Molecular and Morphological Evolution of the Amphipod Radiation of Lake Baikal

Macdonald, Kenneth S., Yampolsky, Lev, Duffy, J. Emmett

01 January 2005

Lake Baikal, in Siberia, Russia, contains the highest biodiversity of any extant lake, including an impressive radiation of gammaroidean amphipods that are often cited as a classic case of adaptive radiation. However, relationships among Baikal's amphipods remain poorly understood. The phylogenetic history of 32 Lake Baikal amphipod species, representing most major lineages of the endemic fauna, was examined using three genes (COI, 16S rRNA, and 18S rRNA), and 152 morphological characters. Results support monophyly of the largest and most diverse of the Baikalian families, the Acanthogammaridae. Analyses suggest that a second Baikalian family, the fossorial Micruropodidae, is paraphyletic and composed of two divergent clades, one of which includes Macrohectopus branickii, a morphologically specialized pelagic planktivore traditionally assigned its own family. The extreme morphological and ecological divergence of Macrohectopus from its close genetic relatives, and conversely, the large genetic distances among other morphologically similar micruropodids, suggest that morphological and molecular evolution have often been uncoupled during the radiation of Baikal's amphipods. This study suggests that the amphipod fauna of Lake Baikal is polyphyletic; originating from two independent invasions of the lake.

16S rRNA

18S rRNA

amphipoda

COI

gammaroidea

Lake Baikal

morphology

Biological Sciences

Gammaridean amphipods from Tomales Bay, California

Gray, Walter Scott

01 January 1969

The purpose of this study is to describe the sediment-dwelling, infaunal gammaridean amphipods of Tomales Bay and to relate their distribution to known variations in the physical environment. Also, the Tomales Bay amphipod fauna is compared to the faunas of other West Coast bays.

Amphipoda California Tomales Bay

Gammaridae California Tomales Bay

Biology

Life Sciences

Inter-individual variability and phenotypic plasticity : the effect of the environment on the biogeography, population structure, ecophysiology and reproduction of the sandhoppers Talorchestia capensis and Africorchestia quadrispinosa

Baldanzi, Simone

January 2014

Climatic envelope models focus on the climatic variables affecting species or species assemblages, and are important tools to investigate the effect of climate change on their geographical ranges. These models have largely been proposed in order to make successful predictions on species‘ persistence, determining which variables are likely to induce range expansion, contraction, or shifting. More recent models, including the ability and the cost for individuals to respond promptly to an environmental stimulus, have revealed that species may express phenotypic plasticity able to induce adaptation to the new environment. Consequently, understanding how species evolve to a changing climate is fundamental. From this perspective, investigating intraspecific responses to an environmental variable may contribute to better understanding and prediction of the effect of climate change on the geographical range and evolution of species, particularly in the case of widespread species. In this context, the present study aimed at establishing how environmental variables (focussing mainly on temperature) may have contributed to shape the spatial distribution, physiology, reproductive biology and connectivity of two species of Southern African sandhoppers (Talorchestia capensis and Africorchestia quadrispinosa, Amphipoda, Talitridae). Most of the work was carried out on T. capensis, due to its widespread spatial distribution. A first investigation of the biogeography of T. capensis and A. quadrispinosa, revealed that, for both species, spatial patterns of abundance, size and sex ratio were not explained by the Abundant Centre Hypothesis (greater abundance at the core of a spatial range), but rather guided by bio-physical forces. Precisely, the abundance of sandhoppers was driven by the morphodynamic state of the beach, salinity and temperatures, with strong differentiation among sites that reflected local environmental conditions. In support of these findings, strong population structure in the genetics of T. capensis was found (three main groups) when investigating its phylogeography and genetic connectivity. Although such defined structure may suggests cryptic speciation, the concomitant within-population variation in the COX1 region of mtDNA, also highlighted the importance of individual genetic variability. High individual variability was also found in the response of T. capensis to temperature, both in its physiology (thermal plasticity) and its reproductive biology (maternal effects). Since temperature is one of the main variables affecting the coastal marine systems of southern Africa and the metabolism of animals in general, its effect on the physiology and reproduction of T. capensis was therefore investigated. Thermal responses to increasing/decreasing temperatures were assessed for separated populations of T. capensis. Individual variability was reported in the oxygen consumption of T. capensis in response to temperature (high variation around the means, especially for increasing temperatures). Among population differences in thermal sensitivity were significantly correlated with air temperature variability experienced over the past 23 years, highlighting the importance of historical temperature fluctuations to the current thermal physiology of these sandhoppers. Temperature also had an important effect on the reproductive plasticity of T. capensis. Different temperatures induced mothers to adjust the size of their offspring (i.e. egg size), with larger eggs produced at lower temperatures. Interestingly, females showed strongly significant among individual variation in the size of the eggs. Given the importance of understanding rapid responses of organisms to climate change and considering the fundamental role played by phenotypic plasticity in evolution, the overall study revealed the significance of individual plasticity and variability in response to the environment and highlighted its importance. Particularly, studying the thermal physiology of separated populations and understanding within population reproductive plasticity in response to temperature, helped to clarify how differences among individual responses have important consequences at the population level, possibly explaining the widespread distribution of T. capensis.

Marine biology -- Africa, Southern

Adaptation (Biology) -- Africa, Southern

Evaluation of Silver Nanoparticle Acute and Chronic Effects on Freshwater Amphipod (Hyalella Azteca)

Kusi, Joseph, Maier, Kurt J.

01 January 2022

Silver nanoparticles (AgNPs) are known to cause ecotoxic effects, but there are no existing derived ambient water quality criteria (AWQC) for these nanomaterials to protect freshwater aquatic life due to insufficient toxicological data. We exposed Hyalella azteca to silver nitrate, citrate-coated AgNPs (citrate-AgNPs), and polyvinylpyrrolidone-coated AgNPs (PVP-AgNPs) in a 10-day and 28-day water-only static renewal system with clean sand as a substrate for the amphipods and compared their point estimates with the United States Environmental Protection Agency (USEPA) AWQC for silver. We observed that all treatments decreased the survival, growth, and biomass of H. azteca, and the order of toxicity was AgNO > citrate-AgNPs > PVP-AgNPs. The LC50s of AgNO, citrate-AgNPs, and PVP-AgNPs were 3.0, 9.6, and 296.0 µg total Ag L, respectively, for the acute exposure and 2.4, 3.2, and 61.4 µg total Ag L, respectively, for the chronic exposure. Acute and chronic EC20s of citrate-AgNPs ranged from 0.5 to 3.5 µg total Ag L while that of PVP-AgNPs ranged from 31.2 to 175 µg total Ag L for growth and biomass. Both Ag released from AgNPs and the nanoparticles contributed to the observed toxicity. The dissolution and toxicity of AgNPs were influenced by surface coating agents, particle size, and surface charge. Most point estimates for AgNPs were above AWQC for silver (4.1 µg L) and the lowest concentration (0.12 µg/L) at which Ag is expected to cause chronic adverse effects to freshwater aquatic life. Our study demonstrates that the current AWQC for silver, in general, is protective of freshwater aquatic life against AgNPs tested in the present study.

amphipod

hyalella azteca

point estimates

silver nanoparticles

toxicity

water quality criteria

fresh water

amphipoda

animals

fresh water

metal nanoparticles (toxicity)

silver (toxicity)

water pollutants

chemical (toxicity)

Environmental Health

Molecular Studies on Head Development of the Amphipod Crustacean Parhyale hawaiensis / Molekulare Untersuchungen zur Kopfentwicklung des amphipoden Krustazeen Parhyale hawaiensis

Schmid, Bernhard

05 July 2011

No description available.

570 Biowissenschaften, Biologie

Biology (incl. Psychology)

42.00 Biologie

WA.000 Biologie

Förekomst av mikroplaster i tångmärlor (Gammaridae) längs södra Hallandskusten

Karlsson, Joakim

January 2020

Since the middle of the 20th century, scientists have observed that marine organisms ingest plastics in various shapes, directly or through food. Plastics smaller than 5 millimetres, called microplastics, have in recent years gained more attention and been found to accumulate environmental toxins. A family of organisms which have been found to ingest microplastics is Gammaridae, which are important as food sources and detritivores in many ecosystems. In this study, the occurrence of microplastics in marine gammarids was investigated in three rural and three urban areas, along the coast of Halland and northern Skåne. The aim was to find out if these organisms contain microplastics and to compare the occurrence in rural versus urban areas. Microplastics were found in 33 (approx. 14.9 %) of 221 samples, ranging from 0 to 3 microplastics per individual. A significant difference in the average amount of microplastics per individual was found between the rural and urban areas; the urban areas had a higher average, with one exception. In other studies, urban areas have been found to often contain more microplastics than rural areas, increasing the possibility that organisms in these areas ingest plastics. With more boat traffic and inhabitants in general, along with streams transferring plastics from inland areas, the amount of emissions in urban areas can be greater than in rural parts. The result shows that microplastics occur in marine gammarids in the 3 examined areas and that these organisms therefore may have an important part in the transfer of microplastics between trophic levels. / Sedan mitten av 1900-talet har forskare observerat att marina organismer tar in plaster i olika former, direkt eller via föda. Plastpartiklar mindre än 5 millimeter, så kallade mikroplaster, har på senare år fått större uppmärksamhet och har också visat sig kunna ackumulera miljögifter. En familj av organismer som man funnit mikroplaster i är tångmärlor (Gammaridae), vilka i många ekosystem är viktiga som födokällor och nedbrytare. I denna studie undersöktes förekomsten av mikroplaster i marina tångmärlor på tre lokaler i stadsområden respektive landsbygdsområden, längs Hallandskusten och Skånes norra kust. Syftet var att se ifall dessa organismer innehåller mikroplaster samt jämföra förekomsten i landsbygdsområden kontra stadsområden. Av 221 analyserade prov förekom mikroplaster i 33 (ca 14,9 %) och förekomsten per individ varierade från 0 till 3 mikroplaster. En signifikant skillnad i medelvärde av mikroplaster per individ fanns mellan landsbygdsområden och urbana områden; urbana områden innehöll i genomsnitt mer men med ett undantag. I andra studier har man funnit belägg för att stadsområden ofta innehåller mer mikroplaster än landsbygdsområden, något som ökar risken för att organismer i dessa områden tar in plaster. Med mer båttrafik och antal invånare överlag, tillsammans med vattendrag som för med sig plast från inlandet, kan det i dessa områden ge en större utsläppsmängd i jämförelse med i landsbygdsområden. Resultatet visar på att mikroplaster förekommer i marina tångmärlor i de undersökta områdena och att dessa organismer därmed kan vara en viktig del i överföringen av mikroplaster mellan trofiska nivåer.

plastic

plastics

microplastics

microplastic

Amphipoda

gammarid

gammarids

Gammaridae

Gammarus

Halland

Skåne

rural

urban

biology

aquatic biology

Falkenberg

Ugglarp

Halmstad

Laxvik

Båstad

Kattvik

Sweden

trophic transfer

plast

plaster

mikroplaster

mikroplast

tångmärlor

tångmärla

Gammaridae

Gammarus

gammarid

gammarider

märlkräfta

märlkräftor

Amphipoda

Halland

Skåne

landsbygd

stad

biologi

akvatisk biologi

Falkenberg

Ugglarp

Halmstad

Laxvik

Båstad

Kattvik

Sverige

trofisk överföring

Biological Sciences

Biologiska vetenskaper

Other Biological Topics

Annan biologi