Review of the biogeography of the genus Artemia (Crustacea, Anostraca)

In this study, we report on the known Artemia habitats worldwide. Recent literature information is incorporated about the taxonomic status of the various populations studied. The genus is composed of di-, tri-, tetra- and pentaploid parthenogenetic populations and of the following bisexual species: A. franciscana franciscana , A. franciscana monica , A. franciscana sp., A. persimilis , A. salina , A. urmiana , A. sinica and A. sp. from Kazakhstan. The problems of characterizing new brine shrimp populations are discussed. In view of the great importance of Artemia as part of the live food chain for the culture of fish and shellfish larvae and the present cyst shortage from the market, the need for commercial exploitation and development of new Artemia sources is now, more than ever, necessary.     

Evolutionary assessment of Artemia tibetiana (Crustacea, Anostraca) based on morphometry and 16S rRNA RFLP analysis

Over the last few years, molecular-based assays in the genus Artemia have considerably enriched prior systematic assessments based on morphometry. For the first time, morphometric and 16S rRNA PCR-RFLP analyses on all type-locality bisexual species of the genus have been employed here. Emphasis was put on the Asian species ( Artemia urmiana , A. tibetiana , A. sinica ) where patterns of divergence and reproductive isolation are rather discrete, and especially on A. tibetiana for which recent reports have questioned its specific status. Discriminant analysis of morphometric characters has shown significant differentiation among species. Classification scores were 99.4 and 100% for males and females, respectively. Mitochondrial DNA RFLP patterns have given indications for lower, albeit similar patterns of differentiation compared with those obtained by morphometry. Artemia tibetiana and A. urmiana are mitochondrially indistinguishable which is suggestive of recent ancestry. Our data, in conjunction with past evidence, are supportive of a significant amount of divergence between A. tibetiana and A. sinica . Morphometric and molecular assays can be reciprocally informative provided theory and patterns of speciation are incorporated into systematic assessments.     

Genetic,ecological, and behavioural divergence between two sibling snapping shrimp species (Crustacea: Decapoda: Alpheus)

Examination of genetic and ecological relationships within sibling species complexes can provide insights into species diversity and speciation processes. Alpheus angulatus and A. armillatus, two snapping shrimp species with overlapping ranges in the north-western Atlantic, are similar in morphology, exploit similar ecological niches and appear to represent recently diverged sibling species. We examined phylogenetic and ecological relationships between these two species with: (i) sequence data from two mitochondrial genes (16S rRNA and COI); (ii) data on potential differences in microhabitat distribution for A. armillatus and A. angulatus; and (iii) data from laboratory experiments on the level of reproductive isolation between the two species. DNA sequence data suggest A. armillatus and A. angulatus are sister species that diverged subsequent to the close of the Isthmus of Panama, and that haplotype diversity is lower in A. armillatus than in A. angulatus. Both species are distantly related to A. heterochaelis and A. estuariensis, two species with which A. angulatus shares some similarities in coloration. Ecological data on the distribution of A. angulatus and A. armillatus from two locations revealed differences in distribution of the two species between habitat patches, with each patch dominated by one or the other species. However, there was no apparent difference in distribution of the two species within habitat patches with respect to microhabitat location. Ecological data also revealed that heterospecific individuals often occur in close proximity (i.e. within metres or centimetres) where sympatric. Behavioural data indicated that these species are reproductively isolated, which is consistent with speciation in transient allopatry followed by post-divergence secondary contact. Our data further resolve taxonomic confusion between the sibling species, A. armillatus and A. angulatus, and suggest that sympatry in areas of range overlap and exploitation of similar ecological niches by these two recently diverged species have selected for high levels of behavioural incompatibility.     

Red kite (Milvus milvus) and black kite (M. migrans): minute genetic interspecies distance of two raptors breeding in a mixed community (Falconiformes: Accipitridae)

Allozyme analysis of 24 loci in 154 red kites (Milvus milvus) and 36 black kites (Milvus migrans) from die Hakel forest (Sachsen-Anhalt, Germany) revealed a Nei's interspecies genetic distance of D = 0.009. Of die observed genetic variance of four polymorphic enzymes, 15.4% referred to die differentiation between die kite species, but 84.6% were contributed by the ingroup polymorphism widiin diese species. Allozymes permit the identification of some 78% of samples as orignating from M. milvus , but only of 5.4% of samples obtained from M. migrans. Akhough the genetic distance is slight, die Milvus kites are valid biospecies which, despite occasional instances of hybridization, coexist sympatrically and may breed in mixed breeding aggregations. Mate choice in die largely separate winter quarters of diese migratory birds or chromosomal incompatibility are hypodietical isolation mechanisms stabilizing die species boundary. Moreover, the range sympatry could have developed fairly recendy widi die spread of human agriculture.     

r/K‐like trade‐off and voltinism discreteness: The implication to allochronic speciation in the fall webworm,Hyphantria cunea complex (Arctiidae)

North America has distinct types of Hyphantria moths (Arctiidae) characterized by red (RD)‐ and black (BL)‐headed larvae, of which the taxonomic status is unresolved. Genetic divergence of 26 populations, based on 710 bp of the mtCOI sequence, showed two phylogenetic lineages, which could not be connected in the haplotype network with 95% confidence. The two lineages are separated by 3.1% sequence divergence and should be considered for full species status. The estimated split occurred 1.2–1.6 million years ago. The range of the RD type covered most of the continent, whereas that of the BL type was limited to eastern deciduous forests. Several biological characteristics were differentiated in the zone of cohabitation where BL had more annual generations than RD. Spring emergence of BL precedes that of RD in the field by at least 1 month, because the diapause in BL was shallow, whereas it was deep in RD. Voltinism requires discreteness of numbers, which functions as a sink of hybrids between the two parental lines that have distinct but equally adaptive reproductive strategies; BL may be more r‐strategist‐like and RD more K‐strategist‐like, because fast‐developing BL has multivoltine life cycle, investing less silk proteins as the round‐the‐clock feeder, and slow‐developing RD univoltine one investing more silk as the nocturnal feeder. Also, intensity of diapause, deep in RD and weak in BL, was grossly different, which may enforce segregation of spring adults. Allochronic speciation avoiding coincidental occurrence of adult stages is therefore the most likely scenario. Because the adults never meet in nature, large morphological differentiation is not required.     

Genetic variation and evolutionary origins of parthenogenetic Artemia (Crustacea: Anostraca) with different ploidies

Using two nuclear (ITS1 and Na⁺/K⁺ ATPase) and three mitochondrial (COI, 16S and 12S) markers, we determined the genetic variation and evolutionary relationship of parthenogenetic and bisexual Artemia. Our analyses revealed that mitochondrial genes had higher genetic variation than nuclear genes and that the 16S showed more variety than the other mitochondrial genes in parthenogenetic populations. Triploid parthenogens showed lower genetic variation than diploid ones, whereas the tetra‐ and pentaploids had greater genetic distance than diploid parthenogens. No shared haplotype was found between individuals of parthenogenetic populations and Asian bisexual species with the exception of Na⁺/K⁺ ATPase (Artemia tibetiana). Only mitochondrial markers can demonstrate phylogenetic relationships, and showed that the parthenogenetic Artemia is a polyphyletic group in which the diploid lineages share a common ancestor with Artemia urmiana while tetraploids are closely related to Artemia sinica. The triploid and pentaploid linages are likely to be directly derived from diploid and tetraploid parthenogens, respectively. Subsequently, west Asia is origin for di‐/triploids, and tetra‐/pentaploids rose from East Asia.     

Causes of a non-random pairing by size in the brine shrimp,Artemia salina: (Crustacea: Anostraca)

Summary Brine shrimp (Artemia salina) males and females entered precopula assortatively by size in the laboratory; large males also had a pairing advantage over smaller males. We investigated the causes of such nonrandom pairing to test hypotheses on size-assortative mating.We found precopulatory biases with respect to male size in the absence of direct competition among males (which produces pairing biases in other species). Large males encountered females significantly more often than did small males. Similarly, large females encountered males more often than did small females, but showed less willingness than small females to enter precopula when housed with small males. Consequently, large females took longer than small females to enter precopula with small males. Although large males entered precopula readily with small females, such size-mismatched pairs appeared short-lived.We conclude that non-random pairing by size in A. salina is determined by several factors including: encounter rates between males and females of different sizes, female behavior, and time following initial pair formation. Our results are likely applicable to other species and can help explain variation for selection on size or other traits.     

A Possible Extra-Ovarian Site for Synthesis of Lipovitellin During Vitellogenesis in Artemia sp. (Crustacea; Anostraca)

Summary

Lipovitellin samples, extracted from yolk platelets of cysts, were applied to SDS-PAGE. A female specific antiserum was raised against the high molecular weight apoprotein lipovitellin alpha-1 (LV-α1) of the lipovitellin complex. This anti-LV-α1 was used in the peroxidase-anti-peroxidase staining method with frontal paraffin sections (of 4μm) of whole embedded Artemia. Females were studied during a complete vitellogenic cycle. The presence of exogenous yolk precursors in the fat storage cells of the thoracopods of female Artemia was demonstrated. The amount of the female specific yolk polypeptides and the number of positively stained cells changes during the vitellogenic cycle. In vitro experiments with ³⁵S-radiolabelled methionine show the synthesis of lipovitellin-like substances in the fat storage cells of vitellogenic females.     

Geographical distribution and evolutionary divergence times of Asian populations of the brine shrimp Artemia (Crustacea,Anostraca)

The brine shrimp Artemia represents a widespread genus of microcrustaceans adapted to hypersaline environments. The species of this genus have been the subject of numerous phylogenetic studies, but many open questions remain, especially for Eurasian Artemia lineages. Artemia sinica Cai, 1989 and Artemia tibetiana have a restricted geographical distribution, whereas the Eurasian haplotype complex (EHC) and especially Artemia urmiana Günther, 1899 show wider ranges. We examined the geographic distribution, evolutionary age, and historical demography of the Asian Artemia lineages (A. urmiana, A. sinica, A. tibetiana, and the Eurasian haplotype complex) using samples from 39 geographical localities and based on the nucleotide sequences of the mitochondrial cytochrome c oxidase subunit I (COI) gene. Asian Artemia taxa clusters into four distinctive clades with high nodal support, consisting of 69 unique haplotypes. A star‐like haplotype pattern was visible in EHC lineages (comprising pathenogenetic populations), which were genetically close to two sexual species, A. urmiana and A. tibetiana. The Bayesian approach of molecular clock estimation indicated that A. sinica had already diverged in the late Miocene (19.99 Mya), whereas A. urmiana, A. tibetiana, and EHC shared a common ancestor in the late Pliocene (5.41 Mya). Neutrality tests indicated a recent population expansion in A. urmiana and EHC lineages. The diversification within A. urmiana and EHC lineages occurred in the Pleistocene (1.72 Mya) and Holocene (0.84 Mya), respectively. Overall, these results suggest a much longer evolutionary history of A. sinica and the possible evolutionary origin of EHC lineages from Asian sexual ancestors. Our findings point to the importance of species structure and divergence time variations of Asian Artemia, highlighting interspecific diversification and range expansion of local species in Asia. © 2015 The Linnean Society of London     

Morphometric and Preliminary Genetic Characteristics of Artemia Populations from Iran

Six Artemia populations, one bisexual and five parthenogenetic, from different parts of Iran were compared using morphometric and genetic characteristics. The discriminant analysis based on 19 morphometric variables showed that there are significant differences between the studied populations based on their morphological characteristics, where 85.9% of original grouped cases were correctly classified. The bisexual Artemia urmiana however exhibited a 100% separation from the parthenogenetic populations. However, a 1500 bp mitochondrial rDNA fragment showed similar RFLP patterns for all Iranian populations confirming earlier reports of a close genetic relationship between A. urmiana and parthenogenetic Artemia. (© 2009 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

The evolution of intrinsic reproductive isolation in the genus Cakile (Brassicaceae)

In theory, adaptive divergence can increase intrinsic post‐zygotic reproductive isolation (RI), either directly via selection on loci associated with RI, or indirectly via linkage of incompatibility loci with loci under selection. To test this hypothesis, we measured RI at five intrinsic post‐zygotic reproductive barriers between 18 taxa from the genera Cakile and Erucaria (Brassicaceae). Using a comparative framework, we tested whether the magnitude of RI was associated with genetic distance, geographic distance, ecological divergence and parental mating system. Early stages of post‐zygotic RI related to F₁ viability (i.e. initial seed set) tended to be stronger than later stages related to F₁ fecundity (i.e. flower number, fruit number). Mating system significantly influenced early stages of RI, such that RI was lowest when the mother was selfing and father was outcrossing, consistent with an imbalance between sink strength and resistance to provisioning. We found little evidence that adaptive divergence accelerates the evolution of intrinsic post‐zygotic RI, consistent with a nonecological model of evolution that predicts the nonlinear accumulation of RI and RI asymmetry with time (i.e. genetic distance), irrespective of adaptive divergence. Thus, although certain aspects of ecological divergence do not appear to have contributed strongly to the evolution of RI in this system, divergence in mating system actually reduced RI, suggesting that mating system evolution may play a significant role in speciation dynamics.     

Characterization of polymorphic microsatellite markers in the brine shrimp Artemia (Branchiopoda, Anostraca)

The brine shrimp Artemia is a complex genus containing sexual species and parthenogenetic lineages. Artemia franciscana is native to America and its cysts (diapausing eggs) are used worldwide as a food source in aquaculture. As a consequence, this anostracan has become an invasive species in many hypersaline aquatic ecosystems of other continents. Parthenogenetic Artemia lineages occur only in the Old World. Ten and five microsatellite markers were developed to characterize two populations for A. franciscana and two populations for diploid parthenogenetic Artemia, respectively. For A. franciscana the number of alleles ranged from 11 to 58 per locus, while for parthenogens the number of alleles ranged from three to 10. The levels of heterozygosity in A. franciscana and in parthenogens ranged from 0.115 to 0.976 and from 0.000 to 0.971, respectively. These microsatellite loci showed a high population assignment power, which will be useful for future studies of population genetics and invasive processes in Artemia.     

Genetic Divergence and Phylogenetic Relationships in Grey Mullets (Teleostei: Mugilidae) Using Allozyme Data

Genetic divergence and phylogenetic relationships among five species of the Mugilidae family (Liza saliens, Liza aurata, Liza ramada, Chelon labrosus, and Mugil cephalus) were investigated, in the present study, on samples taken from Messolongi lagoon in Greece, using allozyme electrophoresis. Ten enzymic systems corresponding to 22 genetic loci were assayed, among which, four were found to be polymorphic in Liza saliens, Liza aurata, and Chelon labrosus, seven in Liza ramada, while only two were polymorphic in Mugil cephalus. Several loci showed different electrophoretic patterns among the species and thus, they can be useful in species taxonomy as diagnostic markers, as well as for further evolutionary studies. It must be underlined that among them the aGPD-2* locus proved to be species-specific, while the other ones can be also used in various combinations for the same purpose. The observed heterozygosity was found to range from 0.020 to 0.051. Allele frequencies of all loci were used to estimate Nei's (1972) genetic distance, which was found to range between 0.249 and 1.171 among the five species studied. UPGMA and NJ trees, obtained by genetic distance matrix methods, as well as, a tree based on the discrete character parsimony analysis were found to exhibit the same topology. Our result show that the three species of the genus Liza are clustered together, Chelon labrosus being closer to the previous clade, while Mugil cephalus being more distinct.     

Genetic and phylogenetic consequences of island biogeography

Abstract.— Island biogeography theory predicts that the number of species on an island should increase with island size and decrease with island distance to the mainland. These predictions are generally well supported in comparative and experimental studies. These ecological, equilibrium predictions arise as a result of colonization and extinction processes. Because colonization and extinction are also important processes in evolution, we develop methods to test evolutionary predictions of island biogeography. We derive a population genetic model of island biogeography that incorporates island colonization, migration of individuals from the mainland, and extinction of island populations. The model provides a means of estimating the rates of migration and extinction from population genetic data. This model predicts that within an island population the distribution of genetic divergences with respect to the mainland source population should be bimodal, with much of the divergence dating to the colonization event. Across islands, this model predicts that populations on large islands should be on average more genetically divergent from mainland source populations than those on small islands. Likewise, populations on distant islands should be more divergent than those on close islands. Published observations of a larger proportion of endemic species on large and distant islands support these predictions.     

Ultrastructural Study of Endoreticulatus durforti N. Sp., a New Microsporidian Parasite of the Intestinal Epithelium of Artemia (Crustacea, Anostraca)

ABSTRACT. A new microsporidian parasite of the Artemia intestinal epithelium has been studied. The microsporidium developed within a membranous parasitophorous vesicle from the host rough endoplasmic reticulum consisting of two membranes, with the proximal one usually lacking ribosomes.
All developmental stages had isolated nuclei. Unikaryotic meronts developed into merogonial plasmodia. Merogonial division occurred by binary fission and rosette-shaped fragmentation. In young sporonts, an electron-lucent space, corresponding to the developing endospore, was immediately observed between both the plasmalemma and the exospore primordium. Sporogonial division occurred also by rosette-shaped fragmentation, resulting in at least eight sporoblasts that developed directly into spores. Fresh spores were 1.7 × 0.9 μm in size and oval-shaped. The 8–11 coil isofilar polar filament was arranged in two rows. The polaroplast was bipartite. The nature of the parasitophorous envelope, host-parasite interaction, developmental cycle and taxonomy are discussed.     

Ontogeny of low molecular weight stress protein p26 during early development of the brine shrimp, Artemia franciscana

Embryogenesis in the brine shrimp, Artemia sp., occurs by one of two pathways: (i) the direct, uninterrupted development of nauplius larvae within the female or (ii) the production of embryos that arrest development at the gastrula stage and enter diapause. Diapause embryos are released from females into the aqueous environment where they remain in diapause until activated by appropriate environmental cues and resume development. These encysted embryos possess at least one low molecular weight stress protein, which we refer to as p26 and which has been implicated previously in the stress response of activated embryos. We investigated the appearance of p26 in developing diapause embryos in utero and looked for its presence in embryos developing directly into nauplii. We found p26 to be specific to diapause-destined embryos; it was not detected in direct-developing embryos. We conclude that p26 is not required for the basic developmental program that produces the nauplius. In diapause-destined embryos, p26 was first detectable after 3 days of development, at which time the embryos were late gastrulae. This protein continues to increase in amount until the encysted embryos are released, approximately 5 days after fertilization. At the time of release almost all p26 is located in the low speed supernatant fraction, but as released embryos continue diapause, p26 transfers to the pelleted nuclear fraction in increasing amounts. Our working hypothesis views p26 as a molecular chaperone preventing protein denaturation and aggregation under conditions associated with metabolic arrest and other stressful states, which these encysted embryos encounter.     

Life history affects the evolution of reproductive isolation among species of Coreopsis (Asteraceae)

The evolution of reproductive isolation within Coreopsis is investigated by integrating phylogenetic data with estimates of pollen viability of plants from inter- and intraspecific crosses. Three different models that predict F1 fitness are compared. The first uses ITS pairwise distances, the second is based on phylogenetic branch lengths derived from DNA sequences, and the third elaborates on the second model by dividing branch length according to reconstructions of the evolution of life history. This is the first study to use phylogenetic branch-length estimates for predicting levels of reproductive isolation. Estimated branch lengths (model 2) predict hybrid fitness more accurately than simply genetic distance (model 1) but only very slightly. This is probably because the two variables are strongly correlated in Coreopsis. Prediction is substantially improved by allowing evolutionary rates to differ between annual and perennial branches (model 3). A bootstrapping procedure indicates that the life-history effect is statistically significant. The more rapid evolution of reproductive isolation within annual species of Coreopsis may be due to differing mechanisms of reproductive isolation, that is, chromosomal rearrangements rather than genetic incompatibilities.     

Genetic and morphological differentiation in Tephritis bardanae (Diptera: Tephritidae): evidence for host-race formation

The fruit fly Tephritis bardanae infests flower heads of two burdock hosts, Arctium tomentosum and A. minus. Observations suggest host-associated mating and behavioural differences at oviposition indicating host-race status. Previously, flies from each host plant were found to differ slightly in allozyme allele frequencies, but these differences could as well be explained by geographical separation of host plants. In the present study, we explicitly test whether genetic and morphological variance among T. bardanae are explained best by host-plant association or by geographical location, and if this pattern is stable over a 10-year period. Populations of A. tomentosum flies differed significantly from those of A. minus flies in (i) allozyme allele frequencies at the loci Pep-A and Pgd, (ii) mtDNA haplotype frequencies and (iii) wing size. In contrast, geographical location had no significant influence on the variance estimates. While it remains uncertain whether morphometric differentiation reflects genotypic variability or phenotypic plasticity, allozyme and mtDNA differentiation is genetically determined. This provides strong evidence for host-race formation in T. bardanae. However, the levels of differentiation are relatively low indicating that the system is in an early stage of divergence. This might be due to a lack of time (i.e. the host shift occurred recently) or due to relatively high gene flow preventing much differentiation at loci not experiencing selection.     

Environmental factors associated with genetic and phenotypic divergence among sympatric populations of Arctic charr (Salvelinus alpinus)

The mechanisms by which phenotypic and genetic divergence may occur among sympatric, conspecific populations have been widely discussed but are still not well understood. Possible mechanisms include assortative mating based on morphology or variation in the reproductive behaviour of phenotypes, and both have been suggested to be relevant to the differentiation of salmonid populations in post-glacial lakes. Here, we studied Arctic charr (Salvelinus alpinus) in Windermere, where putative populations are defined by spatial and temporal variation in spawning. Genetic differentiation was assessed based on nine microsatellite loci, and phenotypic variation was assessed from morphometric characters. We test hypotheses about the relative role of morphology, spawning season and spawning habitat in the evolution of genetic divergence among these populations. Distinct from other lake systems, we find that both morphological and genetic differentiation are restricted primarily to one of two interconnecting basins, that genetic and morphological differentiation are decoupled in this lake and that both phenotype and environment have changed over the last 20 years. The implication is that breeding habitat plays a primary role in isolating populations that differentiate by drift and that phenotypically plastic changes, potentially related to foraging specializations, have either become secondarily decoupled from the genetically defined populations or were never fundamental in driving the evolution of genetic diversity in the Windermere system.     

Infection of Artemia salina by Haliphthoros milfordensis: A scanning and transmission electron microscope study

The fungus Haliphthoros milfordensis is a known pathogen of cultured lobster (W. S. Fisher, E. H. Nilson, and R. S. Schleser, 1975, J. Invertebr. Pathol., 26, 41–45) and has been isolated also from gills of the white shrimp (T. P. Tharp and C. E. Bland, 1977, Canad. J. Bot.55, 2936–2944). Because of the potential impact of this fungus on culture of commercially important marine crustacea, a model laboratory system involving Artemia salina has been devised to study aspects of its biology. This report describes light and electron microscope observations of the infection process and the internal relationship between host and parasite. Following encystment of zoospores on the exoskeleton of larvae, infection occurs via germination of the spore and penetration of the exoskeleton and epidermis by vegetative hyphae. Growth of the fungus destroys first fat and body muscles and ultimately the gut. Electron-dense material at the host-parasite interface is likely a response of the shrimp to invading fungal hyphae. Histolytic activity by the fungus is evident by the dissolution of host cytoplasm along the growing hyphal tips. Following utilization of all host tissues, hyphae grow to the exterior and the process of sporulation is initiated.