Historical biogeography and morphological differentiation ofStreptocephalus torvicornis (Waga) since the Würm III-glaciation

We argue that the Würm III glaciation eradicated possible European populations ofS. torvicornis, and that today, a reconquest of Europe takes place on two fronts.A western wave has reached the Pyrenees, an eastern one now occupies most of eastern and northern Europe. The western route probably started in the Maghreb, the eastern one in the Levant and the Ponto-Caspian. Animals in the west had to move north by crossing, at right angles, a series of east-west oriented river valleys and progressed slowly; animals in the east could move up river valleys extending north-east, and moved quickly. Italy was not occupied, becauseS.torvicornis is a warm stenotherm, and by the time the climate had warmed sufficiently for it to reach the southern shore of the mediterranean (ca 6000 BP), the gap with Italy was probably too large for a crossing. Cold-loving species (of the generaBranchipus, Chirocephalus) conversely, and could freely flow across the Central Mediterranean at low sea-levels (ca 12000 BP), and now occur in Italy (and the rest of Europe) as well as in Northern Africa.A prediction of our hypothesis is that the pioneer populations in Spain and Central Europe should have been isolated longest. Thisis tested and confirmed by their comparative morphology, and two subspecies,S. t. torvicornis andS. t. bucheti are reinstated.A gap across the Nile Valley where onlyS. rubricaudatus seems to occur, deserves further study.     

A new non-equilibrium enzyme linked immunosorbent assay for a glycogen-derived urinary tetrasaccharide

The tetrasaccharide, Glc1-6Glc1-4Glc1-4Glc, denoted (Glc)₄, is a limit dextrin formed by amylolytic degradation of glycogen. In order to evaluate the possible clinical importance of (Glc)₄ excretion as an indicator of certain physiological and pathological conditions, we have developed a new rapid and inexpensive immunoassay using a monoclonal antibody raised against (Glc)₄ glycosidically-linked to a carrier protein. As the antibody is highly specific, it can be used to measure native (Glc)₄ directly, without the chemical reduction step required in previous methods. A new type of non-equilibrium ELISA inhibition test was developed based on the capacity of free (Glc)₄ to decrease initial rates of antibody binding to (Glc)₄-coated microtiter wells. The method is highly reproducible and is as sensitive and accurate as the gas chromatography method or radioimmunoassay used previously.Abbreviations (Glc)₄ Glc1-6Glc1-4Glc1-4Glc - KLH keyhole limpet hemacyanin - BSA bovine serum albumin - PEG polyethylene glycol     

Mutations of Factor H Impair Regulation of Surface-bound C3b by Three Mechanisms in Atypical Hemolytic Uremic Syndrome

Atypical hemolytic uremic syndrome (aHUS) is a thrombotic microangiopathy associated with mutations in complement proteins, most frequently in the main plasma alternative pathway regulator factor H (FH). The hotspot for the FH mutations is in domains 19–20 (FH19–20) that are indispensable for FH activity on C3b bound covalently to host cells. In aHUS, down-regulation of cell-bound C3b by FH is impaired, but it is not clear whether this is due to an altered FH binding to surface-bound C3b or to cell surface structures. To explore the molecular pathogenesis of aHUS we tested binding of 14 FH19–20 point mutants to C3b and its C3d fragment, mouse glomerular endothelial cells (mGEnC-1), and heparin. The cell binding correlated well, but not fully, with heparin binding and the cell binding site was overlapping but distinct from the C3b/C3d binding site that was shown to extend to domain 19. Our results show that aHUS-associated FH19–20 mutants have different combinations of three primary defects: impaired binding to C3b/C3d, impaired binding to the mGEnC-1 cells/heparin, and, as a novel observation, an enhanced mGEnC-1 cell or heparin binding. We propose a model of the molecular pathogenesis of aHUS where all three mechanisms lead eventually to impaired control of C3b on the endothelial cell surfaces. Based on the results with the aHUS patient mutants and the overlap in FH19–20 binding sites for mGEnC-1/heparin and C3b/C3d we conclude that binding of FH19–20 to C3b/C3d is essential for target discrimination by the alternative pathway.Atypical hemolytic uremic syndrome (aHUS)2 is a familial disease characterized by erythrocyte fragmentation and hematuria, damaged renal endothelium, vascular microthrombi, and thrombocytopenia (1). The syndrome leads ultimately to end-stage renal disease with a high mortality rate (2). In aHUS cases point mutations have been found in complement components C3, factor B, CD46, factor I, and factor H (FH), all of which play a role in the activation or control of the alternative pathway (3–8). More than half of the mutations have been found to originate in the HF1 gene that encodes FH and FH-like protein 1.The alternative pathway is initiated spontaneously by hydrolysis of C3 to C3_H2O that forms the C3-convertase C3_H2OBb (9, 10). This enzyme complex converts numerous C3 molecules to C3b that are covalently bound onto practically any nearby surface (11). On a so-called activator surface, such as a microbe, the surface-bound C3b molecules are not efficiently eliminated and therefore new C3bBb complexes are formed leading to more C3b depositions and eventually effective opsonization or damage of the target cell. On non-activator surfaces, such as viable self (host) cells, factor I cleaves C3b to inactive C3b (iC3b) in the presence of one of the cofactors (CD46, CD35, FH, and FHL-1) (12–16). FH is the only one of these cofactors that mediates recognition of self-surfaces making the alternative pathway capable of discriminating between activating and non-activating surfaces (17–19).The two main functions of FH are to prevent the alternative pathway activation in plasma and on self-surfaces. This 150-kDa glycoprotein consists of 20 tandemly arranged short consensus repeat domains that are composed of ∼60 amino acids. Domains 1–4 are essential for the cofactor and decay accelerating activity (20). In the middle region of FH (domains 5–15) there are two binding sites for C-reactive protein (21), one or two sites for glycosaminoglycans (GAGs) (22–25), and one site for C3c part of C3b (C3b/C3c) (25, 26). The C-terminal domains 19–20 (FH19–20) possess binding sites for the thiol ester domain of C3b (C3d or C3dg, TED domain) and GAGs (26, 27).The most common types of mutations found in aHUS are FH missense mutations located within FH19–20 that was recently solved as crystal and NMR structures (2, 28, 29). The C terminus of FH is crucial in self-cell protection as demonstrated by the severity of the aHUS cases and also in a recent mouse model of aHUS where domains 16–20 had been deleted (30, 31). Histopathology of aHUS in these mice had all the characteristics of human aHUS being concordant with the similarity of binding sites for C3b, heparin, and human umbilical vein endothelial cells between human and mouse FH domains 18–20 (32). Binding of mouse or human FH to glomerular endothelial cells has not been characterized despite the fact that in aHUS damage occurs mainly in the small vessels, especially in the glomeruli.The molecular pathogenesis leading to the clinical aHUS in patients with FH mutations remains elusive. The suggested molecular mechanisms for some aHUS-associated mutations include defective binding of the mutated FH to GAGs, endothelial cells, or C3b/C3d (28, 29, 33, 34). The aim of this study was to define the effects of nine aHUS-associated FH mutations and five other structurally closely located mutations on binding of FH19–20 to C3b, C3d, mouse glomerular endothelial cells, and heparin. We identified three primary defects of the mutants: impaired C3b/C3d binding, enhanced mGEnC-1/heparin binding, and impaired mGEnC-1/heparin binding that could lead via three mechanisms to incapability of FH to eliminate C3b on plasma-exposed self-cells. The results clarify the mechanism of target discrimination of the alternative pathway by the C terminus of FH.     

A TGFβRII frameshift-mutation-derived CTL epitope recognised by HLA-A2-restricted CD8+ T cells

Microsatellite instability (MSI) is recognised as genome-wide alterations in repetitive DNA sequences caused by defects in the DNA mismatch repair machinery. Such mutation patterns have been found in almost all analysed malignancies from patients with hereditary non-polyposis colorectal cancer, and in approximately 15% of sporadic colorectal cancers. In cancers with the MSI phenotype, microsatellite-like sequences in coding regions of various cancer-related genes, including transforming growth factor beta receptor type II (TGF betaRII), are targets for mutations. The TGF betaRII gene harbours a 10-bp polyadenine tract, and mutations within this region are found in 90% of colorectal cancers with MSI. The frameshift mutations result in new amino acid sequences in the C-terminal part of the proteins, prematurely terminating where a novel stop codon appears. In this study we have defined new cytotoxic T lymphocyte (CTL) epitope (RLSSCVPVA), carrying a good HLA-A*0201 binding motif, and resulting from the most common frameshift mutation in TGF betaRII. A CTL line and several CTL clones were generated from an HLA-A2+ normal donor by repeated stimulation of T cells with dendritic cells pulsed with the peptide. One of the CTL clones was able to kill an HLA-A2+ colon cancer cell line harbouring mutant TGF betaRII. This epitope may be a valuable component in cancer vaccines directed at MSI-positive carcinomas.     

How Could Language Have Evolved?

The evolution of the faculty of language largely remains an enigma. In this essay, we ask why. Language''s evolutionary analysis is complicated because it has no equivalent in any nonhuman species. There is also no consensus regarding the essential nature of the language “phenotype.” According to the “Strong Minimalist Thesis,” the key distinguishing feature of language (and what evolutionary theory must explain) is hierarchical syntactic structure. The faculty of language is likely to have emerged quite recently in evolutionary terms, some 70,000–100,000 years ago, and does not seem to have undergone modification since then, though individual languages do of course change over time, operating within this basic framework. The recent emergence of language and its stability are both consistent with the Strong Minimalist Thesis, which has at its core a single repeatable operation that takes exactly two syntactic elements a and b and assembles them to form the set {a, b}.It is uncontroversial that language has evolved, just like any other trait of living organisms. That is, once—not so long ago in evolutionary terms—there was no language at all, and now there is, at least in Homo sapiens. There is considerably less agreement as to how language evolved. There are a number of reasons for this lack of agreement. First, “language” is not always clearly defined, and this lack of clarity regarding the language phenotype leads to a corresponding lack of clarity regarding its evolutionary origins. Second, there is often confusion as to the nature of the evolutionary process and what it can tell us about the mechanisms of language. Here we argue that the basic principle that underlies language''s hierarchical syntactic structure is consistent with a relatively recent evolutionary emergence.     

Predicting spacing behavior and mating systems of solitary cervids: a study of hog deer and Indian muntjac

This study investigates the validity of current theory for predicting ecological and allometric effects on space use, social structure and mating systems of poorly known solitary cervids, based on a comparative analysis of radio-telemetry data on hog deer Axis porcinus (N=32) and Indian muntjac Muntiacus muntjak (N=28). The larger and sexually size-dimorphic hog deer inhabit highly productive alluvial floodplains, where resource distribution is patchy and spatiotemporally unpredictable. As predicted for this species, site fidelity was low and range sizes varied among sex and age groups and among seasons. Hog deer were probably non-territorial, as home range sizes seemed too large to be exclusive when taking into account their high population density. Extensive movements of adult males during the rut implied "roaming" as a mating strategy. The smaller, forest-dwelling and sexually size-monomorphic muntjacs inhabit a more uniform and stable habitat. As predicted, muntjacs exhibited higher site fidelity than hog deer, and no seasonal variations in home range sizes. Adults exhibited relatively large home range overlap, both inter- and intrasexually. Hence, strict territoriality did not occur, but their well-defined home ranges and high site fidelity indicated some form of site-specific dominance. In conclusion, habitat characteristics were appropriate predictors of home range sizes and site fidelity. Body mass appeared to be a suitable predictor of intraspecific patterns in space use but a poor predictor of interspecific patterns, probably due to a confounding effect of habitat productivity.     

Evolution of the ovenbird-woodcreeper assemblage (Aves: Furnariidae) - major shifts in nest architecture and adaptive radiation

The Neotropical ovenbirds (Furnariidae) form an extraordinary morphologically and ecologically diverse passerine radiation, which includes many examples of species that are superficially similar to other passerine birds as a resulting from their adaptations to similar lifestyles. The ovenbirds further exhibits a truly remarkable variation in nest types, arguably approaching that found in the entire passerine clade. Herein we present a genus-level phylogeny of ovenbirds based on both mitochondrial and nuclear DNA including a more complete taxon sampling than in previous molecular studies of the group. The phylogenetic results are in good agreement with earlier molecular studies of ovenbirds, and supports the suggestion that Geositta and Sclerurus form the sister clade to both core-ovenbirds and woodcreepers. Within the core-ovenbirds several relationships that are incongruent with traditional classifications are suggested. Among other things, the philydorine ovenbirds are found to be non-monophyletic. The mapping of principal nesting strategies onto the molecular phylogeny suggests cavity nesting to be plesiomorphic within the ovenbird–woodcreeper radiation. It is also suggested that the shift from cavity nesting to building vegetative nests is likely to have happened at least three times during the evolution of the group. We suggest that the shifts in nest architecture within the furnariine and synallaxine ovenbirds have served as an ecological release that has facilitated diversification into new habitats and new morphological specializations.