Assessment of Four Solvents for Extraction and Analysis of the Chemical Composition of Sansevieria Extrafoliar Nectar Drops by Gas Chromatography-mass Spectrometry

In the latter part of the 20th century, much effort was devoted to elucidating the chemical constituents of floral and extrafloral nectar secretions, with the primary aim of understanding their ecological roles, especially in regards to attracting pollinators. But, nearly all these studies focused on determining sugar and amino acid constituents. Only a few studies have reported more comprehensive assessments of the organic chemical constituents of plants, with none of those reporting such efforts for Sansevieria taxa (common houseplants known to purify air by bioaccumulating pollutants). To address this knowledge gap, we evaluated the efficacy of four organic solvents with distinct polarities (dichloromethane (DCM), ethyl acetate, toluene and hexane) to extract the most diverse suite of organic compounds from extrafoliar nectar drops (n = 12) secreted by motherin-law’s-tongue plant (Sansevieria spp.). Each solvent exhibited unique extraction efficiencies, with DCM extracting the greatest number of unique compounds (141), followed by hexane (113), ethyl acetate (58) and toluene (43). Compound class distributions varied with solvent type, with aliphatic hydrocarbons dominating in all but the ethyl acetate extracts. We detected 105 unique aliphatic compounds in the DCM extracts, followed by 69, 28 and 9 in the hexane, toluene and ethyl acetate extracts, respectively. Alcohols predominated in the ethyl acetate extracts. We are aware of no published studies reporting such analytical determinations of the organic compound inventories of Sansevieria extrafoliar nectars. Validation of this methodology provides the impetus to study various other plant secretions of known and unknown utility

Dynamic cratering of graphite : experimental results and simulations

The cratering process in brittle materials under hypervelocity impact (HVI) is of major relevance for debris shielding in spacecraft or high-power laser applications. Amongst other materials, carbon is of particular interest since it is widely used as elementary component in composite materials. In this paper we study a porous polycrystalline graphite under HVI and laser impact, both leading to strong debris ejection and cratering. First, we report new experimental data for normal impacts at 4100 and 4200 m s-1 of a 500-μm-diameter steel sphere on a thick sample of graphite. In a second step, dynamic loadings have been performed with a high-power nanosecond laser facility. High-resolution X-ray tomographies and observations with a scanning electron microscope have been performed in order to visualize the crater shape and the subsurface cracks. These two post-mortem diagnostics also provide evidence that, in the case of HVI tests, the fragmented steel sphere was buried into the graphite target below the crater surface. The current study aims to propose an interpretation of the results, including projectile trapping. In spite of their efficiency to capture overall trends in crater size and shape, semi-empirical scaling laws do not usually predict these phenomena. Hence, to offer better insight into the processes leading to this observation, the need for a computational damage model is argued. After discussing energy partitioning in order to identify the dominant physical mechanisms occurring in our experiments, we propose a simple damage model for porous and brittle materials. Compaction and fracture phenomena are included in the model. A failure criterion relying on Weibull theory is used to relate material tensile strength to deformation rate and damage. These constitutive relations have been implemented in an Eulerian hydrocode in order to compute numerical simulations and confront them with experiments. In this paper, we propose a simple fitting procedure of the unknown Weibull parameters based on HVI results. Good agreement is found with experimental observations of crater shapes and dimensions, as well as debris velocity. The projectile inclusion below the crater is also reproduced by the model and a mechanism is proposed for the trapping process. At least two sets of Weibull parameters can be used to match the results. Finally, we show that laser experiment simulations may discriminate in favor of one set of parameters

Exploring Molecular Simulations of a Plausible Prebiotic Reduced Phospholipid Using Hyperchem Software

How the first cells emerged from the primordial milieu is one of the great questions in science. Biomolecular emergence scenarios abound in the literature, but the lack of bioaccessible phosphate and molecular oxygen on the primordial Earth has posed formidable challenges for deducing emergence pathways. One idea gaining wide acceptance invokes delivery of the phosphide mineral schreibersite ((Fe,Ni)3P) to Earth via meteorite impacts ca. 4.2 billion years ago, whereupon they were corroded to reduced phosphorous oxyacids and phosphonates in primordial aquatic environments. We previously proposed that these reduced phosphorus forms could readily combine with putative geochemical species in shallow mineral-rich alkaline hydrothermal systems to form reduced phospholipid analogs of contemporary phosphate-based phospholipids (Fitch, N.W., K.L. Even, L.J. Leinen and M.O. Gaylor. 2016. Plausible prebiotic assembly of a primitive reduced phospholipid from meteoritic phosphorus on the primordial earth. Proceedings of the South Dakota Academy of. Science 95:176.). Lacking resources to empirically validate this idea, we explored “water box” simulations of the proposed phospholipid structure using the HyperChem software package. Simulation results showed the hydrophobic tails migrating away from water molecules, while hydrophilic heads migrated towards them, resulting in quasistacking behaviors consistent with those of known amphiphiles in water. Inspired by these results, we are now investigating more complex primordial simulation scenarios

The hetZ Gene Regulates Heterocyst Formation in Anabaena sp. strain PCC 7120

To form a complex multicellular organism, stem cells must differentiate into each cell/tissue type along proper spatiotemporal scales. The study of differentiation and organismal development has historically been conducted in prokaryotes due to their genetic and morphological simplicity. Anabaena sp. strain PCC 7120 is a multicellular filamentous cyanobacterium that differentiates a morphologically distinct secondary cell type, the heterocyst, in response to a lack of combined environmental nitrogen. Heterocysts are regularly spaced along filaments and fix atmospheric dinitrogen to maintain organismal viability in its absence. Previous work suggested that the hetZ gene is involved in heterocyst differentiation, but the insertional mutants created produced inconsistent phenotypes, so a specific role was not assigned. In this work, a clean hetZ mutant incapable of heterocyst differentiation was generated and the mutation was complemented with the reintroduction of hetZ alone. Overexpression of hetZ bypassed a mutation of hetR, the master regulator of heterocyst differentiation that controls biological pattern formation, but not a mutation of hetP, a regulator of commitment to a differentiated cell fate, which places hetZ roughly between these processes. A protein-protein interaction study showed that HetZ interacts with both HetR and itself. Assessment of transcriptional fusions between the hetZ, hetR, hetP, and patS (an inhibitor of HetR) promoter regions and GFP, and overexpression of HetR in a hetZ mutant resulted in the differentiation of heterocyst-like cells, together indicated that HetZ may act in concert with HetR as an early regulator of development. Taken together, these data describe a non-linear pathway of regulation leading to heterocyst development governed by both HetR and HetZ

Identification and Characterization of Fungal Isolates from Land-applied Sewage Sludge

Approximately eight million dry tons of sewage sludge is generated in the U.S. each year, with more than half of that now land-applied as the primary method of disposal. Despite the proliferation of this practice, little is known about the microbial constituents of these noxious materials. To address this knowledge gap, we isolated and characterized fungi present in archived samples of land-disposed sewage sludge collected from the Snoqualmie National Forest (Washington State). Sludge samples were resuspended in sterile water and 15 fungal isolates were selected and purified on sabouraud dextrose agar plates supplemented with 50 mg/L of chloramphenicol. Fungal morphology was assessed and photodocumented following growth on sabouraud dextrose agar, potato dextrose agar, yeast maltose agar, and malt extract agar. Additionally, pH and temperature tolerance was assessed by growth in liquid cultures of sabouraud dextrose broth from 0 ºC to 50 ºC and determined from pH 2 to 11 at 28 ºC. Carbon source utilization was assessed using Biolog Filamentous Fungi plates. Amplification and sequencing of the ITS region, commonly used in fungal phylogenetic analysis, is in progress to identify each isolate. Phenotypic assessments of growth, carbon utilization, and lactophenol cotton blue staining revealed that sludge-associated fungi are quite varied in size and appearance, but commonly grow in a mesophilic range (10-40 ºC and pH 4-10). Interspecies variation is further evident in the percentage of 31 carbon sources utilized (63-100%). To our knowledge, this work represents the first reported assessment of the fungal community in sewage sludge wastes disposed in the Snoqualmie National Forest

Characterizing the Volatilome of Land-disposed Sewage Sludge Under Seasonal Temperature Regimes

About eight million dry tons of sewage sludge waste is generated in the US annually, with more than half of that now land-disposed on agricultural and forested lands. Though containing essential plant nutrients, sludge also harbors complex mixtures of volatile organic compounds (VOCs) that result in toxic emissions therefrom. While ecotoxic impacts to sludged ecosystems are a primary concern, the stifling emissions are most obvious to and disconcerting for the public, which has led to increasing concerns for the safety of this practice. The large-scale disposal of sludge in the temperate rainforests of the Puget Sound Watershed has resulted in acute toxicity to macrobiota, and despite escalating concerns for detrimental impacts, little is known about the total VOC inventories, or “volatilomes,” of these complex wastes. To address this knowledge gap, we characterized VOC emissions from forest-disposed sewage sludge over a range of seasonal temperature regimes. We also incubated sludge samples at the more extreme 100 o C to assess the “complete volatilome.” After 1-hr incubations in gastight vials, VOCs accumulated in the headspace were sampled with a gastight syringe and analyzed with gas chromatography-mass spectrometry to generate distinct chemical fingerprints of sludge sample volatilomes over the range of temperatures. Total integrated chromatographic peak areas increased with temperature, indicating increased VOC production. Sludge volatilomes were dominated by a multitude of aliphatics and aromatics, with comparatively lesser emissions of alcohols, esters, aldehydes, terpenes, and nitrogen-, sulfur-, and halogen-containing compounds

Testing the Higgs Mechanism in the Lepton Sector with multi-TeV e+e- Collisions

Multi-TeV e+e- collisions provide with a large enough sample of Higgs bosons to enable measurements of its suppressed decays. Results of a detailed study of the determination of the muon Yukawa coupling at 3 TeV, based on full detector simulation and event reconstruction, are presented. The muon Yukawa coupling can be determined with a relative accuracy of 0.04 to 0.08 for Higgs bosons masses from 120 GeV to 150 GeV, with an integrated luminosity of 5 inverse-ab. The result is not affected by overlapping two-photon background.Comment: 6 pages, 2 figures, submitted to J Phys G.: Nucl. Phy

Pion and proton showers in the CALICE scintillator-steel analogue hadron calorimeter

Showers produced by positive hadrons in the highly granular CALICE scintillator-steel analogue hadron calorimeter were studied. The experimental data were collected at CERN and FNAL for single particles with initial momenta from 10 to 80 GeV/c. The calorimeter response and resolution and spatial characteristics of shower development for proton- and pion-induced showers for test beam data and simulations using Geant4 version 9.6 are compared.Comment: 26 pages, 16 figures, JINST style, changes in the author list, typos corrected, new section added, figures regrouped. Accepted for publication in JINS