Myoid fibrils in epithelial cells: studies of intestine, biliary and pancreatic pathways, trachea, bronchi, and testis.

Cytoplasmic filaments have been studied extensively by electron microscopy, but the histochemical nature of such fibrils in non-keratinizing epithelia has not been systematically investigated. During studies of early arterial lesions we observed structures with the staining properties of myosins in epithelial cells of various organs. The configurational staining, polarization and fluorescence microscopic properties of these myoid structures were compared with those of myofibrils in smooth muscle and classical myoepithelial cells. The following structures showed the characteristics of myofibrils: the terminal web in columnar epithelial cells of intestine, trachea, bronchi, bile ducts, pancreatic ducts and ductus epididymidis, the pericanalicular layer of bile and pancreatic canaliculi, fibers in the caudal tube of spermatids and the flagella of spermatozoa. Cilia, e.g. of respiratory epithelium, tonofibrils in squamous epithelium and nerve axons did not react. These studies indicate significant histochemical differences between cytoplasmic filaments. Different types of intracellular fibrils can be found in the same cell, e.g. in respiratory epithelium.     

Competition between Cellana tramoserica (Sowerby) (gastropoda) and Patiriella exigua (Lamarck) (asteroidea), and their influence on algal standing stocks

Caging experiments were undertaken in the field to test if competition occurs within and between the limpet Cellana tramoserica (Sowerby) and the starfish Patiriella exigua (Lamarck). Both species suffer from intraspecific competition, even at natural densities, and increased density reduces body weight and survival in Cellana tramoserica and growth rate in Patiriella exigua. Cellana tramoserica depresses the growth of Patiriella exigua, while the starfish unexpectedly seems beneficial to Cellana tramoserica, increasing its body weight. The difference in these effects may be due to the divergent methods of feeding used by the two species. C. tramoserica digs into the substratum and removes most available microflora, while Patiriella exigua everts its stomach onto the rock face and can only remove superficial or loosely attached microflora and detritus, and leaves a mucous web which may supplement the diet of Cellana tramoserica. Even at low densities C. tramoserica can completely prevent macroalgae from developing, while Patiriella exigua is unable to do so, although it shows the rate of development. Macroalgae grew in all the cages which contained only P. exigua, but in spite of this the starfish still suffered from intraspecific competition, probably because they cannot feed on macroalgae. Cellana tramoserica also competes by interference, and on contact with Patiriella exigua it extends its mantle and pallial tentacles, both of which may release mucus. P. exigua retreats from Cellana tramoserica, and those parts of its body that have been touched by the limpet may temporarily be immobilised and become wrinkled up. It is suggested that this interference behaviour by C. tramoserica is derived from a similar but more intense reaction that it has to invertebrate predators. Patiriella exigua lacks a pelagic larva and does not have a refuge outside the range of Cellana tramoserica. Other factors must thus be sought to explain the continued coexistence of Patiriella exigua with Cellana tramoserica. It is suggested that although C. tramoserica has a competitive effect on Patiriella exigua, it (and other grazers) may be necessary for P. exigua, preventing macroalgal growth and maintaining a surface suitable for P. exigua to feed on.     

African Herald snakes,Crotaphopeltis, show population structure for a widespread generalist but deep genetic divergence for forest specialists

The African colubrid snake genus Crotaphopeltis currently comprises six species and occurs throughout sub-Saharan Africa. The most widespread of these, Crotaphopeltis hotamboeia, inhabits most biomes, aside from rainforest and hyper-arid regions, and its catholic niche has presumably facilitated substantial gene flow. Despite this, the geographical range is large enough that ecological or physical barriers might exist, facilitating allopatric diversification. In contrast, most of the other species are habitat specialists with limited distributions (e.g., Crotaphopeltis tornieri) and would be expected to show strong genetic structure. We therefore examined species boundaries within Crotaphopeltis in a phylogenetic context using five markers (16S, cyt b, ND4, c-mos, and RAG-1) for four of the six species. Species delimitation methods included two coalescent-based and one barcoding approach. Widespread geographical sampling of C. hotamboeia allowed examination of genetic structuring across its range. The species status of Crotaphopeltis barotseensis, C. degeni, and C. hotamboeia was confirmed, whereas the Afromontane species C. tornieri comprised two candidate species. Crotaphopeltis hotamboeia did not show cryptic speciation, although its phylogeographic structure corresponded with the spatiotemporal pattern of the African savanna. Our results show how the heterogeneous African environment could influence genetic partitioning of habitat specialist and generalist species at broad geographical scales.     

Early–Middle Holocene vegetation history, climate change and human activities at Lago Riane (Ligurian Apennines, NW Italy)

The radiocarbon-dated palaeoecological study of Lago Riane (Ligurian Apennines, NW Italy) presented here forms part of a wider investigation into the relationships between Holocene vegetation succession, climate change and human activities in the northern Apennines. The record of vegetation history from Lago Riane indicates that, since the end of the last glaciation, climate change and prehistoric human activities, combined with several local factors, have strongly influenced the pattern and timing of natural vegetation succession. The pollen record indicates an important change in vegetation cover at Lago Riane at ~8500–8200 cal. years b.p., coincident with a well-known period of rapid climate change. At ~6100 cal. years b.p., Fagus woodland colonised Lago Riane during a period of climate change and expansion of Late Neolithic human activities in the upland zone of Liguria. A marked decline in Abies woodland, and the expansion of Fagus woodland, at ~4700 cal. years b.p., coincided with further archaeological evidence for pastoralism in the mountains of Liguria during the Copper Age. At ~3900–3600 cal. years b.p. (Early to Middle Bronze Age transition), a temporary expansion of woodland at Lago Riane has been provisionally attributed to a decline in human pressure on the environment during a period of short-term climate change.     

Microbiome dynamics of human epidermis following skin barrier disruption

Background

Recent advances in sequencing technologies have enabled metagenomic analyses of many human body sites. Several studies have catalogued the composition of bacterial communities of the surface of human skin, mostly under static conditions in healthy volunteers. Skin injury will disturb the cutaneous homeostasis of the host tissue and its commensal microbiota, but the dynamics of this process have not been studied before. Here we analyzed the microbiota of the surface layer and the deeper layers of the stratum corneum of normal skin, and we investigated the dynamics of recolonization of skin microbiota following skin barrier disruption by tape stripping as a model of superficial injury.

Results

We observed gender differences in microbiota composition and showed that bacteria are not uniformly distributed in the stratum corneum. Phylogenetic distance analysis was employed to follow microbiota development during recolonization of injured skin. Surprisingly, the developing neo-microbiome at day 14 was more similar to that of the deeper stratum corneum layers than to the initial surface microbiome. In addition, we also observed variation in the host response towards superficial injury as assessed by the induction of antimicrobial protein expression in epidermal keratinocytes.

Conclusions

We suggest that the microbiome of the deeper layers, rather than that of the superficial skin layer, may be regarded as the host indigenous microbiome. Characterization of the skin microbiome under dynamic conditions, and the ensuing response of the microbial community and host tissue, will shed further light on the complex interaction between resident bacteria and epidermis.     

Respect for outsiders? respect for the law? the moral evaluation of high scale issues by US immigration officers

High-scale morality is the study of moral ideas and sentiments deployed in relations that encompass multiple, geographically or socially distant populaces. The envisioning of distant people, their attributed moral personhood, the evaluation of their perceived behaviour, and the rectification of wrongs through the use of powerful organizations are key topics in high-scale morality. High-scale morality differs from existing anthropological approaches that emphasize local ethnography or contrastive moral ideas; it addresses the moralization of issues like world hunger, the drug trade, or international migration. The officers of the US Immigration and Naturalization Service understand and evaluate legal and illegal immigrants, as well as directly enacting moral rectification for the US polity. As they resolve moral dilemmas on their job, they utilize pervasive models for moral thought and action in capitalist, individualist, stratified, and bureaucratized societies. The article finishes by considering directions in which anthropology can contribute to understanding the moral dimension of global issues.     

Hermansky-Pudlak Syndrome Protein Complexes Associate with Phosphatidylinositol 4-Kinase Type II �� in Neuronal and Non-neuronal Cells

The Hermansky-Pudlak syndrome is a disorder affecting endosome sorting. Disease is triggered by defects in any of 15 mouse gene products, which are part of five distinct cytosolic molecular complexes: AP-3, homotypic fusion and vacuole protein sorting, and BLOC-1, -2, and -3. To identify molecular associations of these complexes, we used in vivo cross-linking followed by purification of cross-linked AP-3 complexes and mass spectrometric identification of associated proteins. AP-3 was co-isolated with BLOC-1, BLOC-2, and homotypic fusion and vacuole protein sorting complex subunits; clathrin; and phosphatidylinositol-4-kinase type II α (PI4KIIα). We previously reported that this membrane-anchored enzyme is a regulator of AP-3 recruitment to membranes and a cargo of AP-3 (Craige, B., Salazar, G., and Faundez, V. (2008) Mol. Biol. Cell 19,1415 -1426). Using cells deficient in different Hermansky-Pudlak syndrome complexes, we identified that BLOC-1, but not BLOC-2 or BLOC-3, deficiencies affect PI4KIIα inclusion into AP-3 complexes. BLOC-1, PI4KIIα, and AP-3 belong to a tripartite complex, and down-regulation of either PI4KIIα, BLOC-1, or AP-3 complexes led to similar LAMP1 phenotypes. Our analysis indicates that BLOC-1 complex modulates the association of PI4KIIα with AP-3. These results suggest that AP-3 and BLOC-1 act, either in concert or sequentially, to specify sorting of PI4KIIα along the endocytic route.Membranous organelles along the exocytic and endocytic pathways are each defined by unique lipid and protein composition. Vesicle carriers communicate and maintain the composition of these organelles (2). Consequently defining the machineries that specify vesicle formation, composition, and delivery are central to understanding membrane protein traffic. Generally vesicle biogenesis uses multiprotein cytosolic machineries to select membrane components for inclusion in nascent vesicles (2, 3). Heterotetrameric adaptor complexes (AP-1 to AP-4) are critical to generate vesicles of specific composition from the different organelles constituting the exocytic and endocytic routes (2-4).The best understood vesicle formation machinery in mammalian cells is the one organized around the adaptor complex AP-2 (5). This complex generates vesicles from the plasma membrane using clathrin. Our present detailed understanding of AP-2 vesicle biogenesis mechanisms and interactions emerged from a combination of organellar and in vitro binding proteomics analyses together with the study of binary interactions in cell-free systems (5-9). In contrast, the vesicle biogenesis pathways controlled by AP-3 are far less understood. AP-3 functions to produce vesicles that traffic selected membrane proteins from endosomes to lysosomes, lysosome-related organelles, or synaptic vesicles (10-13). AP-3 is one of the protein complexes affected in the Hermansky-Pudlak syndrome (HPS;³ Online Mendelian Inheritance in Man (OMIM) 203300). So far, mutations in any of 15 mouse or eight human genes trigger a common syndrome. This syndrome encompasses defects that include pigment dilution, platelet dysfunction, pulmonary fibrosis, and occasionally neurological phenotypes (14, 15). All forms of HPS show defective vesicular biogenesis or trafficking that affects lysosomes, lysosome-related organelles (for example melanosomes and platelet dense granules), and, in some of them, synaptic vesicles (11-13). Most of the 15 HPS loci encode polypeptides that assemble into five distinct molecular complexes: the adaptor complex AP-3, HOPS, and the BLOC complexes 1, 2, and 3 (14). Recently binary interactions between AP-3 and BLOC-1 or BLOC-1 and BLOC-2 suggested that arrangements of these complexes could regulate membrane protein targeting (16). Despite the abundance of genetic deficiencies leading to HPS and genetic evidence that HPS complexes may act on the same pathway in defined cell types (17), we have only a partial picture of protein interactions organizing these complexes and how they might control membrane protein targeting.In this study, we took advantage of cell-permeant and reversible cross-linking of HPS complexes followed by their immunoaffinity purification to identify novel molecular interactions. Cross-linked AP-3 co-purified with BLOC-1, BLOC-2, HOPS, clathrin, and the membrane protein PI4KIIα. We previously identified PI4KIIα as a cargo and regulator of AP-3 recruitment to endosomes (1, 18). Using mutant cells deficient in either individual HPS complexes or a combination of them, we found that BLOC-1 facilitates the interaction of AP-3 and PI4KIIα. Our studies demonstrate that subunits of four of the five HPS complexes co-isolate with AP-3. Moreover BLOC-1, PI4KIIα, and AP-3 form a tripartite complex as demonstrated by sequential co-immunoprecipitations as well as by similar LAMP1 distribution phenotypes induced by down-regulation of components of this tripartite complex. Our findings indicate that BLOC-1 complex modulates the recognition of PI4KIIα by AP-3. These data suggest that AP-3, either in concert or sequentially with BLOC-1, participates in the sorting of common membrane proteins along the endocytic route.