costs-in-use for local population. Scenarios elaborated by MARXAN, softwarecommonly used for marine conservation planning, are compared using multivariate analyses (MDS,PERMANOVA and PERMDISP) in order to assess input data having greatest effects on protected areasselection.MARXAN is heuristic software able to give a number of different correct results, all of them near to thebest solution. Its outputs show that the most important areas to be protected, in order to ensure longtermhabitat life and adequate propagule supply, are mainly located around the Gulf islands. In additionthrough statistical analyses it allowed us to prove that different choices on conservation featureslead to statistically different scenarios. The presence of propagule supply patches forces MARXAN toselect almost the same areas to protect decreasingly different MARXAN results and, thus, choices forreserves area selection.The multivariate analyses applied here to marine spatial planning proved to be very helpful allowing toidentify i) how different scenario input data affect MARXAN and ii) what features have to be taken intoaccount in study areas characterized by peculiar biological and economic interests.

Global distribution and climatic match of a highly traded ornamental freshwater fish, the sailfin molly Poecilia latipinna (Lesueur, 1821)

Predicting alien species' establishment through climate matching may inform management actions preventing future invasions. The aim of the current study was to evaluate the climate match of the sailfin molly (Poecilia latipinna) worldwide, with emphasis on Europe and the Mediterranean. A literature review indicated that the species presents a total of 100 non-indigenous occurrences in 29 countries worldwide. Predominantly, it has been introduced within tropical/subtropical climatic zones, where it is usually clustered near ornamental trade centers and malaria affected areas. Overall, sailfin molly distribution reflects a warm-stenothermic tolerance, however, there are validated populations outside the subtropical belt in geothermally heated water bodies. Its invasion potential, assessed by Climatch tool, indicated a low environmental match (5% of the assessed sites) within Europe, whereas in the Mediterranean this rose to 60%, though the species is recorded only at one location. This poor match of the model's output may reflect its inability to take into account local environmental filters. Intolerance to prolonged temperature drops appears to be the leading factor constraining sailfin molly establishment in Europe. Additional constrains on its successful invasion, i.e. specialized habitat requirements, limited propagule supply or reduced reproductive fitness, due to breeding manipulations of commercially available strains, are discussed.

Role of sources and temporal sinks in a marine amphipod

Spatially structured habitats challenge populations to have positive growth rates and species often rely on dispersing propagules to occupy habitats outside their fundamental niche. Most marine species show two main life stages, a dispersing stage and a sedentary stage affecting distribution and abundance patterns. An experimental study on Corophium acherusicum, a colonial tube-building amphipod, showed the strong influence that a source population can have on new habitats. More importantly, this study shows the effect of temporal sinks where newly established populations can show reduced growth rates if the propagule supply from a source is removed. Sink populations had a reduction in abundance and became male-biased as females left colonies. The consequences arising from short-term dispersal and temporal sinks could be due to different selection pressures at the source and sink populations. These consequences can become reflected in long-term dynamics of marine populations if we shift focus to non-random dispersal models incorporating behaviour and stage-dependent dispersal.

Higher-order bud production increases tillering capacity in the perennial caespitose grass Scribner’s Panicum (Dichanthelium oligosanthes)

The persistence and dynamics of perennial grass populations strongly depend on tiller recruitment from the bud bank. Because of the structural organization of grasses as populations of phytomers, bud production and tillering are constrained by morphology. An infrequent trait observed in only a few caespitose grasses is the branching of buds to produce higher-order buds prior to tiller development. We studied bud bank dynamics in Dichanthelium oligosanthes (Schult.) Gould a C3 perennial caespitose grass widely distributed in the eastern Great Plains. A hierarchy of bud development occurred in D. oligosanthes, with primary buds branching to produce secondary, tertiary, and quaternary buds. This higher-order bud production increased the overwintering propagule supply for spring recruitment by 4.5 times, and more than half of successful tiller recruits originated as higher-order buds. The temporal patterns of higher-order bud production and development suggest that growing season length may be an important factor determining the extent of higher-order bud production and subsequent year tiller natality in D. oligosanthes. Higher-order bud production likely has important consequences for the population dynamics of grasses. It may increase bud bank densities and tillering capacity, buffer population dynamics, and increase intraclonal tiller densities and resource consolidation in caespitose grasses.