The Formation of Endoderm-Derived Taste Sensory Organs Requires a Pax9-Dependent Expansion of Embryonic Taste Bud Progenitor Cells

In mammals, taste buds develop in different regions of the oral cavity. Small epithelial protrusions form fungiform papillae on the ectoderm-derived dorsum of the tongue and contain one or few taste buds, while taste buds in the soft palate develop without distinct papilla structures. In contrast, the endoderm-derived circumvallate and foliate papillae located at the back of the tongue contain a large number of taste buds. These taste buds cluster in deep epithelial trenches, which are generated by intercalating a period of epithelial growth between initial placode formation and conversion of epithelial cells into sensory cells. How epithelial trench formation is genetically regulated during development is largely unknown. Here we show that Pax9 acts upstream of Pax1 and Sox9 in the expanding taste progenitor field of the mouse circumvallate papilla. While a reduced number of taste buds develop in a growth-retarded circumvallate papilla of Pax1 mutant mice, its development arrests completely in Pax9-deficient mice. In addition, the Pax9 mutant circumvallate papilla trenches lack expression of K8 and Prox1 in the taste bud progenitor cells, and gradually differentiate into an epidermal-like epithelium. We also demonstrate that taste placodes of the soft palate develop through a Pax9-dependent induction. Unexpectedly, Pax9 is dispensable for patterning, morphogenesis and maintenance of taste buds that develop in ectoderm-derived fungiform papillae. Collectively, our data reveal an endoderm-specific developmental program for the formation of taste buds and their associated papilla structures. In this pathway, Pax9 is essential to generate a pool of taste bud progenitors and to maintain their competence towards prosensory cell fate induction.     

Phage endolysins are adapted to specific hosts and are evolutionarily dynamic

Endolysins are produced by (bacterio)phages to rapidly degrade the bacterial cell wall and release new viral particles. Despite sharing a common function, endolysins present in phages that infect a specific bacterial species can be highly diverse and vary in types, number, and organization of their catalytic and cell wall binding domains. While much is now known about the biochemistry of phage endolysins, far less is known about the implication of their diversity on phage–host adaptation and evolution. Using CRISPR-Cas9 genome editing, we could genetically exchange a subset of different endolysin genes into distinct lactococcal phage genomes. Regardless of the type and biochemical properties of these endolysins, fitness costs associated to their genetic exchange were marginal if both recipient and donor phages were infecting the same bacterial strain, but gradually increased when taking place between phage that infect different strains or bacterial species. From an evolutionary perspective, we observed that endolysins could be naturally exchanged by homologous recombination between phages coinfecting a same bacterial strain. Furthermore, phage endolysins could adapt to their new phage/host environment by acquiring adaptative mutations. These observations highlight the remarkable ability of phage lytic systems to recombine and adapt and, therefore, explain their large diversity and mosaicism. It also indicates that evolution should be considered to act on functional modules rather than on bacteriophages themselves. Furthermore, the extensive degree of evolvability observed for phage endolysins offers new perspectives for their engineering as antimicrobial agents.

Endolysins are produced by bacteriophages to degrade the host cell wall and release new particles, but the implications of their diversity on phage-host adaptation and evolution is unknown. This study uses CRISPR-Cas9 genome editing to reveal novel insights into bacteriophage endolysin diversity and phage-bacteria interactions as well as into endolysin adaptation towards a new bacterial host.     

Behaviour-Genetics of Lake Charr (Salvelinus namaycush) and Brook Charr (S. fontinalis): Observation of Backcross and F2 Generations

Brook charr (Salvelinus fontinalis) defend territories and show high levels of agonistic behaviour. In contrast, lake charr (S. namaycush) are non-territorial and rarely show any agonistic behaviour. The genetic determinance of behavioural differences between these species was confirmed by the behavioural similarity of brook charr backcross hybrids and brook charr and a significant maternal effect on hybrid behavioural phenotypes. Backcross and F₂ generations showed either one of two distinct behavioural strategies, one aggressive and territorial and the other non-aggressive and non-territorial. It seems most likely that these strategies are conditional on individual phenotypes, such as size of nearby conspecifics. However, precise measurements of costs and benefits of each strategy are required to distinguish between these alternate hypotheses for either species. Each action pattern was an independent pattern of variation and a distinct behavioural unit. However, patterns were coordinated with all other patterns at a higher hierarchical level (corresponding to the particular behavioural strategy). It seems most likely that these strategies would be controlled by a polygenic system, even though the nature of our data does not allow us to make firm conclusions in this regard.     

Dissimilar peptide growth factors can induce normal human mesothelial cell multiplication

Summary Quiescent normal human mesothelial (NHM) cells will undergo one round of DNA synthesis when they are incubated in a defined medium consisting of LHC basal medium supplemented with hydrocortisone, insulin, transferrin, and one of the following peptide mitogens: epidermal growth factor; transforming growth factor beta (1 or 2); platelet derived growth factor (a,b heterodimer or b,b homodimer); fibroblast growth factor (acid or basic forms); interleukin 1 (alpha or beta forms); interleukin 2; interferon gamma; interferon beta; or cholera toxin. However, sustained cell multiplication does not occur unless the medium contains hydrocortisone, insulin, transferrin, any one of the above-listed peptide growth factors and high density lipoproteins. Growth can be increased twofold if the medium contains certain combinations of these mitogens and high density lipoproteins. The finding that NHM cells can respond to a broad spectrum of growth factors supports the possibility that an autocrine mechanism may be part of the mechanism that leads to transformation of these cells by asbestos.     

Consequences of cytochrome c oxidase assembly defects for the yeast stationary phase

The assembly of cytochrome c oxidase (COX) is essential for a functional mitochondrial respiratory chain, although the consequences of a loss of assembled COX at yeast stationary phase, an excellent model for terminally differentiated cells in humans, remain largely unexamined. In this study, we show that a wild-type respiratory competent yeast strain at stationary phase is characterized by a decreased oxidative capacity, as seen by a reduction in the amount of assembled COX and by a decrease in protein levels of several COX assembly factors. In contrast, loss of assembled COX results in the decreased abundance of many mitochondrial proteins at stationary phase, which is likely due to decreased membrane potential and changes in mitophagy. In addition to an altered mitochondrial proteome, COX assembly mutants display unexpected changes in markers of cellular oxidative stress at stationary phase. Our results suggest that mitochondria may not be a major source of reactive oxygen species at stationary phase in cells lacking an intact respiratory chain.     

DEVELOPMENTAL STABILITY OF RAINBOW TROUT HYBRIDS: GENOMIC COADAPTATION OR HETEROZYGOSITY?

I compare the developmental stability of first generation hybrids between hatchery strains of rainbow trout (Salmo gairdneri) to that of the three pure parental strains raised in a common environment. Two of three reciprocal hybrid pairs show significantly less fluctuating asymmetry of four meristic characters than is found in parental strains. In contrast, the third hybrid pair shows reduced but not significantly lower developmental stability compared to pure strains. These hybrids had previously been found to develop slower than their maternal parental strains, indicating divergence of parental regulatory mechanisms controlling early ontogeny. A significant positive association between the degree of relative delay in hybrid developmental rate and their degree of developmental instability supports this view. For example, the only hybrid pair with decreased developmental stability also had the largest relative delay in development time of all hybrids. Neither absolute developmental rate nor enzyme heterozygosity at 42 loci alone can explain the degree of fluctuating asymmetry in these hybrids. The developmental stability of hybrids is apparently a result of the interaction between the developmental divergence between parental strains and their genomic heterozygosity due to hybridization.     

Foraging environment determines the genetic architecture and evolutionary potential of trophic morphology in cichlid fishes

Phenotypic plasticity allows organisms to change their phenotype in response to shifts in the environment. While a central topic in current discussions of evolutionary potential, a comprehensive understanding of the genetic underpinnings of plasticity is lacking in systems undergoing adaptive diversification. Here, we investigate the genetic basis of phenotypic plasticity in a textbook adaptive radiation, Lake Malawi cichlid fishes. Specifically, we crossed two divergent species to generate an F₃ hybrid mapping population. At early juvenile stages, hybrid families were split and reared in alternate foraging environments that mimicked benthic/scraping or limnetic/sucking modes of feeding. These alternate treatments produced a variation in morphology that was broadly similar to the major axis of divergence among Malawi cichlids, providing support for the flexible stem theory of adaptive radiation. Next, we found that the genetic architecture of several morphological traits was highly sensitive to the environment. In particular, of 22 significant quantitative trait loci (QTL), only one was shared between the environments. In addition, we identified QTL acting across environments with alternate alleles being differentially sensitive to the environment. Thus, our data suggest that while plasticity is largely determined by loci specific to a given environment, it may also be influenced by loci operating across environments. Finally, our mapping data provide evidence for the evolution of plasticity via genetic assimilation at an important regulatory locus, ptch1. In all, our data address long‐standing discussions about the genetic basis and evolution of plasticity. They also underscore the importance of the environment in affecting developmental outcomes, genetic architectures, morphological diversity and evolutionary potential.     

Isolation of separate apical,lateral and basal plasma membrane from cells of an insect epithelium. A procedure based on tissue organization and ultrastructure

The tissue used in this study was the midgut of the tobacco hornworm larva, Manduca sexta. The midgut epithelium is a single layer of cells resting on a thin basal lamina and underlying discontinuous muscle layer. The epithelial cells are of two main types, goblet and columnar cells, joined together by the septate junctions characteristic of insect epithelia. From this tissue we were able to isolate four distinct plasma membrane fractions; the lateral membranes, the columnar cell apical membrane, the goblet cell apical membrane and a preparation of basal membranes from both cell types. The lateral membranes were isolated by density gradient centrifugation following gentle homogenization of the midgut hypotonic medium, which caused the cells to rupture at their apical and basal surfaces, releasing long segments of lateral membranes still joined by their septate junctions. For isolation of apical and basal membranes the tissue was disrupted by ultrasound, based on the light microscopic observation that carefully controlled ultrasound can be used to disrupt each cell in layers starting at the apical surface. The top layer contained the columnar cell apical membrane, which consists of microvilli forming a brush border covering the lumenal surface of the epithelium. The second layer contained the goblet cell apical membrane, which is invaginated to form a cavity occupying the apical half of the cell, and the third layer contained the basal membranes. As each layer was stripped off the epithelium it was collected and the plasma membrane purified by differential or density gradient centrifugation. For all four membrane fractions, the isolation procedure was designed to preserve the original structure of the membrane as far as possible. This allowed electron microscopy to be used to follow each step in the isolation procedure, and to identify the constituents of each subcellular preparation. Although developed specifically for M. sexta midgut, these techniques could readily be modified for use on other epithelia.     

Psychomotor performance during insulin-induced hypoglycemia

Subjects were given intravenous injections of insulin and/or saline on separate occasions and then tested on a pursuit-tracking task. Seven subjects showed clear clinical signs of hypoglycemia which were accompanied by a plasma glucose concentration of 32 mg/dl or less and by impaired tracking performance. Seven subjects showing no hypoglycemic signs despite insulin, and seven subjects receiving saline injections, showed no impairment in tracking. Impairment lasted from about the 15th to the 60th minute following injection, and was more readily apparent in response execution than response selection. There were no changes in accuracy of performance. Possible explanatory mechanisms, including neuroglycopenia, are discussed, and some implications for driving performance are noted.