A new cardiid bivalve from the Pliocene Baklan Basin (Turkey) and the origin of modern Ponto‐Caspian taxa

Abstract: We present the first record of the cardiid genus Monodacna from the Pliocene of Anatolia, Turkey. Monodacna imrei sp. nov. was found in the Pliocene Killik Formation from the western margin of the Baklan Basin, in very marginal brackish to freshwater lacustrine deposits. The new record extends the stratigraphic range of the modern Ponto‐Caspian genus back into the Pliocene and adds to earlier evidence that modern Ponto‐Caspian taxa originated in the Pliocene of south‐western Turkey.     

Climatic niche and neutral genetic diversity of the six Iberian pine species: a retrospective and prospective view

Quaternary climatic fluctuations have left contrasting historical footprints on the neutral genetic diversity patterns of existing populations of different tree species. We should expect the demography, and consequently the neutral genetic structure, of taxa less tolerant to particular climatic extremes to be more sensitive to long‐term climate fluctuations. We explore this hypothesis here by sampling all six pine species found in the Iberian Peninsula (2464 individuals, 105 populations), using a common set of chloroplast microsatellite markers, and by looking at the association between neutral genetic diversity and species‐specific climatic requirements. We found large variation in neutral genetic diversity and structure among Iberian pines, with cold‐enduring mountain species (Pinus uncinata, P. sylvestris and P. nigra) showing substantially greater diversity than thermophilous taxa (P. pinea and P. halepensis). Within species, we observed a significant positive correlation between population genetic diversity and summer precipitation for some of the mountain pines. The observed pattern is consistent with the hypotheses that: (i) more thermophilous species have been subjected to stronger demographic fluctuations in the past, as a consequence of their maladaptation to recurrent glacial cold stages; and (ii) altitudinal migrations have allowed the maintenance of large effective population sizes and genetic variation in cold‐tolerant species, especially in more humid regions. In the light of these results and hypotheses, we discuss some potential genetic consequences of impending climate change.     

An evolutionary fast‐track to biocalcification

The ability to construct mineralized shells, spicules, spines and skeletons is thought to be a key factor that fuelled the expansion of multicellular animal life during the early Cambrian. The genes and molecular mechanisms that control the process of biomineralization in disparate phyla are gradually being revealed, and it is broadly recognized that an insoluble matrix of proteins, carbohydrates and other organic molecules are required for the initiation, regulation and inhibition of crystal growth. Here, we show that Astrosclera willeyana, a living representative of the now largely extinct stromatoporid sponges (a polyphyletic grade of poriferan bauplan), has apparently bypassed the requirement to evolve many of these mineral‐regulating matrix proteins by using the degraded remains of bacteria to seed CaCO₃ crystal growth. Because stromatoporid sponges formed extensive reefs during the Paelozoic and Mesozoic eras (fulfilling the role that stony corals play in modern coral reefs), and fossil evidence suggests that the same process of bacterial skeleton formation occurred in these stromatoporid ancestors, we infer that some ancient reef ecosystems might have been founded on this microbial–metazoan relationship.     

Description of Paratetrahymena parawassi n. sp. using Morphological and Molecular Evidence and a Phylogenetic Analysis of Paratetrahymena and Other Taxonomically Ambiguous Genera in the Order Loxocephalida (Ciliophora,Oligohymenophorea)

ABSTRACT. The marine scuticociliate Paratetrahymena parawassi n. sp. is described on the basis of morphology, especially infraciliature, and the sequence of its small subunit (SSU) rRNA gene to become the second known member of its genus. Paratetrahymena and other ciliates in the order Loxocephalida possess a mixture of morphological and morphogenetic features characteristic of the subclasses Hymenostomatia and Scuticociliatia. Accordingly, we used SSU rRNA sequences to analyze the phylogeny of Paratetrahymena and three other loxocephalid genera. Paratetrahymena and Cardiostomatella vermiformis formed a moderately well‐supported clade that diverged at a deep level from all other scuticociliates, supporting separation of loxocephalids from other scuticociliates as a suprafamilial taxon. Sathrophilus holtae was a sister taxon to Paratetrahymena and Cardiostomatella in a poorly supported, unresolved relationship; nevertheless, association of all three genera into a single clade was supported by an approximately unbiased (AU) test. Any association of these genera singly or as a group with the Hymenostomatia was rejected decisively by AU tests and by a complete absence in the loxocephalids of the unique nucleotide identities that distinguish hymenostomes. Therefore, the morphological and morphogenetic similarities of loxocephalids to hymenostomes may be plesiomorphies, and the conflicting mix of scuticociliate and hymenostome characteristics seen in loxocephalids may result from differing rates of character evolution. Dexiotrichides pangi and Urocentrum, which is currently classified as a peniculid, formed a small clade that associated with hymenostomes and peritrichs. Monophyly of the Loxocephalida with Dexiotrichides and/or Urocentrum included was not rejected by AU; however, inclusion of Urocentrum in the Peniculia was rejected by AU tests. A hypothesis is offered to explain the lack of resolution of loxocephalid ciliates and Urocentrum in phylogenetic trees, namely that their phylogenetic positions are influenced by a combination of heterogeneous data and long‐branch attraction caused by poor representation of taxa in analyses. The well‐known genus Cyclidium, a member of the order Pleuronematida, was revealed to be polyphyletic as a byproduct of our analyses of loxocephalids. In particular, Cyclidium porcatum appears to fall outside the clade containing typical members of the subclass Scuticociliatia and thus invites investigation as a possible member of the order Loxocephalida.     

The Effect of Hydrostatic Pressure Gradients on the Movement of Potassium across the Root Cortex

Transpiration reduces the hydrostatic pressure in the xylemand water moves into the root and across the root cortex inresponse to the pressure gradient so produced. This effect wassimulated by raising the pressure on the external medium surroundinga detopped root system. The flux of sap from the stem stumpand the concentration of potassium in the sap were measuredand the flux of potassium into xylem obtained as (sap flux Xconcentration of potassium). The application of a pressure of 2 atm. caused an approximatelyfourfold increase in potassium flux. This increase was independentof the presence of potassium in the external medium and wasdue, therefore, to an efflux of ions already stored in the roottissues. The effect was specifically due to hydrostatic pressureand not to the D.P.D. difference across the cortex, and wascaused, in part at least, by an increase in the permeabilityof the tissues to iona. This is evident since the increasedpotassium flux occurred in response to pressure, even when theconcentration of potassium in the xylem increased at the sametime, thus precluding any ‘dilution effects‘. It was confirmed that metabolic inhibitors and low temperaturereduce the sap flux but leave the concentration of the sap unchanged.Under a pressure gradient, however, there was an even greaterporportionate reduction of sap flux by equivalent concentrationsof inhibitor or low temperature and the concentration of potassiumin the sap gradually increased. Adding calcium or magnesium ions to the medium caused an increaseof potassium concentration in the sap, demonstrating exchangeprocesses in the transpiration pathway. The difficulty of framing a hypothesis to cover all the factsis discussed and it is tentatively suggested that movement acrossthe cortex to the xylem is a catenary process in which soluteand water move independently at one stage and together as asolution at another stage.     

Adaptive Significance of a Small Heat Shock/{alpha}-Crystallin Protein (p26) in Encysted Embryos of the Brine Shrimp, Artemia franciscana

Encysted embryos of the primitive crustacean, Artemia franciscana,are among the most resistant of all animal life history stagesto extremes of environmental stress. This resistance has likelybeen acquired during evolutionary adaptation to their harshecological setting. In the laboratory, for example, some ofthese embryos survive more than 6 years of continuous anoxiawhile fully hydrated and at room temperature, a phenomenal capabilitythat can easily be related to their frequent encounters withanoxic conditions in nature. A small heat shock protein belongingto the -crystallin family of proteins, referred to as p26, appearsto play a central role in the stress resistance of these embryos.Our evidence shows that this protein is an important componentin their adaptive repertoire, and vital for the survival ofArtemia in nature.