Your search keyword '"Santos, Julia C."' showing total 21 results

1. Ammonium hydrosulfide (NH4SH) as a potentially significant sulfur sink in interstellar ices

Author

Slavicinska, Katerina, Boogert, Adwin, Tychoniec, Łukasz, van Dishoeck, Ewine F., van Gelder, Martijn L., Santos, Julia C., Klaassen, Pamela D., Kavanagh, Patrick J., and Chuang, Ko-Ju

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Solar and Stellar Astrophysics

Abstract

Sulfur is depleted with respect to its cosmic standard abundance in dense star-forming regions. It has been suggested that this depletion is caused by the freeze-out of sulfur on interstellar dust grains, but the observed abundances and upper limits of sulfur-bearing ices remain too low to account for all of the missing sulfur. Toward the same environments, a strong absorption feature at 6.85 $\mu$m is observed, but its long-standing assignment to the NH4+ cation remains tentative. We investigate the plausibility of NH4SH salt serving as a sulfur reservoir and a carrier of the 6.85 $\mu$m band in interstellar ices by characterizing its IR signatures and apparent band strengths in water-rich laboratory ice mixtures and using this laboratory data to constrain NH4SH abundances in observations of 4 protostars and 2 cold dense clouds. The observed 6.85 $\mu$m feature is fit well with the laboratory NH4SH:H2O ice spectra. NH4+ column densities obtained from the 6.85 $\mu$m band range from 8-23% with respect to H2O toward the sample of protostars and dense clouds. The redshift of the 6.85 $\mu$m feature correlates with higher abundances of NH4+ with respect to H2O in both the laboratory data presented here and observational data of dense clouds and protostars. The apparent band strength of the SH- feature is likely too low for the feature to be detectable in the spectrally busy 3.9 $\mu$m region, but the 5.3 $\mu$m NH4+ $\nu_{4}$ + SH- R combination mode may be an alternative means of detection. Its tentative assignment adds to mounting evidence supporting the presence of NH4+ salts in ices and is the first tentative observation of the SH- anion toward interstellar ices. If the majority ($\gtrsim$80-85%) of the NH4+ cations quantified toward the investigated sources in this work are bound to SH- anions, then NH4SH salts could account for up to 17-18% of their sulfur budgets., Comment: Accepted for publication in A&A. 20 pages, 14 figures, and 7 tables in the main text; 15 pages, 17 figures, and 10 tables in the appendix

Published

2024

2. Formation of carbonyl sulfide (OCS) via SH radicals in interstellar CO-rich ice under dense cloud conditions

Author

Santos, Julia C., Linnartz, Harold, and Chuang, Ko-Ju

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

Carbonyl sulfide (OCS) is widely observed in the gas phase towards star-forming regions and was the first of the only two sulfur-bearing species detected in interstellar ices so far. However, the chemical network governing its formation is still not fully understood. While the sulfurization of CO and the oxidation of CS are often invoked to form OCS, other mechanisms could have a significant contribution. In particular, the multistep reaction involving CO and SH is a good candidate to forming OCS in dense cloud environments. We aim to constrain the viability of the CO + SH route to forming solid OCS in the interstellar medium, in a similar manner as CO + OH is known to produce CO2 ice. This is achieved by conducting a systematic laboratory investigation of the targeted reactions on interstellar ice analogues under dense cloud conditions. An ultrahigh vacuum chamber is utilized to simultaneously deposit CO, H2S, and atomic H at 10 K. SH radicals produced in situ via hydrogen abstraction from H2S react with CO to form OCS. OCS is efficiently formed through surface reactions involving CO, H2S, and H atoms. The suggested underlying mechanism behind OCS formation is CO + SH -> HSCO followed by HSCO + H -> OCS + H2. The OCS yield reduces slowly, but remains significant with increasing CO:H2S mixing ratios (CO:H2S = 1:1, 5:1, 10:1, and 20:1). Our experiments provide unambiguous evidence that OCS can be formed from CO + SH in the presence of H atoms. This route remains efficient for large H2S dilutions (5% w.r.t CO), suggesting that it is a viable mechanism in interstellar ices. Given that SH radicals can be created in clouds throughout a wide evolutionary timescale, this mechanism could have a non-negligible contribution to forming interstellar OCS ice., Comment: 7 pages, 4 figures, 1 table, accepted for publication in A&A on August 6th, 2024

Published

2024

3. SO2 and OCS toward high-mass protostars: A comparative study between ice and gas

Author

Santos, Julia C., van Gelder, Martijn L., Nazari, Pooneh, Ahmadi, Aida, and van Dishoeck, Ewine F.

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

We investigate the chemical history of interstellar OCS and SO2 by deriving a statistically-significant sample of gas-phase column densities towards massive protostars and comparing to observations of gas and ices towards other sources spanning from dark clouds to comets. We analyze a subset of 26 line-rich massive protostars observed by ALMA as part of the ALMAGAL survey. Column densities are derived for OCS and SO2 from their rare isotopologues O13CS and 34SO2 towards the compact gas around the hot core. We find that gas-phase column density ratios of OCS and SO2 with respect to methanol remain fairly constant as a function of luminosity between low- and high-mass sources, despite their very different physical conditions. The derived gaseous OCS and SO2 abundances relative to CH3OH are overall similar to protostellar ice values, with a significantly larger scatter for SO2 than for OCS. Cometary and dark-cloud ice values agree well with protostellar gas-phase ratios for OCS, whereas higher abundances of SO2 are generally seen in comets compared to the other sources. Gaseous SO2/OCS ratios are consistent with ices toward dark clouds, protostars, and comets, albeit with some scatter. The constant gas-phase column density ratios throughout low and high-mass sources indicate an early stage formation before intense environmental differentiation begins. Icy protostellar values are similar to the gas phase medians, compatible with an icy origin of these species followed by thermal sublimation. The larger spread in SO2 compared to OCS ratios w.r.t. CH3OH is likely due to a more water-rich chemical environment associated with the former, as opposed to a CO-rich origin of the latter. Post-sublimation gas-phase processing of SO2 can also contribute to the large spread. Comparisons to ices in dark clouds and comets point to a significant inheritance of OCS from earlier to later evolutionary stages., Comment: Accepted for publication in Astronomy and Astrophysics on July 17th 2024

Published

2024

4. Formation of S-bearing complex organic molecules in interstellar clouds via ice reactions with C2H2, HS, and atomic H

Author

Santos, Julia C., Enrique-Romero, Joan, Lamberts, Thanja, Linnartz, Harold, and Chuang, Ko-Ju

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Solar and Stellar Astrophysics

Abstract

The chemical network governing interstellar sulfur has been the topic of unrelenting discussion for the past decades due to the conspicuous discrepancy between its expected and observed abundances in different interstellar environments. More recently, the astronomical detections of CH3CH2SH and CH2CS highlighted the importance of interstellar formation routes for sulfur-bearing organic molecules with two carbon atoms. In this work, we perform a laboratory investigation of the solid-state chemistry resulting from the interaction between C2H2 molecules and SH radicals -- both thought to be present in interstellar icy mantles -- at 10 K. Reflection absorption infrared spectroscopy and quadrupole mass spectrometry combined with temperature-programmed desorption experiments are employed as analytical techniques. We confirm that SH radicals can kick-start a sulfur reaction network under interstellar cloud conditions and identify at least six sulfurated products: CH3CH2SH, CH2CHSH, HSCH2CH2SH, H2S2, and tentatively CH3CHS and CH2CS. Complementarily, we utilize computational calculations to pinpoint the reaction routes that play a role in the chemical network behind our experimental results. The main sulfur-bearing organic molecule formed under our experimental conditions is CH3CH2SH and its formation yield increases with the ratios of H to other reactants. It serves as a sink to the sulfur budget within the network, being formed at the expense of the other unsaturated products. The astrophysical implications of the chemical network proposed here are discussed., Comment: 9 figures, 2 pages, Accepted for publication in ACS Earth and Space Chemistry on July 5th 2024

Published

2024

5. Interaction of H$_2$S with H atoms on grain surfaces under molecular cloud conditions

Author

Santos, Julia C., Linnartz, Harold, and Chuang, Ko-Ju

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

Hydrogen sulfide (H$_2$S) is thought to be efficiently formed on grain surfaces through the successive hydrogenation of S atoms. Its non-detection so far in astronomical observations of icy dust mantles thus indicates that effective destruction pathways must play a significant role in its interstellar abundance. While chemical desorption has been shown to remove H$_2$S very efficiently from the ice, in line with H$_2$S gas-phase detections, possible solid-state chemistry triggered by the related HS radical have been largely disregarded so far -- despite it being an essential intermediate in the H$_2$S + H reaction scheme. We aim to thoroughly investigate the fate of H$_2$S upon H-atom impact under molecular cloud conditions, providing a comprehensive analysis combined with detailed quantification of both the chemical desorption and ice chemistry that ensues. Experiments are performed in an ultrahigh vacuum chamber at temperatures between 10--16 K. The changes in the solid phase during H-atom bombardment are monitored in situ by means of reflection absorption infrared spectroscopy (RAIRS), and desorbed species are measured with a quadrupole mass spectrometer (QMS). We confirm the formation of H$_2$S$_2$ via reactions involving H$_2$S + H, and quantify its formation cross section under the employed experimental conditions. Additionally, we directly assess the chemical desorption of H$_2$S by measuring the gas-phase desorption signals with the QMS, providing unambiguous desorption cross sections. Chemical desorption of H$_2$S$_2$ was not observed. The relative decrease of H$_2$S ices by chemical desorption changes from ~85% to ~74% between temperatures of 10 and 16 K, while the decrease as the result of H$_2$S$_2$ formation is enhanced from ~5% to ~26%, suggesting an increasingly relevant sulfur chemistry induced by HS radicals at warmer environments. The astronomical implications are further discussed., Comment: 11 pages, 9 Figures, 3 Tables. Accepted for publication in Astronomy and Astrophysics

Published

2023

6. First experimental confirmation of the CH3O + H2CO -> CH3OH + HCO reaction: expanding the CH3OH formation mechanism in interstellar ices

Author

Santos, Julia C., Chuang, Ko-Ju, Lamberts, Thanja, Fedoseev, Gleb, Ioppolo, Sergio, and Linnartz, Harold

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Solar and Stellar Astrophysics

Abstract

The successive addition of H atoms to CO in the solid phase has been hitherto regarded as the primary route to form methanol in dark molecular clouds. However, recent Monte Carlo simulations of interstellar ices alternatively suggested the radical-molecule H-atom abstraction reaction CH3O + H2CO -> CH3OH + HCO, in addition to CH3O + H -> CH3OH, as a very promising and possibly dominating (70 - 90 %) final step to form CH3OH in those environments. Here, we compare the contributions of these two steps leading to methanol by experimentally investigating hydrogenation reactions on H2CO and D2CO ices, which ensures comparable starting points between the two scenarios. The experiments are performed under ultrahigh vacuum conditions and astronomically relevant temperatures, with H:H2CO (or D2CO) flux ratios of 10:1 and 30:1. The radical-molecule route in the partially deuterated scenario, CHD2O + D2CO -> CHD2OD + DCO, is significantly hampered by the isotope effect in the D-abstraction process, and can thus be used as an artifice to probe the efficiency of this step. We observe a significantly smaller yield of D2CO + H products in comparison to H2CO + H, implying that the CH3O-induced abstraction route must play an important role in the formation of methanol in interstellar ices. Reflection-Absorption InfraRed Spectroscopy (RAIRS) and Temperature Programmed Desorption-Quadrupole Mass Spectrometry (TPD-QMS) analyses are used to quantify the species in the ice. Both analytical techniques indicate constant contributions of ~80 % for the abstraction route in the 10 - 16 K interval, which agrees well with the Monte Carlo conclusions. Additional H2CO + D experiments confirm these conclusions., Comment: 10 pages, 1 table, 6 figures. Accepted in the Astrophysical Journal Letters

Published

2022

7. Multiply charged naphthalene and its C10H8 isomers: bonding, spectroscopy and implications in AGN environments

Author

Santos, Julia C., Fantuzzi, Felipe, Quitián-Lara, Heidy M., Martins-Franco, Yanna, Menéndez-Delmestre, Karín, Boechat-Roberty, Heloisa M., and Oliveira, Ricardo R.

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

Naphthalene (C10H8) is the simplest polycyclic aromatic hydrocarbon (PAH) and an important component in a series of astrochemical reactions involving hydrocarbons. Its molecular charge state affects the stability of its isomeric structures, which is specially relevant in ionised astrophysical environments. We thus perform an extensive computational search for low-energy molecular structures of neutral, singly, and multiply charged naphthalene and its isomers with charge states +q = 0-4 and investigate their geometric properties and bonding situations. We find that isomerisation reactions should be frequent for higher charged states and that open chains dominate their low-energy structures. We compute both the scaled-harmonic and anharmonic infrared spectra of selected low-energy species and provide the calculated scaling factors for the naphthalene neutral, cation, and dication global minima. All simulated spectra reproduce satisfactorily the experimental data and, thus, are adequate for aiding observations. Moreover, the potential presence of these species in the emission spectra of the circumnuclear regions of active galactic nuclei (AGNs), with high energetic X-ray photon fluxes, is explored using the experimental value of the naphthalene photodissociation cross-section, \sigma_{ph-d}, to determine its half-life, t_{1/2}, at a photon energy of 2.5 keV in a set of relevant sources. Finally, we show that the computed IR bands of the triply and quadruply charged species are able to reproduce some features of the selected AGN sources., Comment: Accepted for publication in the Monthly Notices of the Royal Astronomical Society. 15 pages, 7 pages, supplementary information available online

Published

2022

8. A spectral survey of CH3CCH in the Hot Molecular Core G331.512-0.103

Author

Santos, Julia C., Bronfman, Leonardo, Mendoza, Edgar, Lépine, Jacques R. D., Duronea, Nicolas U., Merello, Manuel, and Finger, Ricardo

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Solar and Stellar Astrophysics

Abstract

A spectral survey of methyl acetylene (CH3CCH) was conducted toward the hot molecular core/outflow G331.512-0.103. Our APEX observations allowed the detection of 41 uncontaminated rotational lines of CH3CCH in the frequency range between 172-356 GHz. Through an analysis under the local thermodynamic equilibrium assumption, by means of rotational diagrams, we determined Texc = 50 \pm 1 K, N(CH3CCH) = (7.5 \pm 0.4) x 10^{15} cm^{-2}, X[CH3CCH/H2] ~ (0.8-2.8) x 10^{-8} and X[CH3CCH/CH3OH] ~ 0.42 \pm 0.05 for an extended emitting region (~10 arcsec). The relative intensities of the K=2 and K=3 lines within a given K-ladder are strongly negatively correlated to the transitions' upper J quantum-number (r=-0.84). Pure rotational spectra of CH3CCH were simulated at different temperatures, in order to interpret this observation. The results indicate that the emission is characterized by a non-negligible temperature gradient with upper and lower limits of ~45 and ~60 K, respectively. Moreover, the line widths and peak velocities show an overall strong correlation with their rest frequencies, suggesting that the warmer gas is also associated with stronger turbulence effects. The K=0 transitions present a slightly different kinematic signature than the remaining lines, indicating that they might be tracing a different gas component. We speculate that this component is characterized by lower temperatures, and therefore larger sizes. Moreover, we predict and discuss the temporal evolution of the CH3CCH abundance using a two-stage zero-dimensional model of the source constructed with the three-phase Nautilus gas-grain code.

Published

2022

9. Methane formation in cold regions from carbon atoms and molecular hydrogen

Author

Lamberts, Thanja, Fedoseev, Gleb, van Hemert, Marc, Qasim, Danna, Chuang, Ko-Ju, Santos, Julia C., and Linnartz, Harold

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Solar and Stellar Astrophysics

Abstract

Methane is typically thought to be formed in the solid state on the surface of cold interstellar icy grain mantles via the successive atomic hydrogenation of a carbon atom. In the current work we investigate the potential role of molecular hydrogen in the CH$_4$ reaction network. We make use of an ultra-high vacuum cryogenic setup combining an atomic carbon atom beam and both atomic and/or molecular beams of hydrogen and deuterium on a H$_2$O ice. These experiments lead to the formation of methane isotopologues detected in situ through reflection absorption infrared spectroscopy. Most notably, CH$_4$ is formed in an experiment combining C atoms with H$_2$ on amorphous solid water, albeit slower than in experiments with H atoms present. Furthermore, CH$_2$D$_2$ is detected in an experiment of C atoms with H$_2$ and D$_2$ on H$_2$O ice. CD$_4$, however, is only formed when D atoms are present in the experiment. These findings have been rationalized by means of computational chemical insights. This leads to the following conclusions: a) the reaction C + H$_2$ -> CH$_2$ can take place, although not barrierless in the presence of water, b) the reaction CH + H$_2$ -> CH$_3$ is barrierless, but has not yet been included in astrochemical models, c) the reactions CH$_2$ + H$_2$ -> CH$_3$ + H and CH$_3$ + H$_2$ -> CH$_4$ + H can take place only via a tunneling mechanism and d) molecular hydrogen possibly plays a more important role in the solid-state formation of methane than assumed so far., Comment: Submitted to ApJ

Published

2021

10. The role of NSP6 in the biogenesis of the SARS-CoV-2 replication organelle

Author

Ricciardi, Simona, Guarino, Andrea Maria, Giaquinto, Laura, Polishchuk, Elena V., Santoro, Michele, Di Tullio, Giuseppe, Wilson, Cathal, Panariello, Francesco, Soares, Vinicius C., Dias, Suelen S. G., Santos, Julia C., Souza, Thiago M. L., Fusco, Giovanna, Viscardi, Maurizio, Brandi, Sergio, Bozza, Patrícia T., Polishchuk, Roman S., Venditti, Rossella, and De Matteis, Maria Antonietta

Published

2022

11. A systematic IR and VUV spectroscopic investigation of ion, electron, and thermally processed ethanolamine ice.

Author

Zhang, Jin, Muiña, Alejandra Traspas, Mifsud, Duncan V, Kaňuchová, Zuzana, Cielinska, Klaudia, Herczku, Péter, Rahul, K K, Kovács, Sándor T S, Rácz, Richárd, Santos, Julia C, Hopkinson, Alfred T, Craciunescu, Luca, Jones, Nykola C, Hoffmann, Søren V, Biri, Sándor, Vajda, István, Rajta, István, Dawes, Anita, Sivaraman, Bhalamurugan, and Juhász, Zoltán

Subjects

STELLAR evolution, ION bombardment, INTERSTELLAR medium, ASTROCHEMISTRY, CELL membranes

Abstract

The recent detection of ethanolamine (EtA, HOCH |$_2$| CH |$_2$| NH |$_2$|⁠), a key component of phospholipids, i.e. the building blocks of cell membranes, in the interstellar medium is in line with an exogenous origin of life-relevant molecules. However, the stability and survivability of EtA molecules under inter/circumstellar and Solar System conditions have yet to be demonstrated. Starting from the assumption that EtA mainly forms on interstellar ice grains, we have systematically exposed EtA, pure and mixed with amorphous water (H |$_2$| O) ice, to electron, ion, and thermal processing, representing 'energetic' mechanisms that are known to induce physicochemical changes within the ice material under controlled laboratory conditions. Using infrared (IR) spectroscopy, we have found that heating of pure EtA ice causes a phase change from amorphous to crystalline at 180 K, and further temperature increase of the ice results in sublimation-induced losses until full desorption occurs at about 225 K. IR and vacuum ultraviolet (VUV) spectra of EtA-containing ices deposited and irradiated at 20 K with 1 keV electrons as well as IR spectra of H |$_2$| O:EtA mixed ice obtained after 1 MeV He |$^+$| ion irradiation have been collected at different doses. The main radiolysis products, including H |$_2$| O, CO, CO |$_2$|⁠ , NH |$_3$|⁠ , and CH |$_3$| OH, have been identified and their formation pathways are discussed. The measured column density of EtA is demonstrated to undergo exponential decay upon electron and ion bombardment. The half-life doses for electron and He |$^+$| ion irradiation of pure EtA and H |$_2$| O:EtA mixed ice are derived to range between |$10.8\!-\!26.3$|  eV/16u. Extrapolating these results to space conditions, we conclude that EtA mixed in H |$_2$| O ice is more stable than in pure form and it should survive throughout the star and planet formation process. [ABSTRACT FROM AUTHOR]

Published

2024

12. Formation of S‑Bearing Complex Organic Molecules in Interstellar Clouds via Ice Reactions with C2H2, HS, and Atomic H.

Author

Santos, Julia C., Enrique-Romero, Joan, Lamberts, Thanja, Linnartz, Harold, and Chuang, Ko-Ju

Published

2024

13. Rotational spectrum simulations of asymmetric tops in an astrochemical context

Author

Santos, Julia C., Rocha, Alexandre B., and Oliveira, Ricardo R.

Published

2020

14. First Experimental Confirmation of the CH3O + H2CO → CH3OH + HCO Reaction: Expanding the CH3OH Formation Mechanism in Interstellar Ices

Author

Santos, Julia C., primary, Chuang, Ko-Ju, additional, Lamberts, Thanja, additional, Fedoseev, Gleb, additional, Ioppolo, Sergio, additional, and Linnartz, Harold, additional

Published

2022

15. Multiply charged naphthalene and its C10H8 isomers: bonding, spectroscopy, and implications in AGN environments

Author

Santos, Julia C, primary, Fantuzzi, Felipe, additional, Quitián-Lara, Heidy M, additional, Martins-Franco, Yanna, additional, Menéndez-Delmestre, Karín, additional, Boechat-Roberty, Heloisa M, additional, and Oliveira, Ricardo R, additional

Published

2022

16. Methane Formation in Cold Regions from Carbon Atoms and Molecular Hydrogen

Author

Lamberts, Thanja, primary, Fedoseev, Gleb, additional, van Hemert, Marc C., additional, Qasim, Danna, additional, Chuang, Ko-Ju, additional, Santos, Julia C., additional, and Linnartz, Harold, additional

Published

2022

17. A Spectral Survey of CH3CCH in the Hot Molecular Core G331.512-0.103

Author

Santos, Julia C., primary, Bronfman, Leonardo, additional, Mendoza, Edgar, additional, Lépine, Jacques R. D., additional, Duronea, Nicolas U., additional, Merello, Manuel, additional, and Finger, Ricardo, additional

Published

2022

18. First Experimental Confirmation of the CH3O + H2CO â†' CH3OH + HCO Reaction: Expanding the CH3OH Formation Mechanism in Interstellar Ices.

Author

Santos, Julia C., Chuang, Ko-Ju, Lamberts, Thanja, Fedoseev, Gleb, Ioppolo, Sergio, and Linnartz, Harold

Published

2022

19. Structure, Stability, and Spectroscopic Properties of Small Acetonitrile Cation Clusters

Author

Cerqueira, Henrique B. A., primary, Santos, Julia C., additional, Fantuzzi, Felipe, additional, Ribeiro, Fabio de A., additional, Rocco, Maria Luiza M., additional, Oliveira, Ricardo R., additional, and Rocha, Alexandre B., additional

Published

2020

20. A Spectral Survey of CH3CCH in the Hot Molecular Core G331.512-0.103.

Author

Santos, Julia C., Bronfman, Leonardo, Mendoza, Edgar, LĂ©pine, Jacques R. D., Duronea, Nicolas U., Merello, Manuel, and Finger, Ricardo

Subjects

*LOCAL thermodynamic equilibrium, *QUANTUM numbers, *MOLECULAR clouds, *TRACE gases, *LOW temperatures, *COSMIC abundances

Abstract

A spectral survey of methyl acetylene (CH3CCH) was conducted toward the hot molecular core/outflow G331.512-0.103. Our APEX observations allowed the detection of 41 uncontaminated rotational lines of CH3CCH in the frequency range between 172 and 356 GHz. Through an analysis under the local thermodynamic equilibrium assumption, by means of rotational diagrams, we determined T exc = 50 ± 1 K, N (CH3CCH) = (7.5 ± 0.4) Ă— 1015 cm2, X [CH3CCH/H2] ≈ (0.8â€"2.8) Ă— 10âˆ'8, and X [CH3CCH/CH3OH] ≈ 0.42 ± 0.05 for an extended emitting region (∼10″). The relative intensities of the K = 2 and K = 3 lines within a given K -ladder are strongly negatively correlated to the transitions’ upper J quantum number (r = âˆ'0.84). Pure rotational spectra of CH3CCH were simulated at different temperatures, in order to interpret this observation. The results indicate that the emission is characterized by a nonnegligible temperature gradient with upper and lower limits of ∼45 and ∼60 K, respectively. Moreover, the line widths and peak velocities show an overall strong correlation with their rest frequencies, suggesting that the warmer gas is also associated with stronger turbulence effects. The K = 0 transitions present a slightly different kinematic signature than the remaining lines, indicating that they might be tracing a different gas component. We speculate that this component is characterized by lower temperatures and therefore larger sizes. Moreover, we predict and discuss the temporal evolution of the CH3CCH abundance using a two-stage zero-dimensional model of the source constructed with the three-phase Nautilus gas-grain code. [ABSTRACT FROM AUTHOR]

Published

2022

21. The role of NSP6 in the biogenesis of the SARS-CoV-2 replication organelle

Author

Simona Ricciardi, Andrea Maria Guarino, Laura Giaquinto, Elena V. Polishchuk, Michele Santoro, Giuseppe Di Tullio, Cathal Wilson, Francesco Panariello, Vinicius C. Soares, Suelen S. G. Dias, Julia C. Santos, Thiago M. L. Souza, Giovanna Fusco, Maurizio Viscardi, Sergio Brandi, Patrícia T. Bozza, Roman S. Polishchuk, Rossella Venditti, Maria Antonietta De Matteis, Ricciardi, Simona, Guarino, Andrea Maria, Giaquinto, Laura, Polishchuk, Elena V, Santoro, Michele, Di Tullio, Giuseppe, Wilson, Cathal, Panariello, Francesco, Soares, Vinicius C, Dias, Suelen S G, Santos, Julia C, Souza, Thiago M L, Fusco, Giovanna, Viscardi, Maurizio, Brandi, Sergio, Bozza, Patrícia T, Polishchuk, Roman S, Venditti, Rossella, and De Matteis, Maria Antonietta

Subjects

Multidisciplinary, SARS-CoV-2, rab GTP-Binding Proteins, COVID-19, Coronavirus Nucleocapsid Proteins, Humans, Lipid Droplets, Viral Nonstructural Proteins, Carrier Proteins, Endoplasmic Reticulum, Virus Replication, Article, Cell Line

Abstract

SARS-CoV-2, like other coronaviruses, builds a membrane-bound replication organelle (RO) to enable RNA replication(1). The SARS-CoV-2 RO is composed of double membrane vesicles (DMVs) tethered to the endoplasmic reticulum (ER) by thin membrane connectors(2), but the viral proteins and the host factors involved are currently unknown. Here we identify the viral non-structural proteins (NSPs) that generate the SARS-CoV-2 RO. NSP3 and NSP4 generate the DMVs while NSP6, through oligomerization and an amphipathic helix, zippers ER membranes and establishes the connectors. The NSP6ΔSGF mutant, which arose independently in the α, β, γ, η, ι and λ variants of SARS-CoV-2, behaves as a gain-of-function mutant with a higher ER-zippering activity. We identified three main roles for NSP6: to act as a filter in RO-ER communication allowing lipid flow but restricting access of ER luminal proteins to the DMVs, to position and organize DMV clusters, and to mediate contact with lipid droplets (LDs) via the LD-tethering complex DFCP1-Rab18. NSP6 thus acts as an organizer of DMV clusters and can provide a selective track to refurbish them with LD-derived lipids. Importantly, both properly formed NSP6 connectors and LDs are required for SARS-CoV-2 replication. Our findings, uncovering the biological activity of NSP6 of SARS-CoV-2 and of other coronaviruses, have the potential to fuel the search for broad antiviral agents.

Published

2022